Atomic spectrometry update – a review of advances in environmental analysis
Jeffrey R.
Bacon
*a,
Owen T.
Butler
b,
Warren R. L.
Cairns
c,
Olga
Cavoura
d,
Jennifer M.
Cook
e,
Christine M.
Davidson
f and
Regina
Mertz-Kraus
g
a59 Arnhall Drive, Westhill, Aberdeenshire, AB32 6TZ, UK. E-mail: bacon-j2@sky.com
bHealth and Safety Executive, Harpur Hill, Buxton, SK17 9JN, UK
cCNR-ISP and Universita Ca’ Foscari, Via Torino 155, 30123 Venezia, Italy
dSchool of Public Health, University of West Attica, Leof Alexandras 196, 115 21 Athens, Greece
eBritish Geological Survey, Keyworth, Nottingham, NG12 5GG, UK
fDepartment of Pure and Applied Chemistry, University of Strathclyde, 295 Cathedral Street, Glasgow, G1 1XL, UK
gInstitut für Geowissenschaften, Johannes Gutenberg-Universität, Becher-Weg 21, 55099 Mainz, Germany
First published on 27th October 2023
Abstract
Highlights in the field of air analysis included: a new focus on measuring tyre-wear particle emissions; an interest in using unmanned aerial vehicles for sampling purposes and an increased use of ICP-MS for measuring halogenated volatile organics, metals sampled directly from air and single particles. Workers have explored further the full capabilities of ICP-MS/MS, which continued to dominate water analysis, including the speciation analysis of non-metallic elements in environmental samples. By far the largest number of papers on water analysis involved preconcentration. The growing interest in reagents for green chemistry was evidenced by the publication of several reviews. Novelties included the direct introduction of magnetic nanoparticles into FAAS to boost sensitivity, and the simultaneous dual-drop preconcentration of oxidation state species that avoided the need for a sequence of elution steps by preconcentrating the analytes into specific reagents contained in the drops. Although the total reflection XRFS and LIBS techniques are close to achieving the detection limits needed to screen contaminated waters, users of these instruments often neglect to validate their methods adequately through the use of reference materials. In methods for the analysis of soils, plants and related materials, sustainable digestion, extraction and preconcentration methods featured strongly. The development of AAS, AES and AFS methods for the direct analysis of solid samples and for increasing sensitivity through analyte enrichment continued to be of considerable interest. The nitrogen-microwave inductively coupled atmospheric-pressure plasma showed promise for ICP-MS analyses. Applications of LIBS have increased dramatically in number with noteworthy developments including single-chamber laser-ablation LIBS and the analysis of plant leaves without the need for grinding and pelleting. However, many published studies lacked validation through e.g. analysis of CRMs or comparison with results obtained by other techniques. Efforts have continued on the characterisation of natural and synthetic materials that are sufficiently homogeneous to act as reference materials (RMs) in the analysis of geological materials. In particular, application of microanalytical techniques, such as LA-ICP-MS and SIMS, led to the availability of a variety of new RMs for in situ isotope ratio determinations. The application of portable LIBS instrumentation to mineral prospecting and ore processing has received much attention, with the development of new chemometric models to improve data quality. The enormous amount of analytical data produced by modern instrumentation prompted the development of software, most of which has been made freely available, for facilitating the processing and reduction of isotopic data.
1. Introduction
This is the 39th annual review of the application of atomic spectrometry to the chemical analysis of environmental samples. This update refers to papers published approximately between August 2022 and June 2023 and continues the series of Atomic Spectrometry Updates (ASUs) in Environmental Analysis1 that should be read in conjunction with other related ASUs in the series, namely: clinical and biological materials, foods and beverages;2 advances in atomic spectrometry and related techniques;3 elemental speciation;4 X-ray spectrometry;5 and metals, chemicals and functional materials.6 This review is not intended to be a comprehensive overview but selective with the aim of providing a critical insight into developments in instrumentation, methodologies and data handling that represent significant advances in the use of atomic spectrometry in the environmental sciences.All the ASU reviews adhere to a number of conventions. An italicised word or phrase close to the beginning of each paragraph highlights the subject area of that individual paragraph. A list of abbreviations used in this review appears at the end. It is a convention of ASUs that information given in the paper being reported on is presented in the past tense whereas the views of the ASU reviewers are presented in the present tense.
2. Air analysis
2.1. Reviews
A comprehensive review (143 references) on tyre-wear particles, an emerging atmospheric pollutant of interest, covered7 the mechanisms of their formation, factors that can influence their emissions (e.g. road surfaces, environmental conditions, tyre specifications and vehicle loads) and their emission characteristics (e.g. concentrations and particle size distributions). Particle sampling systems and their placement on vehicles were also usefully covered. A timely paper by Harrison and Alghamdi8 (64 references) reviewed the relative merits of various inorganic and organic tracers characteristic of species present in tyre particles as exemplified in a study9 that used ICP-MS and pyrolysis GC-MS to measure elemental and organic tracers and in another study10 that used MC-ICP-MS, XAFS and μ-XRF techniques to measure the isotopic and speciated forms of a Zn marker element contained in size-segregated airborne particles. A review paper (263 references) by Zuo et al.11 is recommended for a wider oversight on the use, challenges and future perspectives of stable isotope tracers (Cu, Fe, Hg, Nd, Pb, Si, Sr and Zn) for the source tracing of APM.2.2. Sampling techniques
An evaluation12 (55 references) of test reports published between 1994 and 2021 that detailed the performance testing of personal air samplers highlighted a lack of pertinent experimental information from which conclusions regarding comparative performance could be drawn. Another identified gap was the lack of reported testing over time to ascertain whether changes in the manufacturing process could contribute to changes in sampler performance. The preparation of a standardised test protocol and its subsequent adoption by producers was recommended.Developments in aerosol sampling media included new nanofibrous filter substrates, fabricated13 by layering nanofibrous polymers (for improved particle capturing performance) on top of microfibrous media (for mechanical support). The substrates achieved particle collection efficiencies of 99.4–99.9% for a 0.3 μm particle size at a face velocity of 10 cm s−1. The resultant drop in pressure was 0.5–2.2 kPa. This new approach was suitable for designing bespoke filter media for specific chemical or toxicological measurement requirements. A new high-flow-rate impactor sampler operating at a flow rate of 100 L min−1 employed14 a gelatin substrate that dissolved completely in water thereby allowing the easy extraction of sample particles for subsequent toxicological analysis. However, inorganic contaminants in this substrate could hinder certain chemical assays.
A reassessment of endogenous contaminants in sampling media is required as measurements become more sensitive. In a source-identification study that involved15 the measurement of Sb isotopes in APM, one particular QF filter brand was preferred because it possessed the lowest Sb blank and so did not unduly influence the isotopic measurements. The precleaning of MCE filter media by ultrasonication in 0.07 M HCl before use enabled16 the successful determination of soluble Pt in workplace air particles at 0.02 ng m−3 in a nominal 1 m3 sample. The selection of a clean activated-carbon sorbent for trapping gaseous iodine enabled17 LODs as low as 0.3 ng m−3 for 127I by ICP-MS and 0.05 × 105 atoms per m3 for 129I by AMS to be achieved.
The potential offered by advances in unmanned aerial vehicles include the collection of APM in hazardous environments and provision of a lower-cost alternative to manned flight. However, new miniaturised and lightweight air samplers are required because of the inherent lower loads and available power associated with drones. An impactor-based microsampler, operated18 at a nominal flow rate of 1 L min−1, weighed only 63 g yet had a particle collection efficiency of ca. 50% for ca. 1 μm particles. Volcanic eruptions such as the Icelandic Eyjafjallajökull eruption in 2010 can ground aircraft because of concerns over potential damage to engines due to ingress of volcanic ash. Such disruption could be avoided if there were better assessments of concentrations and particle size distributions of volcanic ash emitted into the atmosphere thereby facilitating the production of more accurate metrological dispersion models that can assist in the potential rerouting of flights. Development of a prototype airborne sampler to collect ash particles on a stub for subsequent SEM analysis involved19 simulating its performance at an altitude of 4000 m using computational fluid dynamics modelling. Deployment on an electric-motor-powered UAV was envisaged because such engines are less susceptible to ingress of ash particles than internal-combustion engines. The STAC (automated size and time-resolved aerosol collector) sampler employed:20 a suite of P/RH/T sensors to monitor ambient conditions; an OPC to measure aerosol size distribution; a micro-aethalometer to measure the black-carbon mass concentration; and a four-stage impactor operating at 3 L min−1 and with particle cut-off sizes of 2.3, 0.62, 0.42 and 0.12 μm to collect particles for offline analysis. This system was attached to a tethered balloon system deployed at various heights to undertake a vertical profiling of the atmosphere.
Passive air samplers require no power and are low cost and so are suitable for deployment in large numbers, especially in remote locations where power supplies are lacking. The performance of a GEM sampler that used a Radiello™ diffusive barrier with an activated carbon sorbent was assessed21 by deploying multiple units at remote locations in the Southern Hemisphere and the Antarctic, for which until now there has been a paucity of available GEM data. The development of this sampler and its validation were described22 in a previous paper. The authors concluded that a greater emphasis on controlling sampling blanks was required if future deployments were to be considered because the GEM concentrations were <1 ng m−3. In addition, more investigative work into sample uptake kinetics and sampling rate at sub-zero temperatures was needed. A new PAS employed23 quartz wool discs for collecting black carbon particles for subsequent EC analysis by a TOT procedure in which disc segments were loaded into the combustion analyser using a modified quartz sampling boat. The intra-sample coefficient of variation of <11% indicated a good degree of sampling (deposition) homogeneity. The inter-sample coefficient of variation derived from deploying six samplers concurrently was <17%. Measured EC in field blanks was <1.8% of that collected in samples. The concurrent deployment at two sampling locations and subsequent measurement of pumped air filter samples allowed an average PAS sampling rate of 1.1 ± 0.2 m3 per day to be calculated.
2.3. Reference materials and instrumental intercomparisons
Aviation is a significant source of ultrafine soot (<100 nm) and measurements are required to understand better its impact on health and the climate. The performance of measurement systems can be tested under controlled conditions using laboratory-based soot generators to generate simulated atmospheres. However such generators typically burn ethylene or propane fuels in air to produce black-carbon particles with a GMD of 150–200 nm which are larger than those emitted from gas turbine engines (20–50 nm). Other fuels (acetylene, dimethyl ether, ethylene, methane and propane) were mixed24 with oxygen-enriched air in an attempt to produce substantially smaller and more realistic soot particles, but alas none of the gas combinations tested was able to produce particles <95 nm in size. In contrast, by running their prototype soot generator on liquid Jet A1 fuel rather than gas fuels, researchers at ETH Zurich did produce25 realistic soot with a controllable GMD of 15–153 nm in sufficient quantities (up to 255 mg m−3). This facilitated the routine measurement of the soot-specific surface-area and pore-size distributions, measurings required in health and climatic studies. An additional benefit was that this generator could also run on the greener paraffins and cycloparaffins and so could be used in future studies on more sustainable aviation fuels.It is encouraging to see comparisons of analytical instrumentation for air pollution measurements being undertaken. Certified U particles were used26 in a comparison of AMS, SIMS and TIMS for the determination of isotope ratios in individual U particles, an application important for nuclear provenance and safeguarding purposes. The relative errors in the determination of 234U/235U and 234U/236U in NBL CRM U200 (uranium isotopic standard) by AMS were <10 and <20%, respectively, whereas the results obtained by fission track-TIMS and SIMS were within ±5% and ±10% of the certified values, respectively, for both techniques. The relative error and external precision of 234U/238U and 235U/238U in the analysis of NBL CRM U850 (uranium (U3O8) isotopic standard, 85% U-235) by AMS, SEM-TIMS or SIMS were <10% and <5%, respectively. The average values of the relative error and external precision for 236U/238U were both <5% for AMS analysis but <10% for SEM-TIMS or SIMS analyses. The EDXRFS and SF-ICP-MS analyses in an inter-laboratory comparison of PM2.5 filters from the IMPROVE air monitoring network gave27 results that agreed within ±20%. Major-axis regression-analysis between the techniques revealed very strong correlations (r2 > 0.9) for Al, Ca, Cu, Fe, K, Na, Mg, Mn, Sr, Ti, V and Zn, strong correlations (0.8 < r2 < 0.9) for Cr, Ni and P, a weak correlation (r2 = 0.69) for Zr and very weak correlations (r2 < 0.4) for As, P and Rb. Highly correlated elements yielded regression slopes within ±20% of unity, except for Zn, indicating that absolute element determinations by the two techniques agreed. This exercise is timely because as air becomes cleaner, lower measurement LODs are required so the use of ICP-MS could supersede that of XRFS. In a similar study, a comparison of ICP-MS/MS and PIXE measurements of Al, As, Br, Ca, Cr, Cu, Fe, Mg, Mn, Mo, Na, Ni, Pb, Rb, S, Se, Sr, Ti, V, Zn and Zr in PM2.5 and PM2.5–10 filter samples demonstrated28 that paired-data ratios were mostly ca. 1 except for those of Br, Mg, Na and Zr. Increased use of ICP-MS/MS is welcome because its enhanced capability in resolving isobaric interferences makes the determination of elements such as S, hitherto not possible with older ICP systems, feasible.
2.4. Sample preparation
Undertaking acid digestions remains a laborious task and so a robotic system was developed29 for processing large numbers of samples of house dust by MAE. Liquid handling steps such as dispensing acids into digestion vessels and diluting samples were automated thus freeing up operator time to perform other required laboratory tasks.In the determination of the in vitro bioavailable fraction of metal(oid)s in PM2.5, filter samples were leached30 in ALF (pH = 4.5 ± 0.1), and SBF (pH = 7.4 ± 0.1) was used as an acceptor solution for the leachates. A dialysis membrane system (8 kDa MWCO) designed to mimic what occurs at the gas-exchange region in the deep lung was assembled in 50 mL glass flasks. Samples were incubated in batches at 37 °C for 24 h and SBF samples diluted and analysed by ICP-MS. Any remaining undissolved residues were subjected to MAE with HNO3/H2O2 following the EN 14902 standard protocol. When aliquots of ERM CRM CZ120 (fine dust (PM10-like) elements) were tested, the mean relative errors for As, Cd, Ni and Pb were −12, 12, −3, and −6%, respectively. The mean bioavailable fractions (CSBF/CMAE) determined in PM2.5 samples were 0.52, 0.06 and 0.36 for Cd, Ni and Pb, respectively. It was not possible to calculate a bioavailable fraction for As because concentrations were below the LOQ. Data were reported for 26 elements in total. It was claimed that inclusion of the dialysis membrane simulated more realistically the process that occurred in the human lung and so provided a better estimation of the health risk posed by inhaled metal(oids)s in PM2.5. In the assessment of a procedure for extracting metallic NPs from air-filter samples, simulant samples spiked with 50 nm-sized gold and 70 nm-sized platinum NPs were subjected31 to either MAE or UAE using various solvents. Interestingly, an alternative extraction system, termed “hard cap espresso extraction”, used a coffee machine with disposable coffee capsules modified in-house for achieving the desired high temperatures and pressures. The NPs were extracted quantitatively in 2.0% (m/m) NH4OH within 4 min by MAE, but for the other procedures tested either incomplete NP recoveries or sample degradation occurred. Soluble P leached from APM deposited into the oceans from the atmosphere is a crucial nutrient source for the marine ecosystem and bioavailability assessment studies generally involve extractions into pure water. However in a study in which both 18 MΩ water and seawater were used32 to leach TSP and PM2.5 particles collected on filters, the P concentrations determined in water leachates were on average ca. 25% higher than those measured in seawater leachates. This led the researchers to conclude that marine phytoplankton productivity rates were being overestimated.
2.5. Instrumental analysis
The measurement of particle number, mass, shape and size in harsh industrial environments is challenging but aspirational because in situ measurements are needed to support process automation. A unique set of instruments with potential for the characterisation of APM during metal smelting processes was assessed35 for interrogating simulant Al2O3 and chalcopyrite particles aerosolised in a dust chamber. The instrumentation, all contactless and working in real-time, included: stroboscopic imaging for confirming particle sphericity and measuring particle number density; LIBS for estimating particle number density and compositional analysis; and LII for classifying particles based upon their tendency to incandesce. Whereas a LIBS setup for aerosol measurements typically involves high fluences and low repetition rates, in this study low pulse energies (3 or 10 mJ) with high repetition rates (up to 500 Hz) were used for the rapid measurements required for process monitoring. The resultant plasma, captured by CCD imaging, allowed the detection volume and the particle hit rate to be measured and hence the particle-number-density values to be calculated. Results were consistent with values derived from stroboscopic measurements. Performing LII measurements at very low particle-number-densities was possible because of the large sample volume deployed. A sensitive and robust photodiode was able to count all light-emitting events because it was operated at a repetition rate of 100 kHz and so responded quickly at the ns scale.
Further developments in application of LIBS to the analysis of air samples are summarised in Table 1.
| Analyte | Sample matrix | Study rationale | Technique | Findings | Reference |
|---|---|---|---|---|---|
| C | Air | Evaluation of a technique for the rapid detection of total gaseous C | LIBS | Use of a total nitrogen IS method enabled a LOD of 14 ppm to be achieved, which was improved to 5 ppm when a multivariate calibration model with an ADMM algorithm used for optimisation purposes | 260 |
| Cs | Surrogate nuclear fallout particles containing Cs, Cu and Na | Ascertaining potential for real-time and stand-off measuring capability – assessment of elemental fractionation effects | LIBS | In the presence of Cu, Na resonance emission enhanced but Cs resonance emission reduced. Use of fs LA found to reduce such fractionation effects by 50%. Such effects arise because the particle matrix can induce changes to local plasma temperature, population of atomic states and emissions | 261 |
| Indoor air aerosols | Indoor air simulation studies | Evaluation of a potential tool for the rapid interrogation of changes in indoor air quality | LIBS | Four common indoor air quality perturbations were simulated, including burning C, burning incense, spraying perfume and running a hot shower. The elemental spectra determined from these different scenarios were examined by PCA analysis. The air environment was classified by k-NN algorithm with an accuracy of 99.2%, demonstrating that the use of LIBS with machine learning tools to detect changes in air quality and predict air composition concentrations was possible | 262 |
| Inhalable particles | Four different test aerosols mimicking those found in the workplace | Evaluation of a potential in situ measuring tool for determining the elemental composition of inhalable particles present in the workplace | LIBS | Prototype sensor used a passive sampling inlet and an optical triggering system for initiating a particle ablation process. Particle composition was quantified by interrogation of emission spectra using a real-time material classification algorithm. Validation performed on 1480 spectra arising from measurement of four test aerosols. Potential for combining with a previously developed direct-reading particle sizer thereby producing a portable system for counting, elemental determination and sizing of large inhalable particles | 263 |
| Single ambient aerosol particles | NaCl test particles | Evaluation of a novel method for the analysis of the elemental composition of single aerosol particles sampled directly from the aerosol phase using size amplification-aided aerosol charging, linear electrodynamic quadrupole as an alternative to the commonly used aerosol MS | LIBS | Proof-of-concept with 300 nm NaCl particles yielded a LIBS hit ratio of >90% for particle concentrations of <1 particle per cm3. Exceptional potential for a portable analysis platform for various applications in the field of aerosol research ranging from atmospheric ice nucleation studies to human respiratory particle studies | 264 |
| Smoke | Smoke arising from burning of plastics | Evaluation of a potential tool for identifying the smoke signature arising from burning of plastics | LIBS | The accuracy in identifying the plastic origins of a waste burn by monitoring the characteristic C, H, N and O elemental emissions in smoke in conjunction with the use of PCA and error back propagation ANN techniques reached 77% | 265 |
| UF6 | UF6 test gases with reported 235U![[thin space (1/6-em)]](https://www.rsc.org/images/entities/char_2009.gif) :238U ratios (enrichment values) determined by gas source MS |
Evaluation of the potential for developing a continuous on-line tool to monitor the enrichment process within a nuclear centrifugal enrichment facility | LIBS | By optimising fs-LIBS measurement conditions for prominent 424.437 and 424.412 nm isotope pair emissions associated with 238U and 235U undertaken, mean absolute errors as low as 0.3% in reported enrichment values obtained that demonstrated the potential effectiveness and applicability of this approach | 266 |
| Volcanic plume ash | Surrogate ash suspended in air using a laser-induced shockwave in a test chamber to simulate a plume | Evaluation of a calibration-free quantification method | LIBS | Calibration-free LIBS-derived elemental data (tabulated as oxides) in good agreement with data derived from measurements by XRFS, typically <10% difference for major (Al and Si) and 10–50% difference for minor elements (Ca, Fe, K, Na and Ti). Future endeavours to include making concurrent particle size measurements and making instrumentation portable for field use | 267 |
2.5.2.1. Inductively coupled plasma mass spectrometry. Two complementary sp-ICP-MS review papers36,37 (137 and 107 references, respectively) presented overviews of the benefits and limitations of the technique and summarised future trends, which included hardware developments such as ICP-TOF-MS for multielement measurements and microdroplet generators for calibration. Topics covered included: use of hyphenated techniques to provide complementary particle information; use of enriched isotope tags to track NP transformation and bioaccumulation processes in the environment; and real-time monitoring of NPs using an IS calibration approach.
Application of ICP-MS as an-online detector for atmospheric measurements continues to be of interest. A gas-exchange device for exchanging air with argon was coupled38 to an ICP-MS instrument so that PM2.5 particles could be sampled directly from air into the plasma thereby making possible trace measurements at a temporal resolution of 5 min. This novel approach, together with TEM analysis of particles collected on impactor samplers, assisted in identifying the sources of air pollution episodes that contained metallic particles. In a similar study, the elements As, Cd, Cs, Cu, Fe, Mg, Mn, Pb, Rb, Sn, Tl and V in PM2.5 could be determined39 with LODs of 0.001–6.30 ng m−3 and a temporal resolution of 3.3 min. Calibrant metallic aerosols containing Cr, Mo and W were produced by a spark generator. A comparison with the more conventional ICP-MS analysis of filters in the laboratory gave elemental correlations (r2) of 0.19–0.84 with slopes of 0.12–0.80 suggesting that further development is needed.
A new automated method for the determination of volatile organic carbon compounds containing Br, I, Se and S involved40 trapping on a sorbent, desorption and analysis by TD-GC-ICP-MS. Volatile species were stable in sorbent tubes stored at −20 °C for at least 28 days. Measurements were performed in <15 min, and the absolute LODs for the various species were in the fg to pg mass range.
Further ICP-MS applications for air analysis are summarised in Table 2.
| Analyte | Sample matrix | Sample preparation/introduction | Technique | Findings | Reference |
|---|---|---|---|---|---|
| Ag | NPs released from textile products | Extraction from textiles by centrifugation using H2O. | sp-ICP-MS | LOD of 4.59 × 104 NPs per gram of textile achieved. | 268 |
| Suspension nebulisation | NP size LOD was 12 nm. | ||||
| Recoveries of silver NP spikes (20, 40 and 60 nm sizes) added to textiles were 102–113% | |||||
| 129I | Deposition rainwater samples | 0.1% NH4OH, 10 g L−1 ascorbic acid and 3% Tween® diluent used to minimise memory effects. | ICP-MS-MS | 129Xe isobaric interferent decreased using O2-mediated mass-shift cell chemistry. Improved LOD of 11 mBq L−1 achieved | 269 |
| Solution nebulisation | |||||
| 129I | Deposition rainwater samples | None. | ICP-MS-MS | 127I hydride and 129Xe isobaric interferences decreased with O2–CO2 cell reaction chemistry | 77 |
| Solution nebulisation using a HEN | |||||
| 129I, 63Ni, 237Np, 239Pu, 90Sr, 99Tc, 93Zr | Air samples (and other environmental matrices) | Microwave-assisted digestion as per EN 14902. | ICP-MS-MS | H2 and He collision gas KED; O2gas and NH3gas mediated mass shift cell chemistries optimised for improved multiple radionuclide measurements in a variety of environmental matrices |
270 |
| Solution nebulisation | |||||
| 204Pb ratios | PM10 | MAE using HNO3/H2O2. | Quadrupole ICP-MS | Repeat measurements of digested BCR CRM 482 (lichen–trace metals) at 1 μg L−1 demonstrated an external precision <0.34% and differences from reference values of <2‰ suggesting that isobaric interference of 204Hg on 204Pb had been corrected | 271 |
| Solution nebulisation | |||||
| Pt | Road dust NPs | Pt NPs – UAE using H2O, centrifugation, and dilution. | sp-ICP-MS | Size, mass- and particle-based concentrations determined in <11 min ca. 12% of Pt in BCR CRM 723 (road dust Pd Pt Rh) measured as NPs. Platinum NPs in measured road dust samples were 15–75 nm at concentrations of 6–20 ng g−1 and represented 11–27% of total measured Pt content | 272 |
| Suspension nebulisation. Total Pt – MAE using HNO3/HCl. | |||||
| Solution nebulisation | |||||
| PTFE microparticles | Particles | n/a. | sp-ICP-MS | Detection of a F elemental marker through use of a BaF2 proxy measurement and elimination of polyatomic isobaric interferences at m/z 157 using O2-mediated chemistry in the DRC | 273 |
| Suspension nebulisation | |||||
| Rh | Road dust NPs | Rh NPs – ultrasonic assisted extraction using rainwater. | sp-ICP-MS | A CPE preparatory step required to remove dissolved ionic Rh signal for successful NP determination. Size LOD of 9 nm achieved even in the presence of high levels (×1000) of dissolved Rh | 274 |
| Suspension nebulisation. | |||||
| Total Rh – MAE using HNO3/HCl. | |||||
| Solution nebulisation | |||||
| Si (dissolved) | Rainwater | n/a. | ICP-DRC-MS | Successful removal of isobaric interferents at m/z 28 and signal enhancement using CO2 in the DRC and by adding CH4 modifier to the plasma | 75 |
| Solution nebulisation | |||||
| U | Particles | n/a. | LA-ICP-MS | Results comparable with those obtained by large geometry SIMS indicating that LA can offer a rapid U isotopic analysis capability without undue loss in analytical performance | 275 |
| Zn | Size fractionated PM | HNO3/HF digestion. | MC-ICP-MS | Zn in particles of 0.65–4.7 μm contained remarkably light δ66Zn. ZnO and ZnS species originated from brake/road/tire dust, ZnCl2 and ZnSO4 from industrial emissions and Zn oxalate from vehicular exhaust. Simultaneous application of speciation/isotopic assays on size segregated APM a powerful tool to estimate origin and formation of Zn species in aerosols | 10 |
| Zn separated from matrix elements by AEC. | |||||
| Solution nebulisation. | |||||
| Direct analysis | XAFS | ||||
| Various | PM2.5 particles | Sonication. | sp-ICP-MS | Metals in individual particles measured and a machine learning protocol applied for source apportionment studies which demonstrated a 73% accuracy on a physically mixed model test sample | 276 |
| Suspension nebulisation | |||||
| Various | Gun-shot residues | Tape sampling followed by extraction. | sp-ICP-TOF-MS | Ability to analyse large number of particles rapidly and to determine minor elements other than Ba, Pb and Sb to aid particle classification | 277 |
| Suspension nebulisation |
2.5.2.2. Mass spectrometry techniques other than inductively coupled plasma mass spectrometry. Applications of MS to air analysis are summarised in Table 3.
| Analyte | Sample matrix | Study rationale | Technique | Analytical findings | Reference |
|---|---|---|---|---|---|
| APM | Particles collected on small air filter/impactor samplers deployed on a UAV | Evaluation of a micro-nebuliser system to efficiently introduce those small (ng) quantities of aerosol samples that are typically collected | Aerosol MS | Micro-nebuliser enabled sample volumes as low as 10 μL to be processed. Instrumental LOD of 0.75 and 0.19 ng determined using test SO42− and NO3− solutions. Results obtained for these ions on PM extracts in agreement with IC determinations | 278 |
| APM | Standard-sized particles (PSL and SiO2) as calibrants. Standard elemental solution droplets and suspension particles as test samples | Evaluation of a new spectrometer for accurate sizing and isotopic analysis of individual particles | Sp aerosol MS | Instrument optimised and a universal formula proposed for size calibration. The measured isotopic ratio for most elements investigated were accurate to 5% | 279 |
| C | Propane gas | To evaluate the accuracy of this versatile technique that only requires a small gas volume for analysis in the determination of position-specific δ13C values which is useful for understanding the evolutionary history of natural gases | GC-pyrolysis-GC-IRMS | Comparative testing against accurate 13C NMR measurements (but which requires a large gas volume size and is slow) on nine natural gas samples undertaken. Results showed that large isotope fractionation effects occurred during pyrolysis step but the extent can vary from instrument to instrument necessitating individual instrument calibration with isotopic gas reference standards. Study also highlighted the need for new position-specific isotope standards for propane and other gases such as CH4 | 280 |
| O | Oxygen | Evaluation of extent of Ar interferences on 18O/16O ratio measurements and improving ways of obtaining more accurate δ18O values | CF-IRMS | 18O/16O ratio measurements by CF-IRMS (GC-IRMS and GasBench™ IRMS) were subject to Ar interferences that led to increases of δ18O values by up to 6‰. These interferences were minimised by improving the chromatographic separation of Ar and O2 signals and by applying a post measurement correction protocol | 281 |
| S | Gases | Improving δ36S measurements | IRMS | Contamination in He GC carrier gas supply discovered. New SF6 fluorination and purification system built. Without purification, measured δ36S values were >10‰ higher than expected. With purification, measured δ36S values before and after passing through GC were < instrumental error of 0.2‰ | 282 |
| U | Particles | Investigation into the use of negative-ion molecular-oxygen primary-beams for particle analysis | SIMS | Use of O3− primary ions provided higher U+ yields, lower mass fractionation and more consistent results across substrates compared to using other O beam species | 283 |
| VOC | Gases | Evaluate instrumental approach for measuring δ13C values as a potential tool for source identification | SPME-GC-combustion-IRMS | Collection and equilibrium time to collect VOC on SPME fibre was 700–800 min but compensated by fast extraction and analysis times. δ13C values for benzene from vehicular exhausts and from air in the vicinity of a petrol station were −25.3 ± 1.0‰ and −26.2 ± 0.7‰ suggesting utility for this approach | 284 |
The improved characterisation of aerosols in their native state was43 the goal of researchers at the Swiss Light Source beam-line facility. Test aerosols, generated by nebulising salt solutions and dried using a diffusion drier, were directed into a measurement chamber for in situ interrogation by XAS. This approach was preferable to alternatives that employed lenses to focus test aerosols as thin jets into a low-pressure chamber because ambient pressure conditions were maintained throughout ensuring that the thermodynamic state of the particles was controllable from generation to analysis. At the ATOMKI accelerator centre in Hungary, a new PIXE setup, equipped with a large angle SDD detector installed in an external beam-line, made it possible44 to process batches of 100–200 aerosol filter samples in 10–12 h. Analysis of NIST SRM 2783 (air particulate on filter media) gave results within ±5% of certified values. The LODs were <10 ng cm−2 for many elements of interest when samples were deposited onto quartz, polycarbonate or PTFE filter media. Developing new mapping capabilities at <mm resolution was proposed as the next development.
Suitable OC/EC split points in TOT assays can be chosen by measuring the transmission of a beam of light through a filter sample during its combustion and by exploiting the fact that different carbonaceous compounds possess different light absorption properties. The fact that other aerosol species also absorb light was exploited46 in the determination of Fe in mineral dust samples collected on filters. Calibrant samples, prepared by doping filters with suspensions containing either Fe2O3 or NIST SRM 2709 (San Joaquin soil), enabled linear calibrations to be made over the 10 to 100 μg cm−2 range. When PM10 samples containing hematite particles were analysed, the Fe results agreed with those obtained by ICP-AES or ICP-MS analyses following MAE. However, results did not agree for filter samples collected from railway tunnels because the Fe content and morphology of particles were different. This highlighted a matrix dependency in this new methodology. More disconcertingly, deciphering a suitable OC/EC split point for air filter samples that contained both C and Fe (loadings of >10 μg cm−2) became challenging because of overlaps in optical absorption spectra and resulted in underestimations in EC and overestimations in OC values. In a worst-case scenario, EC determination was not possible at all. This has serious implications if the use of TOA is contemplated for air environments such as those in vehicle repair shops, where diesel (carbonaceous) fumes and (Fe-containing) welding fumes can potentially co-exist.
Further measurements of carbonaceous particles are summarised in Table 4.
| Analyte | Sample matrix | Study rationale | Technique | Analytical findings | Reference |
|---|---|---|---|---|---|
| C | Carbonaceous particles collected on filter tapes from bam samplers (an air sampler design widely deployed for the real-time determination of particle mass) | Evaluation of a low-cost method for determining black carbon using an off-line image reflectance-based method | Optical spectroscopy | Mobile-phone camera images used to determine black carbon in spot samples collected on filter tapes. LOD of 0.15 μg achieved for an hourly sample collected at 1 m3 h−1. Post-analysis of filter tape samples could be a valuable source of new APM compositional data | 285 |
| C | Diesel fume emissions in railway stations | Study aims: measure worker exposure to diesel fume emissions using wearable aethalometers and to investigate variables that influence emissions | Optical spectroscopy | Real-time personal measurements demonstrated that the extent and frequency of exposures, especially peak exposures, was indeed as suspected intrinsically linked to job role and location within station and the frequency at which diesel-powered trains entered and left stations, but powerfully demonstrated for the first time using wearable fast-response real-time sensors | 286 |
| C | CNT in workplace air | One study aim was to ascertain potential for measuring worker exposure to CNT in real-time using wearable aethalometers (black carbon sensors) as a complementary tool to measuring exposure using TWA filter sampling and off-line EC determinations in the laboratory | Optical spectroscopy | Transport losses of coarser CNT-containing particles emitted from work processes, within the sampling tube (1 m in length) and internal losses in the aethalometer suggested as a reason why no significant correlation between EC and black carbon measurements was noted. Authors advocated that further studies on potential sampling losses of larger particles required | 287 |
| C | Carbonaceous aerosols | Determination of EC in aerosols collected in the Tibetan Plateau | TOR analysis | High OC content in sampled aerosols resulted in a positive bias of 25–40% in EC determinations (conversion of some OC to pyrolytic carbon during the assay and hence misclassification as EC). Authors suggested that this overestimation and its impact on radiative forcing should be considered when comparing observations with model simulations | 288 |
| C | Carbonaceous particles | Evaluation of predictive models to estimate MAC values where direct calculations based upon aerosol light absorption and black carbon mass determinations not possible | Optical spectroscopy | Five models (3 models based upon light scattering theories, one empirical model based upon particle mass concentrations determination and a machine learning model) evaluated. Machine learning model worked well for samples studied but model performance degraded when applied to aged black carbon particles (i.e., coated particles). Generally, the empirical model tended to over-predict MAC whilst models based upon Mie light scattering concept tended to under-predict MAC | 289 |
| C | Carbonaceous particles | The microphysical properties of fresh black carbon emitted from traffic (petrol and diesel fuels) and aged black carbon emitted from solid fuel burning sources (coal, cotton stem, rice stem and mulberry) studied | Single particle soot photometer, differential mobility analyser, CPMA | Core size, number size and coating thicknesses determined that emphasised the large property differences in black carbon particles derived from fresh traffic emissions compared to those derived from aged solid-fuel-burning emissions that have over time mixed with other atmospheric species. Such differences need to be considered in climatic models | 290 |
Development of a new two-stage semi-dry electrostatic precipitator (SDEP) sampler for use in on-line IC systems that measure water-soluble inorganic ions in PM2.5 was reported.47 The number-based collection efficiency was >95% for particles in the 14 nm to 1 μm size range, the mass-based PM2.5 collection efficiency was 94–98% and the ion recovery rates were 93 ± 10% for Na+, 103 ± 15% for NH4+, 96 ± 8% for NO3− and 92 ± 6% for SO42−. In field trials, results obtained with this new SDEP-IC system agreed with those obtained using the established (particle in liquid sampler) PILS-IC system with linear regression slopes of 0.84–0.97 and r2 values of 0.90–0.96. Results for NH4+ by the PILS-based system were, however, ca. 16% lower than those obtained using this new prototype. This loss was attributed to volatilisation when aerosol samples were mixed with high-temperature steam in the PILS-based system to extract water-soluble ions for analysis but which did not occur with the SDEP-based prototype because it used a parallel plate wet denuder to extract water-soluble ions for analysis. It was established48 that the main sources of uncertainty in online IC measurements were variations in LOD, measurement repeatability, fluctuations in sampling flow rates, variabilities in liquid sample volumes and the representativeness of sampled air. The poor LOD for NO3− (ca. 0.6 μg m−3) was attributed to impurities in the eluent but it was noted that cleaner alternatives were available. A preconcentration IC column was recommended for measurements undertaken in more pristine air environments because the LOD term, not surprisingly, dominated the measurement uncertainty budget. The uncertainties in flow and volume measurements were dictated by the performance of the MFC and the syringe pump, so it was important to keep instrumental components in good working order. Loss of HNO3 by reaction with the walls of the inlet sampling line was problematical, so it was recommended to keep the length of the sampling line short to minimise reaction time and thereby improve sampling representativeness. In summary, regular instrumental maintenance, use of appropriate consumables and regular cleaning were recommended to decrease uncertainties in measurements.
3. Water analysis
3.1. Reviews
Two reviews on mono-elemental analysis of water covered F49 (82 references) and Pb50 (61 references). Both papers considered atomic spectroscopy and other detection methods, such as spectrophotometry and electrochemical techniques, both with and without preconcentration.A less-specific review (102 references) on instrumental methods for the quantification of potentially toxic elements in environmental and other matrices included51 nine papers on water analysis.
In an overview (88 references) of the preservation of mercury in water samples, King et al.52 evaluated trapping on SPE phases as an alternative to the current practice of using preservatives in bottles. The authors noted that, when using SPE, various species can be preserved in the field without the use of hazardous reagents. Further advantages are decreased transport costs and elimination of the need to maintain the cold chain. However, the current lack of standardised methods is a drawback.
3.2. Sample preconcentration
A review (120 references) of solid- and liquid-phase microextraction for the determination of Hg in environmental samples included53 the treatment of air, soil, water and biota samples. The authors concluded that sample preparation in the field and, eventually, full in situ analysis will simplify the determination of Hg. A review in Chinese (74 references) on recent advances in the use of graphene for sample preparation covered54 metal ions and organic compounds in biological and environmental matrices.The increasing interest in green chemistry and deep eutectic solvents was reflected in the publication of three reviews. The first (88 references) covered55 homogeneous LLME with solvent-, pH- or temperature-driven phase-separation prior to the extraction of organic compounds and inorganic ions. The second56 (178 references) was an overall review of DESs for the extraction of organic or inorganic species from water and food samples. The third (150 references) covered57 green solvents, including DESs, and ILs for the extraction of trace analytes from various matrices. These three reviews highlight the importance and possibility of removing traditional volatile and toxic solvents from analytical methods.
Tables 5 and 6 present the most significant advances in analyte preconcentration using SPE or LPE for water analysis.
| Analytes | Matrix | Technique | Substrate | Coating or modifier | LOD in μg L−1 (unless stated otherwise) | Validation | Reference |
|---|---|---|---|---|---|---|---|
| Ag | Soil and water | HR-CS-ETAAS | Bentonite | 0.01 | NIST SRM 2709 (San Joaquin soil), NIST SRM 2711 (Montana soil) and NIST SRM 1643e (trace elements in water) | 127 | |
| Ag, Au NPs | Water | ETAAS | Ferrite particles | Ammonium diethyl dithiophosphate | 4 (Ag) 12 (Au) ng L−1 | NIST SRM 1640a (spring water) and ECCC CRMs TM-23.4 (trace element fortified water), TM-25.4 (low level fortified water sample), and TMDA-62.2 (Lake Ontario fortified water) | 291 |
| AsIII, Asv | Water | ICP-MS | SAX and SCX columns | 0.03 | NRCC CRMs CASS 5 (near shore seawater) and SLRS-2 (river water) | 292 | |
| Asv | Water | EDXRFS | Poly(vinylidene)fluoride membrane | MIL-101(Fe) (an Fe-based MOF) | 0.094 | Spike recovery | 293 |
| Cd | Pure and tap water | ETAAS | Fe3O4 NPs | Amine-functionalised shell, ion imprinted with Cd2+ | 0.64 ng L−1 | Spike recovery and comparison with ICP-MS results | 294 |
| Cd, Co, Cr, Cu, Fe, Mn, Ni | Water and plant samples | FI-FAAS | Bi(OH)3 coprecipitation | 1 (Cd) to 27 (Ni) | IRMM BCR-715 (industrial effluent wastewater) | 295 | |
| Cd, Co, Cu, Fe, Mn, Mo, Ni, Pb, Ti, V, Zn | Water and wastewater | FI-ICP-AES | Carboxymethylated polyethyleneimine 600 resin | 0.0012 (Cd) to 0.11 (V) | SCP science RMs EnviroMAT ES-L-1 (ground water) and EU-L (wastewater) | 296 | |
| Cd, Cr, Cu, Ni, Pb | Water | ICP-MS | Silica gel | C18-alkylimidazolium ionic liquid, metal ions complexed with 1-(2-pyridylazo)-2-naphthol (PAN) | 0.11 (Cd) to 11.3 (Ni) | Spike recovery | 297 |
| Cd, Cu, Fe, Ni, Pb | Seawater | FAAS | 3-Phenyl-1-(2-pyridyl)thiourea resin | 0.13 (Cu) to 2.63 (Ni) | Spike recovery | 298 | |
| Cd, Cu, Pb, Zn | Seawater | AAS | Polystyrene resin microspheres | EDTA-type amino polycarboxylic groups | 0.01 (Cd) to 3.1 (Zn) | Spike recovery and analysis of a seawater RM from Beijing Putian Tongchuang BioTech Co., Ltd | 299 |
| Cd, Pb | Tap and river waters, agricultural products | ETAAS | KCC1 fibrous Si nanospheres | Amine functional groups | 0.02 (Cd) and 0.18 (Pb) | Spike recovery | 300 |
| Co, Ni | Water and plants | FAAS | Multiwalled carbon nanotubes | 3-(2,4-Dihydroxyphen-1-ylazo)-1,2,4-triazole | 0.3 (Co) and 0.6 (Ni) | ECCC RM TMDA-52.3 (fortified lake Ontario water) and NIST SRM 1570A (spinach leaves) | 301 |
| CrVI, total Cr | Sea, well and tap waters | ICP-AES | Magnetic graphene oxide | 4-Aminobenzenesulfonic acid | 0.1 (CrVI) and 0.08 (total Cr) | ECCC CRM TMDA 54.4 (fortified lake waters) and SPS RM SW2 (surface water) | 302 |
| Cu | Tap, river and seawaters | FAAS | Silica gel | N-{3-[(3-Aminopropyl)amino]propyl}-2-hydroxy-benzaldimine | 0.45 | ECCC TMDA 54.4 (fortified lake waters) and NWRI ECCC RM NWTM-15.2 (fortified water) | 303 |
| Ga | Seawater | IDA-ICP-MS | Nobias chelate PA 1 resin | 0.10 pmol L−1 | Spike recovery and comparison with standard coprecipitation method | 304 | |
| Ga, In | Waters, soils, electronics | ETAAS | Fe3O4 NPs | 0.01 (In) to 0.02 (Ga) | ECCC RMs TM-25.4 (low level fortified lake water) and TMDA-62.2 (lake Ontario fortified water) | 305 | |
| Ni | Water, tomato leaves | HR-CS-FAAS | Fe3O4 NPs | 2-(5-Bromo-2-pyridylazo)-5-(diethylamino)phenol | 15 | NWRI ECCC CRM TMDA-64.3 (lake Ontario water) and NIST SRM 1573a (tomato leaves) | 306 |
| Pd | Tap, river and seawaters | HR-CS-FAAS | Graphene oxide NPs | Titanium aluminum carbide | 0.3 | Spike recovery | 307 |
| Pu | Water, seawater | ICP-MS/MS | TK 200 resin | 0.32 μBq L−1 (0.14 fg L−1) | CRM IAEA-443 (Irish Sea water) | 308 | |
| REEs | Seawater | SF-ICP-MS | seaFAST-3™ mixed functional group proprietary resin | 0.01–0.03 ng L−1 | NRCC CRM SLEW-3 (estuarine water) | 309 | |
| U | Mineral, river, lake and sea waters | TXRFS | Graphene oxide | β-Cyclodextrin | 0.014 | NIST SRM 1640a (trace elements in natural water) and spike recovery | 310 |
| Analytes | Matrix | Technique | Method | Reagents | LOD in μg L−1 (unless stated otherwise) | Validation | Reference |
|---|---|---|---|---|---|---|---|
| Cd | Oil production waters | ETAAS | DLLME | Diethyldithiocarbamate and chloroform | 5 ng L−1 | NRCC CRM CASS 5 (near shore seawater) and NRCC CRM SLEW-3 (estuarine water) | 311 |
| Co, Ni | Water, fruit juice | FAAS | DLLME | Choline chloride, butyric acid and phenylacetic acid | 0.1 (Co) and 0.17 (Ni) | SPS RM WW2 (wastewater) | 312 |
| Co, Pb, Pd | River water, wastewater | FAAS | DLLME-SFOD | Folic acid, 1-undecanol and acetone | 0.022 (Pb) to 0.055 (Pd) | Spike recovery and NIST SRM 1643f (trace elements in water) | 313 |
| CrIII, CrVI | Water | ETAAS | Dual drop LPME | DDTC, 1-phenyl-3-methyl-4-benzoylpyrazol-5-one and 1-decanol | 1.1 (CrIII) and 1.4 (CrVI) ng L−1 | Chinese CRMs GSBZ50027-94 and GBW(E)080039 (waters) | 314 |
| Cu | Water | ETAAS | DLLME | 2-(5-Bromo-2-pyridylazo)-5-dimethylaminoaniline, ammonium acetate, chlorobenzene and acetonitrile | 0.01 | Spike recovery | 315 |
| Cu, Pb | Water, fruit juice | FAAS | DLLME | DDTC, chloroform and folic acid | 0.07 (Pb) and 0.08 (Cu) | SPS RM WW2 (wastewater) | 316 |
| Hg | Tap and lake waters | AFS | CPE | Triton X-114 and thio-Michler’s ketone | 0.003 | Spike recovery | 317 |
| I | Brine | EDXRFS | LPE | Trihexyltetradecylphosphonium chloride and trioctyl ammonium chloride | Not reported | Spike recovery | 318 |
| Ni | Seawater | ETAAS | Electro-membrane assisted micro LPE | Di-2-ethylhexyl phosphoric acid in kerosene | 23 ng L−1 | IRMM CRM BCR-403 (seawater) | 319 |
| SeIV | Ground water | ETAAS | LPE | ZnCl2 | 25 ng L−1 | Spike recovery | 320 |
| CH3CONH2 and APDC | |||||||
| Sm | Wastewater | ICP-AES | Air assisted CPE | Ammonium salt of aurintricarboxylic acid and Triton X-114 | 0.06 | Spike recovery and NIST SRM 2780a (hard rock mine waste) | 321 |
| TeIV | Water, beverages | ETAAS | DLLME | APDC, choline chloride and phenol | 3.5 ng L−1 | Spike recovery | 322 |
| VIV, VV | Water | ETAAS | Dual drop LPME | 1-(2-Pyridylazo)-2-naphthol, 1 undecanol and chloroform | 1.5 (VV) and 2.4 (VIV) ng L−1 | Chinese CRM GSBZ 50029-94 (water) | 323 |
3.3. Speciation analysis
The multi-elemental speciation of As, Cr and Mo in rainwater leachates of geotechnical composites was achieved58 by compacting the composites into a lysimeter and collecting the leachates after rainfall events. The oxyanions AsO43−, CrO42−, and MoO42− were separated by fast SAX LC on a high porosity column with a linear gradient from 18 MΩ water to 0.7 M NaCl at a flow rate of 1.5 mL min−1. The LODs for a 100 μL injection and ICP-MS detection ranged from 0.16 (As and Cr) to 0.31 (Mo) ng mL−1. Spike recoveries from the sample were 100–103%. The poorer LOD for Mo was probably as a result of contamination from the pump. The results could possibly have been improved through use of an inert pump and an ion suppressor unit. Volatile organo–Br, –I, –S and –Se species in aquatic samples were collected40 on board ship by purge and trap on a mixed Tenax TA®/Carbograph 5TD sorbent cartridge, which gave optimum trapping and storage stability with analyte recoveries of 100 ± 9% after storage at −20 °C for 28 days. The analytes were thermally desorbed at 200 °C in the laboratory and quantified by GC-ICP-MS. The MDLs were 88 × 10−3 (DMDSe) to 122 (DMS) fM for a 0.5 L aquatic sample. The complete analytical cycle of desorption, separation and quantification lasted 15 min for each sample.Three methods for the determination of Gd-based contrast agents for MRI were compared.59 The first two of the methods were based on HILIC with a binary eluent gradient of acetonitrile and 12 mM ammonium formate (pH 9) at a flow rate of 0.3 mL min−1. In the first method the column was coupled to an ICP-MS instrument whereas in the second method it was coupled to an ESI-MS/MS system. Perhaps unsurprisingly, the HPLC-ICP-MS combination gave the lowest absolute LODs with all analytes detectable at sub pg levels, whereas the HPLC-ESI-MS/MS system achieved absolute LODs in the order of tens to hundreds of pg. The third method involved IC with conductimetric detection and was only able to separate unambiguously three of the seven contrast agents. The other agents had split peaks that the authors ascribed to dissociation caused by the OH− eluent. The LODs for the three agents that could be separated were in the ng range. The HPLC-ICP-MS method was successfully employed to determine Gd agents in Chinese municipal wastewater. It would have been interesting to see what improvement could have been made by coupling the IC with ICP-MS.
The standard manual method for the determination of dimethyl and elemental mercury in seawater was automated60 to overcome the instability of these species after collection and to reduce sample handling of the extremely toxic methylated mercury. Dissolved volatile species were separated from the water sample with a CF water-collection cell sparged with Hg-free air. The Hg species were trapped on Carbotrap® sorbent packed in tubes and were subsequently desorbed thermally and fed by a flow of Ar into a GC set-up for separation and AFS detection of the Hg peaks. The improved reproducibility of the automated process resulted in a reduction in sampling time from 2 h to 30 min and an improvement in LODs from the 2–25 fM achieved in previous studies to 0.2 fM. The method was successfully applied in a sampling programme off the Eastern Coast of the USA.
The HPLC-ICP-MS/MS detection of two organophosphorus pesticides and their metabolites in water was made possible61 by the use of an oxygen reaction mode in which P+ ions were detected as PO+. The organophosphorus compounds were separated, without any derivatisation, on an anion-exchange column packed with TSK gel Super IC-AZ, which has quaternary ammonium ion-exchange ligands bound to a 4 μm particle size hydrophilic porous polymer. The mobile phase was 70 mM ammonium acetate buffered to pH 3.7 at a flow rate of 0.8 mL min−1. With a 50 μL sample loop, the analytes were detectable in filtered water samples with LODs ranging from 0.03 (3-methylphosphinicopropionic acid) to 0.17 (glufosinate) μg L−1. Spike recoveries from river water ranged from 98.8 (glufosinate) to 122% (aminomethylphosphonic acid).
The elemental fractionation in suspended particulate matter from an artificial lake was investigated62 by trapping the particulate matter in a 5 mL sample onto a PTFE filter treated with poly(3,4-ethylenedioxythiophene)–poly(styrene sulfonate) in a small electrolytical cell constructed in-house. The electrochemical cell was then loaded with H2O, methanol or 0.05 mM EDTA in sequence to extract the water-soluble, organic and insoluble fractions, respectively, at a voltage of +0.8 V. The liberated ions (Cu, Mn, Ni, Pb and tetramethyl Pb, and Zn) were detected as their EDTA chelates by ESI-MS. The authors suggested that this proof of concept could one day replace the Tessier and BCR sequential extraction protocols. Feasibility was demonstrated by ICP-MS analysis of the samples after water extraction and total digestion using the standard Chinese protocol (HJ 539-2015). The ESI-MS peak areas were in the same ratios as the concentrations found in the fractions obtained by the standard protocol.
3.4. Instrumental analysis
Bazo et al.65 demonstrated the possibility of using a CS-AAS instrument as a molecular absorption spectrometer for determining Sr isotope ratios in spiked tap water. Using an Ar/CH3F gas mixture as the fluorinating agent and an Ar/H2 mixture as a purge gas, Sr isotopes could be detected as SrF molecules at 630.27 nm. Peak deconvolution was used to resolve spectral overlap between the isotopic signals. The authors stated that the method had potential for determining 87Sr/88Sr and 86Sr/88Sr ratios in naturally abundant Sr standards at concentrations above 100 mg L−1, but clearly, for most samples, this approach is unlikely to replace TIMS or MC-ICP-MS procedures.
Although the cold vapour generation of Hg0without using a reducing agent could only give67 an LOD of 0.09 μg L−1, substantially poorer than that obtained when adding such a reducing agent, the finding that Hg0 could be generated at a pH of >11 without addition of a chemical reducing agent offers the intriguing possibility of a green-chemistry method for reducing Hg2+ and CH3Hg+ ions to Hg0.
Some elements can be made volatile using electrolytic vapour generation. For instance, OsIII and OsIV ions in solution were successfully oxidised68 to the volatile OsVIII compound OsO4(g) (boiling point 130 °C) by using a RuO2-coated dimensionally stable anode and a graphite cathode in the presence of H2SO4. The OsO4 produced in solution was volatilised in a heated (>100 °C) gas–liquid separator for ICP-MS detection. The 12-fold increase in signal intensity compared to that obtained by pneumatic nebulisation resulted in a LOD of 5 pg kg−1. A portable instrument for the determination of As in water employed69 a large-surface-area Fe-coated lead oxide/lead cathode (Fe@PbO/Pb) to supply electrons for the reduction of As to AsH3(g) before detection in a miniaturised atmospheric point-discharge plasma. The method was sensitive enough (LOD of 1 μg L−1) to detect As in reservoir water.
Table 7 summarises the main advances in the application of photochemical vapour generation, a methodology not only widely used for hydride-forming elements but also commonly reported in the literature for producing volatile metal compounds from non-hydride forming elements under photochemical reaction conditions.
| Analyte | Matrix | Technique | Vapour generation reagents | LOD in μg L−1 (unless stated otherwise) | Validation | Reference |
|---|---|---|---|---|---|---|
| Hg, Ni, Se | Water, river water, fish | AFS and micro PD-AES | Formic acid and HNO3 | 0.002 (Hg) to 0.01 (Se) | NSMCC CRMs GBW08603, GBW08607, GBW(E)080395 (water) and NRCC CRMs DORM-4 (fish protein) and DOLT-5 (dog fish liver) | 324 |
| Ir | Spring, river, lake and sea waters | ICP-MS | Formic acid with Cd and Co as sensitisers | 3 pg L−1 | Spike recovery and NIST SRM 2556 (used auto catalyst) | 325 |
| Sb | Water, sediments | ICP-MS | Formic acid, acetic acid and VIV sensitiser | 4.7 ng L−1 | NRCSM CRMs GBW07303a, GBW07305a (sediment) and spike recovery | 135 |
| TeIV | Water | AFS | Formic acid and acetic acid, with release of Co from, and preconcentration of Te on Co-MOF-74 | 0.08 | Spike recovery | 326 |
Microplasmas or discharges can replace pneumatic nebulisation and generate volatile species in a discharge in contact with the sample solution. A microplasma improved70 the ICP-AES analytical signal intensities for Ag, Bi, Cd, Pb, Tl and Zn by 2–13 times and by over 30 times for Hg. The improvement was ascribed to the higher analyte fluxes and less water vapour produced by the microplasma. The LODs were 0.06 (Hg) to 0.4 (Ag) μg L−1 and the recoveries from spiked tap and seawater were 98–113%. A plasma electrochemical vapour generator was coupled71 with MC-ICP-MS to improve Cd isotopic analysis. The VG improved the signal six-fold compared to that obtained with nebulisation, and removed the need for a desolvation unit before the ICP-MS unit. The matrix separation inherent with VG meant that only one step was required in the sample purification so the sample processing took only 3 h compared to the 72 h required for the method used previously. The δ114Cd/110Cd value of 0.00 ± 0.06 (2SD, n = 25) determined for the NIST SRM 3108 (Cd standard) at a concentration of 8 μg L−1 agreed well with results obtained after sample purification and isotope-ratio determination under dry plasma conditions.
The intensities of analytical lines with low excitation energies are affected by the presence of easily ionisable elements in the nitrogen plasma of MP-AES instruments. This was overcome73 by the addition to the sample of elements with low IPs, such as Al, Ba, Eu, Ga, In, La, Rb and Sm, at concentrations between 75–100 mg L−1. Recoveries of 85 (Ba) to 99% (Mg) for Ba, Ca, K, Li, Mg and Na in lake sediment pore waters were achieved through the addition of In. The sensitivity of an MP-AES instrument was rather unsurprisingly improved74 by addition of a commercially available enhanced nebulisation system with desolvation. Although the performance was still not as good as that achievable by ICP-AES, the three-fold improvement in LODs allowed detection of Al, Cd, Co, Cr, Cu, Fe, Mn, Mo, Ni and Pb in the NIST SRM 1643e (trace elements in water) (concentrations ranging from 6.5 (Cd) to 141.8 (Al) μg L−1) and Cr, Cu and Mo in several Brazilian mineral waters.
The interference-free ICP-MS/MS determination of the radionuclide 129I was made possible77 by the addition of a flow of O2 into the DRC to lower the 129Xe background and by the use of CO2 as reaction gas to lower the 129IH2+ background signal. Using both gases simultaneously resulted in a LOD of 0.73 mBq L−1 (0.11 ng L−1) thereby making it possible to determine 129I in rainwater without any chemical separation even in the presence of up to 100 mg L−1 127I. The use of N2O as a reaction gas improved78 slightly the determination of REEs in river water by boosting the yields of 153Eu16O+ and 172Yb16O+ in the reaction cell in mass shift mode. In addition, Ba-related spectral interferences on Eu were suppressed so there was no need for spectral interference corrections. The LODs improved from 0.024 (O2 gas) to 0.01 (N2O gas) pg mL−1 for Eu, and from 0.06 (O2 gas) to 0.023 (N2O gas) pg mL−1 for Lu. The method was successfully validated against the NRCC CRMs SLRS-3 and 4 (river water). In the HG-ICP-MS determination of Te, elimination of 128Xe and 130Xe interferences on the most abundant isotopes 128Te and 130Te meant79 that an LOD of 0.07 ng L−1 could be achieved, thereby making the determination of Te in lake, river, bottled and seawaters possible. Results for total Te in six CRMs agreed well with certificate values.
3.4.4.1. Nanoparticle analysis. A new sampling protocol was developed80 with the aim of quantifying nanoparticles at real world concentrations by ICP-MS. Seawater was filtered immediately after collection through 0.45 μm polycarbonate membrane filters to obtain a “dissolved” metal sample. The sample was then spiked with silver, TiO2 and ZnO NPs and homogenised for 5 min before ultrafiltration of a 0.5 mL sample through a 3 kDa cut-off ultrafiltration tube conditioned for 15 min with Cu(NO3)2 to decrease ion absorption. The trapped particles were dissolved in 30% v/v HNO3. The filter was washed with ultrapure water and the wash combined with the sample to give a 3–5% v/v HNO3 solution for analysis by SF-ICP-MS. The LODs expressed as metal concentrations were 0.06 (Ag) to 17.5 (Zn) μg L−1 and the recoveries ranged from 87% for Ag to 109% for Zn. Although NPs were not detected in unspiked samples in this study, in later work81 this method was successfully used to detect NPs in seawater up to 2 km from the coast of the Black Sea.
The pretreatment of samples for single particle ICP-MS analysis has been investigated. Natural colloidal particles were determined82 in lake water after filtration or centrifugation. Perhaps counter intuitively and in contrast to the method reported above in which NPs and colloids were trapped on ultrafilters, in this study samples were filtered and the filtrate analysed. Polyethersulfone membrane filters with three pore sizes were investigated to see which gave the best recovery. When samples were filtered through a conventional 0.45 μm filter, many natural colloids and particles of 100–200 nm size were removed. Increasing the pore size to 3 μm improved NP and colloid recovery in the filtrate. Surprisingly, however, a larger number of smaller particles were found when a 0.22 μm filter was used probably because the higher pressure required broke up the agglomerates. Further experiments showed that centrifugation at 2000 rpm had a similar particle selectivity as filtration through a 3 μm filter. Similar results were found83 during the determination of silver NPs in tap and surface waters and sewage effluent. The recovery of NPs from surface water samples spiked with 60 nm diameter silver NPs increased from 60% for a 0.22 μm filter to 90% for a 0.8 μm polyethersulfone membrane filter. Transmission electron microscopy of membranes showed that heating membranes to 100 °C and then cooling them increased the mean pore size of the filters and so further improved the NP recovery. To improve the determination of microplastics in river water, samples were pretreated84 with 10% HNO3 for 24 h at room temperature as an alternative to filtering. This pretreatment removed DOC, carbonates and microorganisms thereby decreasing the C background in sp-ICP-MS. A particle recovery of 80% was obtained for river water spiked with polystyrene particles (2–3 μm particle size). The reduction in background signal resulted in a five-fold increase in the number of particles that could be detected.
3.4.4.2. Isotope analysis. The determination of Hg isotope ratios was improved85 by the development of a purge-and-trap system that was coupled to a MC-ICP-MS instrument. The samples were treated in 40 mL vials with 0.1 mL of 20% m/v SnCl2 to convert the Hg ions into Hg0, which was collected on gold traps for analysis. The Hg concentration (8 ng L−1) needed for accurate isotope ratio determinations was close to concentrations found in uncontaminated environments.
A procedure for the isotopic analysis of Sb in water samples at low concentration (<1 μg L−1) involved86 the addition of 200 μL of a 25% v/v BrCl solution to a 200 mL sample to digest all the DOM in the sample. A mixture of KI, hydroxylamine hydrochloride and ascorbic acid was added to this digest to remove excess BrCl and to convert any SbV present to SbIII. The SbIII was then preconcentrated onto a column with a thiol resin (CleanertSH, pore size 60 Å and grain size 40 mm) and eluted for HG-MC-ICP-MS analysis. No fractionation was observed during sample preparation, and Sb isotope ratios could be determined for samples with Sb concentrations as low as 0.01 ng mL−1.
In a rapid procedure for the separation of U from environmental matrices, the U was preconcentrated87 from a 100 mL sea water sample by Fe(OH)3 coprecipitation. The precipitate was dissolved in 3 M HNO3 for sequential separation of the matrix from U on a TK200 resin column. The first elution step removed the main interfering elements (Au, Hg, Np, Pb, Pt, Tl), main matrix elements (Al, Ca, Fe, K, Mg, Na) and the REEs. The second elution step stripped out the Th, and the final step isolated the U. This final eluate was evaporated to dryness and then redissolved in 2% v/v HNO3 for analysis by MC-SF-ICP-MS. The method was validated for seawater against the CRM IAEA-443 (Irish Sea water). The U was preconcentrated 30-fold with a 90% recovery. A batch of 20 samples could be treated within 6 h, faster than by methods requiring multiple extraction columns.
Improved sample pretreatments mean that the LIBS detection of trace elements in water at natural concentrations is becoming closer to being feasible. For example, by preconcentrating Pb in a 5 mL sample onto 0.1 g of a macroporous cation exchange resin with weakly acidic iminodiacetic acid groups, it was possible90 to detect Pb at concentrations down to 88 ng L−1 using LIBS-LIF interrogation of the resin. This was not quite low enough to detect Pb in canal and tap waters at natural concentrations. Recoveries from spiked samples (2 and 10 μg L−1 spikes) were between 91 (canal water) and 103% (tap water).
The use of LIBS has been extended to the determination of non-metals in water. A LOD of 0.1 mg L−1 for P in river water was achieved91 by SPE of P onto FERROLOX®, an iron-hydroxide-based MOF. The solid (unreported amount) was isolated from the sample (unreported volume) before LIBS analysis. The method wasn’t yet sensitive enough to determine natural P concentrations but recoveries of >96% were obtained for 0.5 mg L−1 spikes.
What is noticeable this year is that practitioners of LIBS seem to be blissfully unaware of the existence of RMs or the need for method validation. Now that LODs are approaching useful levels, better analytical rigour is required and should be encouraged by referees.
Significant efforts continue to be made to develop preconcentration methods for XRFS analysis. Some of those studies are presented in Tables 5 and 6. The freeze drying of water onto a quartz glass substrate resulted93 in a film-like residue suitable for TXRFS analysis with LODs of 6 (Sr) to 51 (Ca) ng g−1.
By combining the utility of portable XRFS with on-site preconcentration, it was possible94 to determine Cu, Mn, Ni, Pb, U and Zn in spiked lake and ground waters in the field. Analytes in a 10 mL water sample were immobilised onto a nanoporous filter based on bisphosphonate-modified thermally carbonised porous silicon. The results obtained by this method were not significantly different from those obtained by ICP-MS for the concentration range 50–10000 μg L−1. The LODs of 35 (Cu) to 103 (Mn) μg L−1 showed that this method was a viable field-screening test for the identification of contaminated waters such as mine waters.
4. Analysis of soils, plants and related materials
4.1. Reviews
Three reviews covered techniques for elemental analysis of plants. El Hosry et al.95 (177 references) provided an accessible introduction to FAAS, ICP-AES, ICP-MS and XRFS, together with guidance on the selection of techniques for the analysis of plant-based foods. Ibourki et al.96 (224 references) discussed similar topics but also featured LIBS and NAA. Aleluia et al.97 (152 references) included herbal medicines and medicinal plants in their review of analytical approaches for the determination of trace element impurities in pharmaceutical products.The spectrometric characterisation of NPs in biological and environmental samples was the topic of a critical review98 (116 references) that discussed the determination of: NP synthesis yield; particle size and particle number concentration; elemental and isotopic composition; and surface properties.
Arsenic proved a popular topic for element-specific reviews with no fewer than three being published during the period covered by this ASU. With reference to soils and waters, both Patel et al.99 (238 references) and Valskys et al.100 (177 references) discussed As contamination, quantification, sources, mobility and health hazards. Mihucz101 (222 references) focused on As speciation and analysis in soil, water, foods and Ayurvedic medicines. Methods for extraction, separation and detection of Se-enriched proteins and peptides in plants were included in a review by Xiong et al.102 (136 references) that also covered bioavailability and bioactivity.
4.2. Reference materials and interlaboratory comparisons
Examples of new or improved isotopic data for CRMs or RMs obtained by MC-ICP-MS included:• δ25Mg and δ26Mg values in five soils, four river sediments and five plants using Alfa-Mg, a new delta-zero reference solution for Mg isotope ratio measurement.103
• δ34S values in GBW07410 (soil), ERM-CD281 (rye grass) and NIST SRMs 2704 (river sediment) and 1515 (apple leaves) derived through an inter-laboratory study.104
• δ65Cu, δ56Fe and δ66Zn values in two soils and three sediments.105
• δ66Zn values in three NIST soil SRMs and nine Chinese soil CRMs.106
• δ146Nd values in three soils, one loess and eight sediments.107
The mass fractions of 48 analytes, including the REEs and the technology-critical elements Be, Bi, Ga, Ge, Li, Nb, Sb, Ta and Tl, were determined108 in seven plant CRMs by ICP-MS/MS to provide benchmark values for future studies. Krata109 reported the first information on Hg speciation in a soil CRM, EnvCRM 03 from the National Metrology Institute of Turkey. Values determined by SSID-HPLC-ICP-MS were 316 ± 10 μg kg−1 for inorganic Hg and 0.54 ± 0.03 μg kg−1 for MeHg. The MeHg content was verified as 0.54 ± 0.03 μg kg−1 by off-line chromatographic separation and quantification by MeHg SSID-ICP-MS.
A German interlaboratory exercise with 28 participants compared110 two aqua regia digestion methods and three analytical techniques for the determination P in sewage sludge. Microwave-assisted digestion according to Method EN 16174 was preferred to digestion under reflux (Method EN 13346), and ICP-AES was preferred to ICP-MS or spectrophotometric determination because this combination gave highest P recoveries and best precision.
4.3. Sample preparation
Digestion procedures for soils and plants included that of Kochergina et al.112 who combined matrix-specific acid digestion protocols and appropriate column chemistry for the determination of Nd, Pb and Sr in a broad range of environmental and archaeological materials including low-Nd silicates, carbonates, carbonatites, organic soil, plants, water, wood, alloys, bones and teeth. Analytes were determined by TIMS (Nd and Sr) or MC ICP-MS (Pb). The procedures, which are useful for laboratories handling diverse samples, were successfully verified with isotopic RMs. Dynamic versions of the SBET were successfully developed113 for As, Cd, Cr, Cu, Fe, Mn, Pb and Zn in PM10. Extractants were introduced continuously onto simulated PM10 samples prepared from NIST SRM 2711A (Montana II soil) and BGS 102 (Ironstone soil) loaded on TX40 filters in polycarbonate filter units. The extract eluted from the unit was either collected offline as subfractions for analysis by ICP-MS or introduced continuously into the nebuliser for online analysis. Element concentrations in residual samples were also determined. Mass balances determined by both online and offline methods agreed well with results from the analysis of separate test portions. Concentrations of 1100 ± 127 mg kg−1 and 1170 ± 135 mg kg−1 (n = 3) for bioaccessible Pb determined for NIST SRM 2711A by the offline and online methods, respectively, did not differ significantly from the certified value of 1110 ± 49 mg kg−1. In addition, there was no significant difference between the bioaccessible PTE concentrations determined by the online and offline methods (Student’s t-test, 95% CI, n = 3), indicating that both dynamic methods are suitable for the determination of bioaccessible PTEs in PM10.
Electrothermal digestion with powdered NH4F was proposed114 for the determination of the halogens Br, Cl and I in soils and sediments. During the high-temperature digestion (optimised conditions: 220 °C, 2 h, 400 mg NH4F, for 50 mg soil or 100 mg powdered rock/sediment samples), NH3 released from the decomposition of molten NH4F prevented loss of the sample halogens, which were leached from the resultant solid residue with 5% (v/v) aqueous ammonia. The SF-ICP-MS LOQs were 0.018, 2.8 and 0.003 μg g−1 for Br, Cl and I, respectively. Concentrations determined for Br and I in of a suite of 56 Chinese soil and sediment RMs were not significantly different from the reference values for most RMs but for Cl, positive relative measurement errors were as high as +48%. The authors suggested that this was due to the decomposition of refractory minerals by the NH4F digestion. The mass fraction measured for I in RM GSD 13 of 0.17 ± 0.03 μg g−1 was lower than the certified value of 0.3 ± 0.1 μg g−1, so the authors proposed a revision of the certified value.
Reaction ‘minivessels’ were constructed115 for the MAE of small-mass biological samples. The internal volume of 3 mL and external diameter of 1.2 cm enabled three of the Teflon minivessels to be placed simultaneously on the platform of a standard 100 cm3 autoclave (EasyPrep) of a MARS-5 microwave system. Digestions were performed with only 10–20 mg of sample and 1.5 mL acid per minivessel. Results from the ICP-MS analysis of CRM INCT-TL-1 (Argentine black tea leaves), CTA-OTL-1 (oriental Bulgarian tobacco leaves), CTA-VTL-2 (Virginia tobacco leaves) and IAEA-153 (milk powder) were not significantly different to certified values (n = 4–6) at 95% confidence. New data were also obtained for the concentrations of B, Bi, Ga, Nb, Tl, Y and REEs in these RMs.
In a comparison of acid digestion methods for the determination of Al, Cd, Mg and Mn in plant samples, Bankaji et al.116 concluded that the most effective method was both element- and species-specific. Analyte concentrations in five different plant species, determined by AAS, did indeed vary significantly depending on the plant species, acid mixture and extraction conditions. Results obtained for the analysis of RMs following the same digestion procedures are troubling: for CRM BCR 62 (Olea europaea) the measured concentrations were 1145–7730 mg kg−1 for Al (certified value 450 mg kg−1), 175–251 mg kg−1 for Cd (certified value 0.1 mg kg−1) and 101–1106 mg kg−1 for Mn (certified value 57 mg kg−1). The Cd concentrations measured for BCR 279 (Ulva lactuca) were 168–243 mg kg−1 (certified value 0.274 mg kg−1). The authors interpreted these differences as evidence of a highly efficient digestion but the deviations from the certified values were so large that real experimental errors must be considered.
Platinum NPs from vehicle emissions can accumulate in roadside soils in urban environments and so should be monitored to assess population exposure. Ultrapure water and 0.005% FL70 (a commercial alkaline detergent) were compared117 for the stabilisation of platinum NPs extracted from soil. The extraction involved several vortex, sonication and centrifugation steps, performed with and without addition of 0.1 M NaCl. After extraction, either ultrapure water or 0.005% FL70 were added to aid dispersion of the NPs prior to sample analysis by sp-ICP-TOF-MS. The methods were tested with LKSD-1 (lake sediment) spiked with 820 ± 150 NP mL−1. Extraction with FL70 was more efficient than with ultrapure water, with particle number recoveries between 117–137% (with NaCl) and 78–102% (without NaCl).
Natural and recycled materials were in fact employed in several separation and preconcentration methods for elements other than Hg. A novel and rapid CPE ICP-AES method119 for the simultaneous determination of Cd and Ni utilised a DES as an environmentally friendly reagent. The DES, based on L-menthol and n-hexanoic acid, decreased the cloud point temperature of TX-114 and so enabled the rapid extraction of Cd and Ni at room temperature. Under optimised conditions, the LODs were 0.01 and 0.05 μg L−1 for Cd and Ni, respectively. No statistical differences (Student’s t-test, no CI presented) were found between the concentrations of Cd and Ni in Salvia yunnanensis samples, indicating that the method was a suitable low-temperature CPE alternative for extraction of Cd and Ni.
Current research suggests120 that the microbial toxicity of amino acids-based DESs may be lower than that of other DESs. An innovative UA matrix solid-phase dispersion method with amino acids-based DESs was developed121 for the extraction of As from medicinal herbs. Powdered DES precursor was dispersed directly with the sample into tubes and, following UA solid-phase-dispersion, ultrapure water was added to the mixture, which was then ultrasonicated. After phase separation on filter paper, supernatants were analysed by ICP-MS. The method LOD was 0.039 mg kg−1 under conditions optimised by Doehlert design (50 °C, 60 min and a sample–solvent ratio of 10:1 mg mL−1). Beta-alanine–citric acid–water (1:2:17 molar ratio) was the most effective DES for As extraction. The results (n = 3) from the analysis of NIST SRM 1547 (peach leaves) and EMBRAPA E1001a (Marandu) of 0.05 ± 0.0014 and 1.71 ± 0.284 mg kg−1, respectively, did not differ significantly from the certified values of 0.062 ± 0.014 and 1.69 ± 0.70, respectively. The overall ‘greenness assessment’ of the method, based on the analytical eco scale,122 was 94 out of a possible maximum of 100 for total sustainability, clearly better than the score of 83 for MAD with HNO3 and H2O2.
Recycled facemasks were used in a novel stir-bar sorptive method123 for the extraction of Co, Ni and Pb from plant and water samples. The bar was made by inserting an iron wire into chopped up, meltblown layers of facemask and was saturated with a synthesised DES (choline chloride:3,4-dimethylphenol). The bar was then immersed into 100 mL of digested (plant) or acidified (water) sample containing 2-(5-bromo-2-pyridylazo)-5-diethylaminophenol chelating agent and sodium acetate buffer. After stirring (6.0 min, 375 rpm), the complexed analyte ions were extracted with 4.0 mL of 1 M HNO3 in THF under sonication for 30 s and determined by FAAS. Under optimised conditions, the linear ranges were 3–150, 2–150 and 7–500 μg L−1, and the LODs were 0.91, 0.61 and 2.3 μg L−1 for Co, Ni, and Pb, respectively. The results of 9.8 ± 0.3, 48.6 ± 1.4 and 25.1 ± 0.6 μg L−1 for SPS-SW2 (surface water I – trace metals) did not differ significantly from the certified values of 10 ± 0.05, 50 ± 0.3 and 25.0 ± 0.1 μg L−1 for Co, Ni and Pb, respectively. Similarly, the results of 61.8 ± 1.5, 71.0 ± 1.8 and 71.2 ± 2.1 μg L−1 for Sigma-Aldrich RM QC-1187 (trace metals ICP sample 1) did not differ significantly from the certified values of 62.2 ± 1.1, 72.5 ± 1.3 and 72.8 ± 1.3 μg L−1 for Co, Ni and Pb, respectively. The method was also applied to samples of dill, coriander and spinach.
Methods for speciation analysis are particularly welcome for elements for which the oxidation state directly affects species mobility and toxicity. An HR DGT technique used with LA-ICP-MS analysis enabled124 the selective and simultaneous 2D chemical imaging of AsIII, CrIII and SbIII at the sub-mm scale for the first time. Whereas trivalent species were selectively accumulated on a mercapto-functionalised attapulgite binding gel, <2% of the higher oxidation state species were accumulated. Uptake was unaffected by pH (3.2 to 8.2) and sorption capacity was 72, 44 and 79 μg per DGT device for AsIII, CrIII and SbIII, respectively. There was a linear relationship (r2 > 0.99) between species uptake and LA signals, and analytical precision was adequate (RSD < 10%).
Other separation and preconcentration methods for the analysis of soils, plants or related materials, or those developed for other sample matrices that used soil or plant CRMs for validation, are summarised in Table 8 (SPE methods).
| Analyte(s) | Matrix | Technique | Extraction mode/reagent(s) | Findings/comments | Validation | Reference |
|---|---|---|---|---|---|---|
| Ag | Soil, water | HR-CS-ETAAS | UA dispersive μSPE with bentonite sorbent | pH, sorbent mass, ultrasound time and HR-CS-ETAAS parameters optimised, preconcentration factor = 34, RSD 5% | NIST SRM 2709 (San Joaquin soil), NIST SRM 2711 (Montana soil), NIST SRM 1643e (trace elements in soil) | 127 |
| Cd | Lake and mineral waters, tomato leaves | Flame-furnace AAS | Vortex-assisted dispersive magnetic SPE with Fe3O4@C | Nanocomposite characterised by ATR-FTIR, SEM, VSM, XRD. Optimised conditions: 10 mL sample, 2 mg sorbent, pH = 8. Magnetic particles collected by stainless steel rod. Linearity 15–750 ng L−1, RSD 1–4% (n = 10) | NIST SRM 1643e (water), SRM-1573a (tomato leaves) | 327 |
| Co, Ni | Food, juice, and water samples | FAAS | UA dispersive μSPE with multiwalled CNT and 3-(2,4-dihydroxyphen-1-ylazo)-1,2,4-triazole chelating agent | Effective at pH = 8. Linear range 1.0–200 μg L−1 for Co and 2.0–300 μg L−1 for Ni | NIST SRM 1570A (spinach leaves), TMDA-52.3 (enriched water) | 301 |
| Cu | Artichoke leaves | SQT FAAS | Dispersive SPE with CdS-NPs | CdS precursor synthesised from microwave-assisted reaction. Sorbent characterised by FTIR, SEM and XRD. Optimum conditions: 40 mL sample volume; 0.1 mL buffer (pH 4); 7.5 mg CdS NPs; 30 s sonication; 100 μL HNO3. Linear range 2.5–30 μg L−1 | Spike recovery (artichoke leaf extracts) | 328 |
| Ga, In | Electronic devices (mobile phones, non-touch laptop screens, diodes of LED bulbs), soil, water | ETAAS | Dispersive SPME with Fe3O4 | Ga desorbed with 2 M NaOH (50 μL), In desorbed with 4 + 1 mixture of 0.1 M EDTA and 2 M HNO3 (50 μL). Linear range 0.1–15 μg L−1 for Ga, 0.05–1 μg L−1 for In | NIST SRM 2711 (Montana soil); NCS DC 73319a (soil); ECCC TM-25.4 (water) and TMDA-62.2 (water) spike recoveries | 305 |
| Ni | Cornflakes sage, green tea, yogurt | HR CS FAAS | Magnetic SPE with Fe3O4@ Diaion HP-2MG resin, 2-(5-bromo-2-pyridylazo)-5-(diethylamino)phenol chelating agent | 0.15 mg sample, 15 mg sorbent, pH = 8, 3 M HNO3 eluent (0.4 mL), 60 s vortex. Resin reused 15 times without performance degradation. pH, sorbent mass and sample volume optimised | NIST SRM 1573a (tomato leaves) ECCC TMDA-64.3 (fortified water) | 306 |
| Pb | Food, water | FAAS | Dispersive magnetic SPE with MWCNTs@MgAl2O4@TiO2 nanocomposite | Nanocomposite synthesised using sol–gel method and characterised by FTIR, SEM and XRD. pH, sorbent mass and sample volume optimised | ECCC TMDA 64.3 (fortified lake water), NCS DC 73349 (bush, branches and leaves) | 329 |
| Pb | Biscuit, chili oat flour, chili pepper (dried), garlic, infant formula, pepper, sumac tobacco, water | FAAS | Dispersive μSPE with Ag modified ZnO nanoflowers | Nanoflowers synthesised by hydrothermal method and characterised by BET, EDX, FESEM, FTIR, XRD. Optimised conditions: 500 mg sample, pH = 4, 6 mg sorbent, 0.25 M HNO3 eluent (0.4 mL) | Chinese RMs GBW07424 (soil) and GBW07425 (soil) | 330 |
| Pd | Medical devices, soil, water | HR-CS-FAAS | SPME with Ti3AlC2 max phase graphene oxide nanocomposite | Nanocomposite characterised by EDXRFS, FTIR, SAA, XRD. pH, sorbent mass, sample volume, vortex time, desorption conditions were optimised | Spike recovery (medical devices, soil and water) | 307 |
| Rh | Soil | SQT-FAAS | Dispersive SPE with magnetic colloidal gel (MCG) | MCG produced by mixing Fe3O4 based magnetic NPs and DES (choline chloride and phenol 1:3). Optimised conditions: 5 g dried soil, pH = 7, 125 μL DES–MCG, 14.7 M HNO3 eluent (75 μL) |
Spike recovery (soil extract) | 331 |
| Rh | Soil | FAAS | Dispersive SPE with MnFe2O4 NPs | pH, buffer volume, sorbent mass, sample volume, eluent concentration and volume were optimised | Spike recovery (soil extracts) | 332 |
4.4. Instrumental analysis
Analytical methods based on HR-CS-ETAAS are becoming more widely used. A simultaneous quantification of Fe and Zn in plants was based126 on spectral lines at 307.572 nm (Fe) and 307.588 nm (Zn), both of which fell within the spectrometer bandpass. The LODs were relatively poor (0.05 mg L−1 for Fe and 0.02 mg L−1 for Zn) for an ETAAS method, due to the selection of low-intensity secondary lines, but adequate for the routine analysis of vegetable samples. Accurate results were obtained127 for the determination of Ag in soil following preconcentration on bentonite and slurry-sample introduction. The values obtained for NIST SRMs 2709 (San Joaquin soil) and 2711 (Montana soil) were not significantly different from certified values according to a Student’s t-test at 95% confidence. The LOD was 0.01 μg L−1 for a sample volume of 20 μL.
The Zr-based MOF UIO-66-NH2 was synthesised,128 characterised and successfully used as a novel matrix modifier in the determination of Cd in soil by ETAAS. Capture of Cd within the MOF helped stabilise the analyte during the pyrolysis step of the heating programme and thereby yielded a 30% improvement in sensitivity relative to conventional Pd(NO3)2 modification.
Phytoavailable elements in soil were measured130 with a dielectric barrier discharge microplasma. A 0.1 M NaNO3 extract was diluted 30-fold before electrochemical accumulation of analyte cations onto an activated-carbon-electrode tip and in situ desorption into the plasma. The LODs for Cd, Cu, Pb and Zn were 0.8–6.0 μg kg−1 and results for IRMM CRM BCR 483 (sewage sludge amended soil) were not significantly different from indicative NaNO3-extractable concentrations, according to a Student’s t-test at 95% confidence.
A new approach for improving sensitivity in the determination of Hg in environmental samples involved131 plasma-induced VG and FI gas analysis. Initially, analyte vapour was produced by a solution-anode GD unit operating without carrier gas flow (the accumulation stage). Then gas flow was restored, and the concentrated vapour swept into the ICP (the injection stage) to generate a transient signal analogous to conventional liquid sample FIA. Even though the signal increased up to an accumulation time of 120 s, a 60 s time was selected to maintain sample throughput. Recoveries of spikes from dilute HNO3 extracts of two spiked urban soils were 102 ± 11% and 104 ± 5% (n = 3).
Progress has been made in the development of methods for the direct analysis of soil by ETV-AFS. A miniature nickel foam trap was positioned132 between a modified commercial ETV unit and spectrometer for gas-phase enrichment of Cd. Analyte trapping efficiency was 100% and the LOD was 0.035 ng g−1 for a 20 mg sample. Subsequently, an improved system for simultaneous measurement of Cd and Hg was constructed133 by incorporating the same type of metal ceramic heater discussed in Section 4.4.1 of this ASU together with a novel platinised nickel trap. Following stepwise vaporisation and trapping of the analytes (Hg at ca. 500 °C under air and Cd at ca. 1000 °C under Ar/H2), the trap was heated and the analytes released. Accurate results were obtained for Chinese soil CRMs GSS-2a, GSS-16 and GSS-22 (Student’s t-test, 95% confidence). Spike recoveries for real soil samples were 102–105% for Hg and 96–104% for Cd.
New vapour generation methods for use with ICP-MS continue to be developed. Dong et al.135 applied the procedure for the vanadium-assisted PVG of Te, noted in our previous ASU,1 to the determination of Sb. Addition of 80 mg L−1 VIV followed by 100 s UV irradiation increased the signal three-fold (relative to when no catalyst was present) and gave a LOD of 4.7 ng L−1. However, sensitivity was still only half of that achieved with cobalt-assisted PVG. Liu et al.71 successfully used plasma electrochemical VG in a rapid and cost-effective approach for the determination of Cd isotopes by MC-ICP-MS. The procedure was at least 20 times faster than the usual method (a two-step anion-exchange-resin purification followed by membrane desolvation) and had improved tolerance to matrix elements. Results for δ114Cd in two soil, three sediment and one basalt RM were similar to those reported by other researchers.
Although the coupling of chromatographic separation with ICP-MS is now routine, procedures continue to be developed, optimised and validated. Examples included: an HPLC-ICP-MS method136 for As speciation in soil extracts prepared by MAE in 0.5 M phosphoric acid; an HPLC-ICP-MS method137 for As speciation in foods of plant origin that was applied to cereals, seaweed and vegetables; and an HPLC-ICP-MS method138 for Sb speciation in soils, which was used to compare the impacts in southern Poland of a slag heap from a historical Pb/Zn mine, a modern WEEE plant and a motorway. Of particular interest to the wine enthusiasts amongst the ASU readership was an IC-ICP-MS method based on detection of the PO+ ion that could detect139 residues of phosphonic acid, a substance banned from use in organic viticulture in the EU since 2013. The method offered at least 20-fold lower LODs for both solid (grapes, leaves, pomace, roots, soil, stems) and liquid (wine, wine must, xylem sap) samples than the approach currently used (IC with a conductivity detector). When applied to 130 samples from across France, Germany, Italy and Spain, the mean results for phosphonic acid were 4.32 mg kg−1 for conventional wines and 0.32 mg kg−1 for organic wines.
A rapid-cooling cryogenic sample chamber facilitated140the imaging of plant tissue by LA-ICP-MS. The temperature could be lowered to −20 °C in 4 min and remained stable (±0.1 °C) for 10 h. The LODs for Cu, Fe and Zn in spiked agarose-gel calibrants improved 1.6-, 3.3- and 1.7-fold, respectively. Better spatial resolution was obtained during ablation of fresh coriander leaves as the cryo-chamber minimised heating and so tissue damage and loss of water were kept to a minimum. The same approach was applied141 in a comparison of the distribution and effects of Ce3+ ions and CeO2 NPs taken up into cucumber leaves.
The analytical capability of a nitrogen-microwave inductively coupled atmospheric-pressure plasma was demonstrated142 through accurate determination of As, Cd, Co, Cr, Cu, Pb, V and Zn concentrations in seven soil RMs from BAM. Except for Ni, which was overestimated by MICAP-MS due to the presence of a nickel skimmer cone, results were comparable to those obtained by ICP-MS and similar to the reference values. The LODs of 2.11 (V) to 103 ng L−1 (Ni) were slightly poorer than those obtained by ICP-MS (except for Pb) but were nevertheless still fit for purpose. The lower operating costs were a major advantage of the new instrument.
An improved ICP-MS/MS method for measuring 135 Cs/ 137 Cs ratios in samples with low radiocaesium content combined143 the authors’ previously reported extraction and purification procedure with introduction of a novel gas mixture to the collision–reaction cell. The N2O (0.55 mL min−1) + He (1 mL min−1) + NH3/He (10 + 90 m/m, 4.79 mL min−1) gas mixture proved effective for removal of interference from residual Ba, Sb and Sn. The 135Cs and 137Cs LODs were 1.66 and 0.67 fg g−1, respectively. Results obtained for CRMs IAEA 330 (spinach) and IAEA 375 (soil) agreed with previously published values.
Discriminating between different types of NPs in soil remains challenging, in particular for engineered and natural NPs of similar composition. However, some advances have been made. A dual-analyte sp-ICP-MS procedure for distinguishing kaolinite and goethite NPs was based144 on the detection of three types of events: Al unpaired events; Fe unpaired events; and paired events. Particle numbers and sizes were consistent with results obtained by single-analyte sp-ICP-MS. The ability to recognise soil NPs with different mineralogy is important because of their role in biogeochemical cycling of PTEs. The capability of sp-ICP-TOF-MS to provide multi-element information on individual particles allowed Taskula et al.117 to identify naturally-occurring Pt-containing NPs in lake sediment NRCC CRM LKSD-1. This approach was based on the co-detection of Pt with Au, Bi and Ir, which are not present in engineered platinum NPs. When the CRM was spiked with engineered platinum NPs, 31–78% of the NPs formed mixed aggregates with sediment particles. Bland et al.145 also used sp-ICP-TOF-MS in their study of the behaviour in soil of 47Ti-enriched TiO2 NPs, which could be distinguished from natural nanomaterials based on isotope analysis.
An analytical workflow for characterisation and quantification of engineered nanoparticles in biological tissues provided146 useful guidance to researchers. Covering both sample preparation and analytical approaches such as single cell ICP-MS, sp-ICP-MS and synchrotron-based techniques, the protocol could be adapted for use in a variety of studies.
Research continues into means for enhancing signal intensity in LIBS analysis. Zhou et al.149 investigated NP-enhanced LIBS for the determination of Cu, Fe, Mn and Zn in soil. Silver NPs were either deposited on top of a pressed soil pellet or dried onto a glass slide and overlain with a 2 M HCl soil extract that was dried prior to ablation. The second approach gave better performance. Calibration curves prepared using a series of Chinese GBW soil CRMs had r2 > 0.98 for all four elements. Sensitivity for the determination of Hg in dried tangerine peel was improved150 six-fold by coating the sample pellet with gold NPs and purging the sample stage with 15 L min−1 of Ar to reduce quenching of analyte emission lines by oxygen. A comparison of different sizes and shapes of NPs led to the selection of 40 nm Au nanocages at a surface concentration of 1.77 × 10−3 mg cm−2 as being optimal. By studying the effect of KCl addition and sample temperature, Li et al.151 found that signal intensities for Al and Cd in lake sediment were enhanced (1.6- and 2-fold, respectively) in the presence of 15% KCl at 180 °C compared with analysis at room temperature without the additive. Meng et al.152 achieved similar improvements (2.5 to 2.8-fold increase in signal for Al, Cd, Fe and Pb in soil) at 180 °C with planar mirror confinement (an approach in which the sample is ablated between two parallel mirrors to compress the plasma plume into a smaller volume) rather than by chemical addition. Amador-Mejia153 also recommended sample heating but to a higher temperature (400 ± 20 °C), together with re-excitation of the laser plasma using a high-voltage discharge. This gave an up to seven-fold increase in signal intensity for As, Be, Cd, Cr, Ni, Pb, V and Zn in loam soil. Two remarkably similar articles by Rahim et al.154,155 explored the impact of magnetic field confinement and laser fluence on the emission lines of As, Ba, Co, Cr, Mn and Ti in river sediment samples. They claimed up to six-fold enhancement under optimised conditions. The novel APGD cylindrical-confinement approach discussed in last year’s ASU1 was applied156 to improve LODs in the determination of selected REEs in soil.
Although something of a contradiction in terms of nomenclature, a calibration-free LIBS method with one-point calibration decreased157 matrix effects in the determination of Ca, Fe and Mg in soybean leaf samples. Results were first normalised to a TiO2 IS added to the sample pellets at a concentration of 0.5 wt% and then empirical corrections, based on the results for one sample, were applied to the emission line intensities in the other samples. An RMSE of <10% relative to AAS data was achieved. The same approach was later applied158 to measure Hg in soil and the residues from dried landfill leachates. Samples were first analysed under optimised conditions by DP-LIBS and then corrections based on one sample type (the soil) were applied throughout. The mean relative absolute error in the concentration predicted for analysis of two sandy loam CRMs was improved from 89 to 6.9%.
An alternative approach for reducing matrix interference is LA-LIBS in which a sample aerosol is generated by an ablation laser and then transported in a carrier gas to a different location for plasma formation by a second laser. However, the instrument system is more complex than conventional LIBS, and LODs are poorer. Han et al.159 overcame these limitations by incorporating the two lasers in a single chamber. The output of a high-energy plasma-generation laser (200 mJ per pulse) was focused onto the aerosol plume produced by a low-energy ablation-laser (3 mJ per pulse). Improved signal stability was achieved together with an LOD of 7.8 μg g−1 for the determination of K in soil, an improvement over the 9.8 μg g−1 for the traditional combined sample-ablation and plasma formation. Results for three real samples were similar to those obtained by AAS.
Other notable advances in the LIBS analysis of soils included: a mathematical procedure160 to correct for spectral line self-absorption; a method161 based on key parameter monitoring and a back-propagation neural network that improved precision; and a theoretical model162 of ablation-crater morphology that allowed analysis to be optimised in such a way as to reduce confinement effects.
Also published were numerous methods for the determination of specific elements in soil. A procedure for C in Brazilian soils overcame163 interferences from Al and Fe, both of which are typically present at high concentrations in such samples. Two methods were reported for the determination of Cd. The first involved164 polarisation-resolved LIBS and a support-vector regression algorithm. The second featured165 co-linear DP-LIBS and a particle-swarm-optimised least-squares support vector machine. The performance of a linear-weighted network was improved166 for the determination of Cr by addition of adaptive weighted normalisation. The application of a novel ion-enrichment chip containing an anion exchange resin (for CrVI) and an active carbon fibre (for total Cr) made167 speciation analysis possible. Although potentially useful for solution analysis, the assertion that the method was suitable for the determination of total Cr in soil is highly questionable. Soils with naturally low concentrations of Cr were spiked with standard solutions to give Cr concentrations of 100–1000 mg kg−1. The Cr was extracted with deionised water (1:3 m/v) and the extract passed through the ion-enrichment chip for preconcentration and LIBS analysis. Hence, only the water-soluble Cr fraction and not Cr associated with solid soil minerals could be measured.
In the LIBS analysis of plants, a back-propagation neural network that had been optimised using a sparrow search algorithm was used168 successfully to predict concentrations of Cd, Cu and Pb in Fritillaria thunbergii. Fang et al.169 explored the possibility of analysing Cd- and Pb-spiked laurel leaves without the need for grinding and pelleting. For calibration, small (10 mm diameter) wafers were cut from leaves that had been soaked in solutions with different analyte concentrations for two days, rinsed with deionised water and dried before the laser interrogation. Unsurprisingly, the spatial variability was high (RSDs of 13–160%, n = 12). However, an r2 value of 0.8272 was obtained when the LIBS signal intensity for Pb at 405.78 nm was plotted against results obtained for the same samples following MAE and ICP-MS. This is an encouraging result.
The effect of laser-spot size on the LIBS analysis of heterogeneous agricultural samples such as plants was studied170 at constant fluence using soybean grist as a test substrate. Laser characteristics of three types of LIBS instrument were simulated: a hand-held instrument with low pulse energy and small laser beam diameter (0.12 mm); a typical laboratory-based instrument with moderate pulse energy and beam diameter (0.53 mm); and an industrial system, found typically on a production line, with high pulse energy and large beam diameter (1.1 mm). As might be expected, the larger beam profile gave better linearity and accuracy for the determination of Zn.
Monochromatic EDXRFS with a silicon drift detector was used172 together with a fundamental parameters algorithm for the determination of 20 elements in soils and sediments. The LODs for all elements except Cr and V were lower than those obtained by WDXRFS. The LOD for Cd (0.04 mg kg−1) was particularly low. Concentrations of As, Cd, Cr, Cu, Ni, Pb and Zn obtained for 17 soil and sediment CRMs correlated (r2 > 0.98) with certified values for all elements. Monochromatic-excitation EDXRFS coupled with a fundamental parameters approach was applied173 for the first time to the determination of As, Cd and Pb in herbal medicines. Analysis time was only 10 to 30 min and the cost of analysis was a tenth of that by ICP-MS. The LODs were 0.093, 0.144 and 0.232 mg kg−1 for As, Cd and Pb, respectively. Linear regression between 99 pairs of ICP-MS and XRFS results yielded r2 values of 0.91 for As and of 0.96 for Cd and Pb.
The XRFS analysis of organic samples in which the low-Z elements C, H, N and O predominate generally requires an increased sample mass per unit area (sample thickness) in the sample cup than the analysis of soil and rock samples. Zhou et al.174 developed a mass-correction model for quantification of As, Cu, Fe and Zn in thicker samples of organic materials. When 39 organic materials including animal tissue, fungi and plants were analysed, the measured concentrations decreased with increasing sample thickness in a power-law relationship. The model corrected for this concentration decrease and allowed predictions of concentrations in infinitely thick samples to be made. For samples of intermediate thickness, the concentrations of As, Cu, Fe and Zn were predicted by applying a simple linear regression previously derived by cross calibration with ICP-MS data. The relative measurement errors of results when compared to ICP-MS data of <18% (As) to <34% (Fe) indicated that with further development pXRFS had potential for the analysis of organic matrices.
Two papers described the integration of XRFS technology into new hardware and software applications with the aim of accumulating data over large areas with rapid real-time data sharing. Huang et al.175 presented the concept for an ‘integrated unmanned aerial vehicle-based soil heavy metal pollution rapid detection system’ yet to be built. The drone-like multi-rotor vehicle would fly to a specific investigation site where data would be collected at a height of 5 cm above the ground by an onboard pXRF spectrometer. Kim et al.176 developed a smart-glasses-based app that enabled the wearer to move to predetermined sampling points by navigating a satellite image, to analyse samples by pXRFS and to enter the results into the app via a wearable keyboard. The app calculated pollution indices and identified potentially contaminated locations. Data could be uploaded to the cloud server and shared in real time with other users on- and off-site. Both developments highlight the tremendous potential of XRFS for remote and real-time monitoring.
5. Analysis of geological materials
5.1. Reference materials and data quality
The production of new RMs for trace element determinations has been mainly directed to addressing the need for more matrix-matched RMs for microanalysis. A useful addition to the range of available glass RMs was three natural glasses, andesitic glass OJY-1 and rhyolitic obsidians OH-1 and OA-1, which were characterised180 for 54 major and trace elements and for Pb isotope ratios by a variety of analytical techniques. Microanalyses (10–120 μm) demonstrated that all three glasses were homogeneous with respect to these determinands except for Ni in OJY-1 and Ce, Cu and Zr in OH-1. Four carbonate powders, developed by Sun et al.181 from natural raw materials by a coprecipitation method, were assigned certified values for more than 35 element mass fractions determined by solution techniques. Pressed pellets prepared from these powders were checked for homogeneity and stability by LA-ICP-MS; although the repeatability for many elements was comparable to those obtained from homogeneous glasses, values for some elements, such as Cd, Co, Ga, Ge, Mo, Ni, Se and U, fell outside acceptable limits. After characterisation of their major and trace compositions by EPMA and LA-ICP-MS, two clinopyroxene megacrysts (DMP-2 and DMP-3) were considered182 to be sufficiently homogeneous for in situ microanalysis. Recommended and information values for 32 elements were reported together with their uncertainties (2SD). Of the 12 apatite samples tested by Kennedy et al.183 as potential RMs for SIMS analysis, three (SLAP, NUAN and GR40) were internally homogeneous. Most of the trace element mass fractions determined by LA-ICP-MS had precisions of ≤2.0%. On the other hand, AFG2 and BR5 were considered the best for U–Pb dating as these had relatively high Th and U contents and 206Pb/204Pb ratio and were more homogeneous than many naturally occurring apatites. However, because of the variable amounts of common Pb, none of the apatites studied could be used as a single-chip ID-TIMS U–Pb RM. Four natural chromite samples from the Luobusa ophiolite (China) and Stillwater Complex (USA) were evaluated184 as potential RMs for in situ microanalysis by LA-ICP-MS. Recommended values for major oxides (Al2O3, Cr2O3, FeO and MgO) and trace elements (Co, Ga, Mn, Ni, Sc, Ti, V and Zn) were derived from solution ICP-MS data and the homogeneities of the major and trace elements were checked by EPMA and LA-ICP-MS, respectively. Prasad et al.185 described the production of a bauxite CRM (BARC-B1201) and its certification for 8 major and minor elements and loss on ignition (LOI) following an inter-laboratory comparison exercise involving 17 laboratories in India.A bibliographic review (28 references) of selected papers published in 2021 containing analytical data for geological and environmental RMs highlighted186 the large proportion of papers reporting values for isotopic systems and the characterisation of new RMs for isotope analysis. This trend is reflected in Table 9, which lists new geological RMs for isotope measurements published within the period covered by this ASU. Another trend observed in the review by Weis et al.186 was the analysis of established RMs by new and improved methods and techniques thereby providing reference values for a wider range of trace elements and isotope systems than the original certificate. This continues to be the case and new data for existing geological RMs concerned with isotope systematics and dating protocols are listed in Table 10.
| Determinands | Matrix | Technique | RM name | Comments | Reference |
|---|---|---|---|---|---|
| Cu isotopes | Chalcopyrite | fs-LA-MC-ICP-MS | 14ZJ12-1, JGZ-29, JGZ-78 | 3 Natural chalcophyrites. Homogeneity demonstrated by intermediate precision of 0.07–0.08‰ (2SD) for δ65Cu. Recommended values for RMs relative to NIST SRM 976 (copper) obtained by solution MC-ICP-MS | 333 |
| Fe isotopes | Pyrite | LA-MC-ICP-MS | Tianyu-Py | Recommended values of 0.49 ± 0.03‰ (2SD, n = 4) for δ56Fe and 0.73 ± 0.04‰ (2SD, n = 4) for δ57Fe based on solution analysis. Homogeneity of Fe isotopes verified by LA-MC-ICP-MS | 334 |
| Fe isotopes | Chalcopyrite | fs- and ns-LA-MC-ICP-MS | Tianyu-Ccp | Recommended values of 0.39 ± 0.07‰ (2SD, n = 4) for δ56Fe and 0.57 ± 0.06‰ (2SD, n = 4) for δ57Fe based on solution analysis. Homogeneity of Fe isotopes verified by LA-MC-ICP-MS; precision 0.19‰ (2SD, n = 86) for δ56Fe for spot size of 16 μm | 335 |
| Fe isotopes | Fe metal | fs-LA-MC-ICP-MS | IRMM-524A | IRMM-524A (Fe metal) characterised relative to IRMM-014, which is commercially unavailable. Results identical to published values by solution MC-ICP-MS within analytical uncertainty | 336 |
| Hf isotopes | Zircon | LA-MC-ICP-MS | Ban-1 | Recommended value for 176Hf/177Hf of 0.282983 ± 0.000009 (2SD, n = 130) obtained by solution MC-ICP-MS. Considered sufficiently homogeneous for in situ isotope determinations of Hf and Zr (see later entry) | 337 |
| Li isotopes | Clinopyroxene | LA-MC-ICP-MS | CPXA01, CPXB01-05 | Six synthetic clinopyroxene RMs prepared by mixing metallic oxides with either USGS RM GSP-2 (granodiorite) or IAEA CRM L-SVEC (Li carbonate) and fusing to make glasses. Homogeneity testing gave 2s of <1‰, the long-term precision for δ7Li by LA-ICP-MS | 338 |
| Mg isotopes | Mg solution | MC-ICP-MS | Alfa-Mg | New delta-zero Mg solution with certified δ26/24Mg of −1.40‰ relative to DSM3 with uncertainty of 0.05‰ (k = 2). δ26/24Mg values reported for 14 environmental RMs | 103 |
| O isotopes | Lawsonite | SIMS | LM-19 | Recommended δ18O value of 8.98 ± 0.10‰ (1SD). Main limitation was chemical variability in Fe and Ti that may cause a minor matrix effect resulting in an δ18O bias of −0.90‰ | 339 |
| O isotopes | Monazite | SIMS | COM-1, hongcheon-1, hongcheon-2 | Recommended δ18OVSMOW values of 6.67 ± 0.08‰, 6.60 ± 0.02‰ and 6.08 ± 0.07‰ for the three RMs, respectively | 340 |
| Pb isotopes | K-feldspar | LA-MC-ICP-MS | Albany K-feldspar | Double-spike TIMS used in conjunction with LA-MC-ICP-MS to characterise Pb isotope composition. No Pb isotopic heterogeneity detected in Albany K-feldspar but Shap K-feldspar heterogeneous at precisions of <0.15%; leaching to remove secondary radiogenic Pb recommended | 341 |
| S isotopes | Sulfides | LA-MC-ICP-MS | SPH-1 (sphalerite), GC-1 (chalcopyrite), NWU-GN (galena), RPPY pyrite powder) | δ 34S values determined by GS-IRMS and solution MC-ICP-MS relative to V-CDT. LA-MC-ICP-MS data consistent with preferred values within analytical uncertainty | 342 |
| S isotopes | Sphalerite | LA-MC-ICP-MS | GBW07270 | Natural powders prepared as a sintered material. Recommended δ34SV-CDT of −5.44 ± 0.18‰ (2SD) agreed with IRMS value within analytical uncertainty | 343 |
| Sn isotopes | Cassiterite | LA-MC-ICP-MS | Synthetic cassiterite | Sintered material prepared from ultrafine cassiterite powder. Homogeneity (2SD) as assessed by LA-MC-ICP-MS was improved from 0.64‰ in the original cassiterite to 0.10‰ by sintering. Recommended δ124Sn/120Sn of 0.60 ± 0.03‰ (2SD, n = 5) by solution MC-ICP-MS | 344 |
| Sr isotopes | Plagioclase | LA-MC-ICP-MS | AMNH-107160 (Labradorite), G29958 (Anorthite), Hrappsey 14-2 (Bytownite) | RMs developed as part of wider recommended procedures and data reduction strategies for Sr isotope measurements in geological materials by LA-MC-ICP-MS | 345 |
| Sr isotopes | Calcite | LA-MC-ICP-MS | MNP | MNP has a low Rb/Sr ratio, low amounts of heavy REEs and high Sr content. Recommended 87Sr/86Sr value of 0.70617 ± 0.00005 (2SD, n = 18) determined by TIMS and solution MC-ICP-MS. An average 87Sr/86Sr ratio from LA-MC-ICP-MS analyses on random calcite crystals was identical to that of the solution-based data | 346 |
| U–Pb dating | Columbite | LA-ICP-MS | SN3 | ID-TIMS age of 404.0 ± 1.3 Ma (2SD), with low common Pb content; 96% of LA-ICP-MS data within the ID-TIMS 206Pb/238U age | 347 |
| U–Pb dating | Garnet | TIMS, LA-ICP-MS | IUC-1 | Gem quality andradite-rich garnet with assigned age of 20.4 ± 0.5 Ma (2SD) proposed as secondary garnet RM for in situ dating | 348 |
| U–Pb dating, Nd–Sm isotopes | Titanite | LA-ICP-MS | Khan River, Bear Lake | U–Pb data were acquired by a variety of microbeam techniques including ID-TIMS and bulk measurements. Khan River was considered suitable as a secondary RM for U–Pb geochronology and Nd isotope ratios, whereas Bear Lake could be used for in situ trace element microanalysis and Nd–Sm isotope analysis, as well as U–Pb dating | 349 |
| U–Pb dating and Nd isotopes | Apatite | LA-ICP-MS | MAP-3 | Shown to be free of mineral inclusions with a 206Pb/238U age of 800.5 ± 0.9 Ma (2SD, n = 11) determined by ID-TIMS. High degree of chemical and isotopic homogeneity demonstrated, making it suitable as a primary RM for in situ U–Pb and Nd isotope measurements | 350 |
| U–Pb ages and Hf–O–Zr isotopes | Zircon | LA-ICP-MS, TIMS, SIMS, SHRIMP | SLZA, SLZB and SLZC | U–Pb ages determined by CA-ID-TIMS; Hf isotopes by solution MC-ICP-MS; O isotopes by laser fluorination method and SIMS, and Zr isotopes by double spike TIMS. SLZA exhibited slight heterogeneity for U–Pb, Hf and Zr isotopic compositions, whereas SLZB and SLZC considered to be homogeneous | 351 |
| (U–Th)/He and U–Pb dating | Zircon | LA-ICP-MS | SA01 | In situ laser microbeam (U–Th)/He and U–Pb double dating method applied and compared with traditional solution (U–Th)/He method. Concordia age of 535.2 ± 71 Ma (n = 32) indistinguishable from published ages | 352 |
| Zr isotopes | Zircon | LA-MC-ICP-MS | Ban-1 | Recommended values of δ94Zr/90ZrIPGP-Zr of −0.09 ± 0.006‰ (2s, n = 5) by double spike TIMS. Considered sufficiently homogeneous for in situ isotope determinations of Zr and Hf (see earlier entry) | 337 |
| Determinand | Matrix | Technique | Comments | Reference |
|---|---|---|---|---|
| He dating | Apatite and zircon | Fission-track dating | Zircon FC1 from the Precambrian Duluth Complex, Minnesota, recommended as a RM for zircon (U–Th)/He dating, in addition to U–Pb geochronology. Apatite FC1 from the same location not suitable as RM because of wide dispersion of ages obtained. Air abrasion recommended to control α-ejection in (U–Th)/He dating | 353 |
| Hf isotopes | Mafic rocks | MC-ICP-MS | 176Hf/177Hf ratios plus Lu and Hf mass fractions measured in 10 mafic and ultramafic rock RMs. 176Hf/177Hf precision of <60 ppm (2SD) achieved on test portions of 0.06 to 0.3 g for 7 recommended RMs | 354 |
| Nd isotopes | Geological RMs | MC-ICP-MS | Nd isotopic compositions of 27 RMs, including silicates, sediments, soils and carbonate, 13 of them for the first time. δ146Nd/144Nd long-term measurement precision <0.030‰ (2SD) relative to RM JNdi-1 | 107 |
| Rb isotopes | Geological RMs | MC-ICP-MS | δ 87Rb reported for 21 RMs including igneous, sedimentary and metamorphic rocks as well as a seawater RM relative to NIST SRM 984 (RbCl). Long-term measurement reproducibility <0.06‰ (2SD) | 355 |
| Rb–Sr dating | K-feldspars, mica | LA-ICP-MS/MS | 4 RMs, GL-O (glauconite), Mica-Mg (phlogopite), Mica-Fe (biotite) and FK-N (K-feldspar) prepared as nano-powder pellets and tested for in situ Rb–Sr dating, complemented by ID-MC-ICP-MS data. Only nano-pellets of Mica-Mg and GL-O proved suitable for this application | 356 |
| Rb–Sr dating | K-feldspars, mica | LA-ICP-MS/MS | Grains of 4 RMs (Mica-Mg, Mica-Fe, GL-O and FK-N) found to have variable degrees of heterogeneity by SEM-EDS and EPMA imaging. Powdered material analysed by ID-TIMS and ID-MC-ICP-MS provided proposed working values for 87Sr/86Sr and 87Rb/86Sr and associated uncertainties when using these RMs for in situ dating | 357 |
| S | Geological RMs | SF-ICP-MS | Rapid method developed for quantification of S mass fractions based on aqua regia digestion at 90 °C in open vessels applied to 60 geological and environmental RMs. The use of a heating-condensing sample introduction into the ICP provided an LOQ of <1.0 μg g−1 in the solid | 358 |
| S | Rock RMs | XRFS, elemental analyser, iodo-titration | Compilation of >1700 measurements of S mass fractions for 37 geological RMs obtained by several analytical techniques over 25 years | 359 |
| Sn isotopes | Rock RMs | MC-ICP-MS | δ 120Sn/118Sn data relative to NIST SRM 3161a (Sn isotope solution) reported on 10 geological RMs, seven for the first time. Overall method precision estimated as ±0.07‰ (2SD, n = 6) for USGS RM BHVO-2 (basalt) | 360 |
| Trace elements | Uraninite | EPMA, LA-ICP-MS | Additional information on matrix effects and trace element homogeneity for the Happy Jack Uraninite RM. REE discrepancy between LA and bulk solution ICP-MS measurements likely to be the result of digestion of mineral inclusions | 361 |
| U isotopes | Geological RMs | MC-ICP-MS | 233U–236U double spike technique used to determine U isotopes in 29 Chinese rock RMs with U mass fractions ranging from 0.11 to 18.7 μg g−1 | 362 |
| U–Pb dating | Cassiterite | LA-ICP-MS | Confirmed ages and better estimates of uncertainties for SPG, Yankee, AY-4 and Jian-1 cassiterite RMs previously analysed by ID-TIMS | 363 |
| U–Th–Pb dating | Titanite and apatite | LA-ICP-MS | New U–Th–Pb isotope and trace element mass fraction data for 10 titanite and 5 apatite RMs based on integrated EPMA, LA-ICP-MS and ID-MC-ICP-MS characterisation | 364 |
| Water content and trace elements | Amphiboles | Karl-Fischer titration, LA-ICP-MS | New data on water content and trace element mass fractions reported for two amphibole microanalytical RMs from the Smithsonian | 365 |
| Water content | Clinopyroxene, orthopyroxene | SIMS and FTIR spectroscopy | 4 Clinopyroxenes and 5 orthopyroxene potential RMs analysed and found to be homogeneous in terms of water content as indicated by a low standard deviation of <18.6% (2SD) for both inter- and intra-fragments | 366 |
| Zn isotopes | Geological RMs | MC-ICP-MS | Demonstration that δ66Zn can be precisely and accurately measured within ±0.03‰ (2SD) by MC-ICP-MS. Zn isotope data reported for 21 geological RMs, some for the first time | 367 |
| Zr isotopes | Zircon | LA-MC-ICP-MS | Long-term stability of 0.08‰ for δ94Zr/90Zr achieved in study of Zr isotope variations in a range of zircon RMs | 368 |
Potts and Webb187 proposed a simple test for assessing the fitness-for-purpose of values for a RM. Their approach involved comparing individual reference value uncertainties with a target uncertainty calculated using a modified form of the Horwitz function that models the variation of precision with mass fraction over a range of six orders of magnitude. They provided worked examples for various geological CRMs to demonstrate that a quality factor, calculated as the ratio of the reference value uncertainty to one third of the target uncertainty derived from the Horwitz function, provided an overall indication of the quality of a RM and whether the material was appropriate for its intended use.
5.2. Sample preparation, dissolution and chemical separation
Logue et al.188 presented a novel laser ablation microsampling technique as a non-mechanical alternative to micro-milling for sampling single crystals and interstitial phases. Target phases delineated by LA were extracted using a binocular microscope and common mineral-separation tools and digested for the determination of Nd and Sr isotope ratios by ID-TIMS. However, this technique had limited usefulness for thicker samples because the efficiency of LA instruments decreases rapidly beyond 200 μm depth.Vlastelic and Piro189 investigated the volatilisation of trace elements during the evaporation-to-dryness of basaltic samples dissolved in HF under both open- and closed-vessel systems. With the exception of B, sublimation at 80 °C in open systems was low (≤3%). However, the closed-vessel system included a PTFE elbow and volatilisation losses of >3% were recorded for a significant number of trace elements, including refractory elements such as Hf, Nb, U and Yb. It was concluded that the higher vapour pressure of HF in the closed system gave rise to highly fluorinated species with low sublimation temperatures, or to unstable species such as the REE tetrafluorides. These findings indicated that closed-system evaporation must be used with caution for quantitative analyses.
A method based on sequential leaching to obtain reliable SiO2 concentrations in sediments was devised190 to overcome the problem of the release of volatile SiF4 during conventional HF–HNO3 digestions. Five powdered RMs were processed using a two-step leaching procedure utilising HCl to digest authigenic minerals such as carbonates, ignition in a muffle furnace to remove any remaining OM and digestion with concentrated HF–HNO3 at high pressure and temperature to attack detrital silicate phases. Measured values were within ±2% (1 RSD) of the reference values and the precisions were better than 0.46%. Advantages over other methods were low sample consumption and high efficiency.
Rapid and simple digestion procedures that achieve total dissolution remain a priority. Liu et al.191 evaluated the ability of ammonium bifluoride (NH4HF2) to digest Ti-rich minerals such as rutile, ilmenite, titanite and perovskite for the determination of major and trace elements by ICP-MS. Complete digestion of 50 mg samples was achieved in 4 h using 300 mg of NH4HF2 at 230 °C. This was claimed to be 18–42 times faster than a closed-vessel acid digestion procedure. The analysis of Ti-rich materials using the two digestion methods gave ICP-MS datasets for 36 trace elements that were within ±10% for most elements. The one exception was rutile, for which the closed-vessel acid digestion suffered from the formation of an insoluble precipitate that caused low recoveries of Nb, Ta, Ti and V. He et al.114 employed NH4F digestions in the determination of Br, Cl and I in geological materials by SF-ICP-MS. Ammonia released from the decomposition of molten NH4F at 200–240 °C in a screw-top PFA vial was effective in preventing the loss of halogens released from geological samples. Analysis of a range of RMs confirmed that the method was capable of extracting Br, Cl and I quantitatively from rocks, sediments and soils, with LOQs of 0.018, 2.8 and 0.003 μg g−1, respectively.
A rapid method for the separation of REEs from barium when analysing Ba-rich samples containing barite or witherite was developed192 to eliminate the Ba interference for accurate determination of REE content by ICP-MS. This method relied on barium nitrate being almost insoluble in concentrated HNO3 whereas the REEs were not. The whole separation procedure took <2 h and only consumed 1.5 mL 15 M HNO3. Analysis of four barite RMs with BaSO4 contents of 19–42 wt% gave results within ±4% of the reference values.
5.3. Instrumental analysis
Yang et al.194 explored the effect of sample surface morphology on LIBS spectra. Images of the plasma were recorded with an intensified CCD camera during LIBS analysis of samples with various surface reliefs and roughness. Functional relationships between the surface morphology and characteristic parameters of LIBS spectra were examined. Although this study provided a basis to account for some of the unpredictability of LIBS spectral anomalies, it had limited value for field-based in situ measurements for which the surface morphology of the sample was unknown.
As in previous years, various contributions in the field of LIBS focused on topics related to exploration and mining. In their quest to develop a downhole geochemical assay tool, Fontana et al.195 investigated the optimal number of LIBS analyses required to provide data of a similar quality to whole rock geochemical data for major elements (Al, Ca, Fe, K, Mg, Na, Si, and Ti). Rocks with diverse chemical, textural and mineralogical properties were tested by averaging LIBS spot analyses performed along a drill core and comparing the results to whole-rock geochemical data obtained in the laboratory for the corresponding core interval. The greatest influence on the number of LIBS analysis required was the concentration range of each element; a wider range of major element contents required more LIBS analyses to estimate whole rock geochemistry. Lesser factors were the number of minerals that hosted an element and grain size. It was concluded that between 30 and 560 spot analyses per meter were necessary to achieve whole rock geochemistry by LIBS. A laser-fusion pre-treatment method was proposed196 for the quantitative determination of element concentrations in sandstone. A quasi-continuous-pulse high-frequency (50 kHz) laser was directed at the sandstone powder for 20 s to produce glass beads which were then analysed by LIBS. Comparison of results for CRMs prepared in this manner with those from LIBS analysis of a traditional powder pellet showed that the LODs for the laser-fused glasses were better and the spectral signals more stable than those from the pellets.
The versatile nature of LIBS for in situ analysis of a wide range of potential ores has been demonstrated in several papers. Identification in the field of different types of bauxite was based197 on a convolutional neural network approach and PCA. Fast and detailed analysis of mineral species in copper ores was achieved198 by preliminary screening using hyperspectral imaging to discriminate between Cu-sulfides and barren minerals, followed by detailed elemental and mineralogical analysis by μLIBS. In a follow-up paper, multivariate calibration techniques such as PLS, ANN and MCR-ALS were compared199 as quantification approaches for improved mineralogical analysis of copper ores. A new method was proposed200 to overcome matrix interferences in the quantitative determination of total Fe in iron ores using variable-importance back-propagation ANN (VI-BP-ANN). Compared with other models, the VI-BP-ANN model reduced overfitting and obtained the highest r2 and lowest RMSE for calibration and prediction. Complex ferromanganese nodules were analysed201 rapidly on-board ship with a prototype mobile LIBS setup that incorporated a portable diode-pumped solid-state laser with a high repetition rate. Similar results were obtained by LIBS with an intensified CCD camera and by EDXRFS demonstrating that minimal sample treatment (milling and pelletisation) was sufficient for the semiquantitative determination of major and minor elements with this instrumentation.
Other critical-metal ores analysed by LIBS included202 the determination of La in REE ores, in which LIBS was combined with LIF and the standard addition method to decrease the influence of matrix effects and self-absorption. The LOD for La was 7.2 ppm. A specially designed set of calibration standards was employed203 for the direct LIBS determination of lanthanides in REE-rich niobium and uranium ores. The content of each REE in the calibration set covered two orders of magnitude and analytical lines were selected through thermodynamic modelling of the LIBS spectra. Under these experimental conditions, PLS regression provided better analytical performance for La, Nd and Sm quantification in ores than univariate regression. An assessment of hand-held LIBS for its potential in the exploration of pegmatite- or granite-related mineralisation was based204 on a univariate calibration curve. Simultaneous quantification of Li contents and major element ratios, such as Si/Al, allowed rapid discrimination between different Li-bearing silicates that can be difficult to identify in the field on the basis of macroscopic criteria. Ferreira et al.205 used both a commercially available handheld device and a laboratory prototype in their extensive comparison of the performances of different algorithms for quantifying Li by LIBS when prospecting for Li ores. They concluded that, when covering a wide range of concentrations typical of a mining environment, non-linear methodologies offered better performances than linear methods which were more affected by saturation and matrix effects. A study of the capability of LIBS to determine Pd in a one-meter-long core ore sample identified206 three main mineralogical phases by PCA. The instrument was calibrated using three sets of CRMs in the form of compressed powders with concentrations ranging from 1 to 500 ppm Pd. The LIBS analysis highlighted significant heterogeneity of the Pd distribution on the core surface and revealed sulfide-rich zones also particularly rich in Pd. Elhamdaoui et al.207 used pressed powder pellets of RMs doped with Pd solution to establish calibration curves for the measurement of trace amounts of Pd by LIBS and LIBS-LIF. The LIBS-LIF LODs of 160 ppb for a single laser shot or 16 ppb for 100 shots were greatly superior to the LODs obtained by LIBS. Unlike LIBS, LIBS-LIF could resolve spectral interferences on the Pd spectral lines in iron-rich mineral matrices thereby making it a good candidate for in situ analysis of ore samples.
Other examples of the use of LIBS in combination with other techniques included208 application of μLIBS, μXRFS and EPMA to a rock thin-section for rapid mineral-classification and multi-elemental quantitative imaging of major to trace elements down to the ppm level. Crystallographic information was acquired by Raman spectroscopy. Results from μLIBS micro-mapping were compared209 with those from EDXRFS macro-mapping to illustrate the advantages of LIBS, such as speed, lateral and in-depth resolutions and the capability to determine light elements. However, it was recognised that a combination of the two techniques was preferable to provide a rapid classification of geological materials with different compositions. In an interesting development, Zhao et al.210 proposed a confocal-microscopy-controlled Raman-LIBS hybrid method with high spatial resolution and anti-drift properties. The axial-focusing resolution and lateral resolution for morphological imaging were ca. 15 and 66 nm, respectively. The authors claimed to be the first to combine Rayleigh/reflected light, LIBS and Raman spectra to acquire simultaneously geometrical topography and information on elemental composition and molecular structure. A LIBS-XRF analyser that combined PCA and PLS regression methods was developed211 for rapid assessment of coal quality. The experimental results for calorific value, ash content, volatile matter and S content demonstrated good accuracy and stability, with the measurement repeatabilities meeting national standards. Further development of the online system was required in order to monitor the coal quality on a conveyor belt in real time.
Data processing is a crucial aspect of LIBS analysis. To enable the sharing of prediction models between LIBS instruments, a transfer-learning method based on dynamic time warping (DTW) algorithms was proposed by Rao et al.212 Even though the method based on DTW was superior to a piecewise direct standardisation algorithm for prediction of both lithology and quantitative elemental composition on another instrument, the Pearson coefficient was introduced to improve the performance of the prediction further. Multivariate regression models based213 on machine and transfer learning were developed to correct for chemical and physical matrix effects. A set of 27 fully characterised rocks were prepared as pressed powder pellets, and LIBS spectra of both the pellets and the parent rocks recorded. Spectra from the pellets were used to train multivariate regression models based on a machine-learning approach that combined feature selection and a back-propagation neural network. Tests with rocks revealed the influence of the physical matrix on the prediction performance of the models, which could be improved significantly by introducing transfer learning to the model. The polynomial interactive reconstruction method was proposed214 to improve the accuracy of classifying gem minerals by portable LIBS. In a classification experiment involving 24 types of gemstone minerals, an accuracy of 94% was achieved compared to 83% and 82% for the conventional spectral-intensity and whole-spectrum methods, respectively.
A new technique for in situ U–Th disequilibrium dating by LA-ICP-MS was developed217 for the analysis of inclusion-bearing ilmenite in order to date young volcanic deposits. Such rocks often do not contain minerals such as zircon or K-bearing phases, thus limiting the application of more conventional dating techniques. Isochrons were generated by combining LA-SF-ICP-MS measurements of the host ilmenite (low in U and Th mass fractions) with those of numerous inclusions (higher U and Th mass fractions) with a large spread of 238U/232Th ratios. Estimates of age overlapped within the uncertainty of published ages. The main caveat was that large ablation spots (ca. 250 μm diameter) were required because of the low U mass fractions and this could result in a mixed signal of ilmenite host and various inclusions. Although bastnaesite is an important geochronometer for recording the time of REE mineralisation in such deposits, there is a very limited supply of bastnaesite K-9, the only reliable primary RM for in situ U–Th–Pb dating of bastnaesite. For this reason, Tang et al.218 assessed xenotime XN01 as an alternative RM and found that the 206Pb/238U and 208Pb/232Th ratios of xenotime XN01 were more uniform than in bastnaesite K-9 and that any difference in isotopic fractionation in Th/Pb and U/Pb ratios between the two materials was almost negligible. The addition of nitrogen in the ablation cell played an important role in minimising these fractionation effects. It was concluded that xenotime XN01 was a better primary RM than bastnaesite K-9 for in situ U–Pb dating of bastnaesite. Niki et al.219 developed an in situ238U–230Th dating method using multiple spot measurements by a fs LA-ICP-MS system equipped with collision/reaction cell technology. This system was evaluated by analysing four Quaternary zircon samples with ages between 110 ka and 16 ka and three reference zircons (GJ-1, OD-3 and Plešovice). The resulting ages for the Quaternary zircons were consistent with chronological constraints including fission track ages. Whereas the measured 230Th/238U values for GJ-1 and Plešovice agreed with 230Th/238U in secular equilibrium, the 230Th/238U values for OD-3 were significantly higher than the secular equilibrium value, an observation that had been reported previously.
Several contributions focused on issues related to in situ U–Pb geochronology. In a study to assess the long-term reproducibility of U–Pb ages of zircon RMs by LA-ICP-MS, characteristic excess variances for 206Pb/238U and 207Pb/206Pb ages were calculated220 from results obtained from more than 100 measurement sessions over six years for each of seven zircon RMs. This exercise provided an example of how to compile large datasets and to assess the intermediate measurement precision of long-term zircon age data. Jenkins et al.221 investigated the ablation behaviour of garnet and rutile and the implication for U–Pb geochronology measurements. The influence of analytical parameters such as fluence and laser beam size on crater morphology, ablation rates, downhole fractionation and U–Pb ages was very different for the two minerals. Some recommended LA sampling strategies for these minerals were provided on the basis of these findings.
The 40Ar/39Ar geochronometer relies on the co-irradiation of samples with neutron-fluence (or flux) monitors of known age. Biotite is often used as a primary monitor because it is difficult to fully degas argon from the otherwise preferable sanidine melts. The potential of a first-principles method to calibrate 40Ar/39Ar neutron-fluence mineral monitors was illustrated222 by measuring 40Ar abundances using an Absolute Quantities of Argon pipette system and combining these with existing 40K abundance data. Ages for HD-B1 and MD2 biotite fluence monitors were calculated and combined with intercalibration data for HD-B1 and Fish Canyon sanidine to determine the 40Ar/39Ar age of Fish Canyon sanidine. The SK01 sanidine RM was analysed223 at three different laboratories to test its homogeneity and 40Ar/39Ar age consistency. Incremental heating of 5 mg aliquots gave a weighted mean age of 27.58 ± 0.06 Ma (95% confidence level). Total fusion analysis of 23 single crystals gave ages between 27.070 ± 0.108 and 27.736 ± 0.062 Ma; the older ages were interpreted to reflect an inherited or excess argon component in some crystals. It was concluded that further work was required to evaluate the age dispersion more fully before SK01 sanidine could be utilised as a 40Ar/39Ar RM. A sanidine sample separated from Yunshan obsidian and selected as a potential neutron-flux monitor had224 homogeneous Ca and K contents and no significant intragrain differences in its major element composition. Results from step heating and single-grain laser-fusion yielded a weighted mean age of 93.45 ± 0.21 Ma (2SD). Although this sanidine was not considered to be an ideal RM for monitoring the neutron flux in high-precision analysis because of its relatively high atmospheric argon content, it was acceptable as a secondary RM for monitoring analytical procedures.
The considerable research effort focused on isotope ratio determinations by MC-ICP-MS and other techniques is reflected in Table 11. Because the range of elemental isotope ratios now being measured in geological materials is so extensive, a table is provided as a starting point for readers to explore the systems of most relevance to them. In general, it is difficult to discern any major advances as many of the studies provided modest improvements to existing separation procedures or analytical protocols.
| Element | Matrix | Sample preparation | Technique | Comments | Reference |
|---|---|---|---|---|---|
| B | Silicate and carbonate RMs, corals | In situ analysis of RMs as glasses or pressed powder pellets; corals cleaned and embedded in epoxy resin | UV-fs-LA-MC-ICP-MS | Calibration against NIST SRM 610 (glass). External reproducibility of ±0.9‰ (2SD). No laser-induced or ICP-related matrix effects observed within stated precision | 369 |
| Ba | Barite | Barite RMs sintered under high pressure to stabilise them for in situ analysis | LA-MC-ICP-MS | Long-term precision for δ137Ba/134Ba ±0.09‰ (2SD). Good agreement with values obtained by solution double-spike method within analytical uncertainty | 370 |
| Ba | Geological RMs | A simplified two-column method using AG50-X8 and Eichrom Sr resins enabled efficient and simultaneous Ba separation in multiple samples | MC-ICP-MS | SSB and double-spike (135Ba–136Ba) methods compared; SSB providing the better precision. Long-term reproducibility was ≤±0.07‰ (2SD) for δ138Ba/134Ba. Ba isotope data for 9 geological RMs confirmed accuracy of method | 371 |
| C, N | Natural diamonds | Both isotope ratios obtained from a single ca. 10 μm diameter pit | SIMS | Spot-to-spot reproducibility of δ13C and δ15N for UWD-1 RM, a natural N-rich diamond from Kelsey Lake, USA, were 0.3‰ and 1.6‰, respectively (2SD). UWD-1 confirmed to be isotopically homogeneous | 372 |
| Ca | Geological RMs | After dissolution, 42Ca–43Ca double spike added and published separation chemistries employed depending on sample matrix | MC-ICP-MS/MS | CCT with double spike gave long-term precision for δ44Ca/40Ca of ±0.035‰ (2SD), an improvement on previous TIMS or MC-ICP-MS studies. Capable of determining both radiogenic and stable Ca isotope ratios on small amounts of Ca | 373 |
| Ca | Geological RMs | Mixed acid attack dissolution and separation of Ca on AG50W-X12 resin | CC-MC-ICP-MS | SSB method required matching of Ca intensities within 3% between sample and standard. Long-term precision of <±0.07‰ (2SD for δ44Ca/40Ca). Capable of determining both radiogenic and stable Ca isotope ratios on small amounts of Ca | 374 |
| Ca, Fe, Mg | Lunar samples | 3-Step purification scheme to separate Ca, Fe and Mg from a single aliquot of sample digest with amounts of these elements down to 15, 20 and 10 μg, respectively, via a combination of columns filled with AG1X-8, DGA and AG50W-X8 resins | MC-ICP-MS, TIMS | Ca isotopes measured by TIMS, Fe and Mg by MC-ICP-MS. Long-term precisions of ±0.03‰, ±0.02‰ and ±0.03‰ for δ44Ca/42Ca, δ56Fe and δ26Mg, respectively, obtained on three USGS basalt RMs | 375 |
| Cd | Geological samples | 111Cd–113Cd double spike added to samples before digestion. Modified two-step column separation procedure employing AG1-X8 and TRU Spec resins, designed to avoid use of HBr to separate Zn from Cd | MC-ICP-MS | Cd and Zn eluted together but did not affect measured Cd isotope data when Zn/Cd < 103. Long-term precision of ±0.05‰ for δ114Cd/110Cd based on measurements of pure Cd solutions | 376 |
| Cd | Geological samples | 111Cd–113Cd double spike added to samples before digestion. Two-step column separation method employing AG MP-1M anion-exchange and BPHA extraction resins | MC-ICP-MS | Sample P/Cd ratios ≥100 shown to result in positive Cd isotope shifts, which may be attributed to organic P compounds co-eluted with Cd from TRU Spec resin; hence use of BPHA instead. δ144Cd/110Cd for USGS rock RMs agreed with published values within analytical uncertainties | 377 |
| Cd | Geological and biological RMs | Evaluation of double spike standard addition method for ultra-trace Cd samples. After sample digestion, 111Cd–113Cd spike added and Cd purified using AG MP-1M resin | MC-ICP-MS | δ 114Cd/110Cd values measured in samples with as low as 2.09 ng Cd consistent with recommended values within uncertainty. No significant difference between single and multiple standard additions of Cd spike. Overall precision 0.041 ± 0.022‰ (2SD, n = 46) | 378 |
| Cd, Cu, Fe, Zn | Rock, soil and sediment RMs | One-step method to separate Cd, Cu, Fe and Zn using AG MP-1M anion-exchange resin. Recoveries were 99 ± 1, 100.1 ± 0.8, 99.8 ± 0.7 and 100 ± 0.8% (2SD, n = 3) | MC-ICP-MS | Method validated by measurements of δ110Cd/114Cd, δ65Cu, δ56Fe and δ66Zn in a range of geological RMs; results for 10 geological RMs agreed with published values within analytical uncertainties | 105 |
| Ce, Nd | Geological RMs | Two-step procedure employed AG50W-X12 column to preconcentrate Ba and REEs before a second column of TODGA cation-exchange resin was used to collect separate Ce and Nd fractions. Yields of Ce and Nd were >99.3% | MC-ICP-MS | SSB combined with Sm and Eu employed as ISs for Ce and Nd respectively, gave long-term reproducibilities of <0.04‰ (2SD) for δ142Ce/140Ce and <0.03‰ (2SD) for δ146Nd/144Nd. Results for 6 rock RMs agreed with published values within analytical uncertainties | 379 |
| Cl | Planetary materials | Cl-bearing solutions were precipitated as AgCl and mixed with Nb powder, before being loaded into stainless steel cathodes prior to insertion in the ion source | AMS | Bulk δ37Cl measurements made with values from 0 to +45‰ with an accuracy of ±1‰ in samples with Cl masses as low as 1 μg; typical precision was 1–3‰. Method designed to complement SIMS and IRMS data | 380 |
| Cr | Terrestrial and cosmos chemical materials | A complex 4-step chemical purification method developed for a range of very diverse matrices including U ores, Cr ore residues and contaminated soils. The Cr yield always >87% with a mean value of 95% | TIMS | A full multi-dynamic data reduction scheme developed. Reproducibilities of 5 and 13 ppm (2SD) for 53Cr/52Cr and 54Cr/52Cr respectively. Accuracy for terrestrial materials confirmed by measuring 4 USGS rock RMs as well as extra-terrestrial samples | 381 |
| Cr | Terrestrial and cosmos chemical materials | Powdered meteorites digested in HF–HNO3 and Cr separated in four-step column separation procedure. Total Cr yield >90% | TIMS | Correlated variation between μ53Cr and μ54Cr in repeated TIMS measurements of isotope RMs thought to be caused by evaporation of Cr-oxide species during thermal ionisation. Problem alleviated by use of W filaments instead of Re filaments | 382 |
| Cu | Geological RMs | Powdered rock RMs digested in HF–HNO3 and Cu purified in two-stage chromatography procedure with AG MP-1M resin | MC-ICP-MS | SSB technique in low resolution mode. Intermediate precision of ±0.030‰ (2SD) for δ65Cu. Data for 11 geological RMs consistent with published values within analytical uncertainties | 383 |
| Fe | Geological RMs | Powdered rock RMs dissolved in mixed acid digestion, and Fe purified in a two-step procedure involving AG MP-1M and AG-1-X8 resins | CC-MC-ICP-MS | SSB technique in low resolution mode with He and H2 added to the collision cell to minimise ArO+, ArN+ and ArOH+ ion formation. Major advantage was high Fe sensitivity, with δ56Fe precisions typically <0.03‰ (2SD) for Fe contents ca. 30 ng mL−1, opening up new applications for small or Fe-depleted samples | 384 |
| Fe | Geological RMs | Samples dissolved in mixed acid digestion and Fe purified by one-step column anion-exchange separation on AG MP-1M resin | MC-ICP-MS | Large-geometry, high-resolution (3000, 10% valley) instrument able to resolve completely Ar-related interferences. Long-term precisions of <±0.03‰ (2SD) for δ56Fe and <±0.06‰ (2SD) for δ57Fe. Values for 5 geological RMs agreed with published data within uncertainties | 385 |
| Hf | Zr-bearing minerals | In situ analysis of RMs | LA-MC-ICP-MS | Hf isotopes and 177Hf16O signals measured concurrently to monitor influence of rate of REE oxide formation on 177Hf/176Hf ratios. SA02 zircon recommended as primary RM for testing accuracy of method as it has a high REE/Hf compared to other zircon RMs | 386 |
| Hf | Cassiterite | In situ analysis of RMs | LA-MC-ICP-MS | Corrections for Lu and Yb interferences required for 177Hf/176Hf determinations in spite of low Yb/Hf and Lu/Hf ratios in cassiterite. Several possibilities for matrix-matched RMs for in situ analysis suggested | 387 |
| K | Carbonates | Dual-column K purification method developed using AG50W-X8 resin to separate K from the carbonate matrix before purification on AG50W-X8 resin. Yield ca. 100% for 100–150 mg sample size | MC-ICP-MS | NIST SRM 1d (limestone) and USGS RM BHVO-2 (basalt) used to confirm accuracy of method. Low and varied δ41K values for RM JCp-1 (coral aragonite) were ascribed to RM heterogeneity | 388 |
| K | Lunar samples | Samples digested in HF–HNO3 mixture, and K separated from other matrix elements in two-stage column procedure with K yield >99% | CC-MC-ICP-MS | Influence of Ca on K isotope measurements dramatically reduced if D2 rather than H2 employed as reaction gas. Long-term precision for QC solution ±0.06‰ (2SD). δ41K values in 6 geological RMs and a seawater RM agreed with literature values within uncertainty | 389 |
| K | Planetary materials | Samples digested in HF–HNO3–HCl mixture and K separated and purified in a two-step ion-exchange column procedure employing AG1-X8 and AG50W-X12 resins. Recoveries >95% | TIMS | Instrument equipped with 1013 Ω amplifier to collect 40K signal; new method for gain and baseline calibrations developed. Long-term producibility 0.40 for ε40K (2SD) with sample size of ca. 50 ng. ε40K values for 7 USGS rock RMs agreed with literature values within uncertainty | 390 |
| K | Geological RMs | Test solutions prepared from a commercial K standard solution (1000 μg g−1) and purified digest of USGS RM AGV-2 (andesite) | CC-MC-ICP-MS | Improved tolerance to differences in K concentrations between standard and sample in SSB method in the measurement of K ratios was achieved by optimising RF voltage applied to the hexapole rods and the He and H2 cell gas flow rates | 391 |
| Li | Geological materials | Samples digested in HF–HNO3 and then aqua regia. Chemical purification was achieved using a single column containing AG50W-X12 resin | CC-MC-ICP-MS | Precision of <±0.20‰ (2SD) for δ7Li in geological RMs over eight months. Values for 11 rock RMs consistent with published data within uncertainty limits | 392 |
| Li, Mg | Geological materials | Digestion in HF–HClO4 acids followed by modified method for chemical purification on a single column containing AG MP-50 resin to reduce separation time, reagent volumes and procedural blanks. Yields of Li and Mg ca. 100% | MC-ICP-MS | Long-term precision of <±0.6‰ for δ7Li and <±0.08‰ for δ26Mg (2SD). Values of Li and Mg ratios in a range of geological RMs agreed well with published data within uncertainty limits | 393 |
| Lu, Hf | Xenotime, apatite, garnet | In situ analysis. A small amount of N2 was added to the carrier gas after the ablation cell to enhance sensitivity | LA-ICP-MS/MS | High purity NH3 was more effective as reaction gas than the 1 + 9 NH3–He mixture often used. A reaction product of 176Hf was measured at mass 258 to separate it from 176Lu and 176Yb. Matrix-matched RMs were required to correct for a matrix-induced bias on 176Lu/177Hf ratios. Accuracy of single-spot ages in xenotime generally <±1.5%, comparable to that obtained by in situ U–Pb analysis | 394 |
| Mg | Carbonates | 4 Magnesite, 5 dolomite and 4 siderite samples analysed. Addition of water vapour before the ablation cell significantly suppressed isobaric interference of 48Ca2+ on 24Mg+ and downhole fractionation | LA-MC-ICP-MS | MGS-3 magnesite, DOL-8 and DOL-9 dolerites, and SD-5 siderite were found to be suitable as calibration standards with intermediate precisions <±0.14‰ (2SD) for δ26Mg and <±0.15‰ (2SD) for δ25Mg | 395 |
| Nd, Sm | Geological samples | Glass RMs with low Nd contents analysed in situ. Small amount of water vapour added to carrier gas prior to LA | LA-MC-ICP-MS | Nd signal intensity improved by factor of 1.9–3.6 with addition of water vapour and different cones in the ICP interface. Sm–Nd isotope data for 8 reference glasses were consistent with recommended values within analytical uncertainty | 396 |
| Nd, Sr | Geological samples | Rock powders digested in HF–HNO3–HCl acids before separation of LREE and Sr from matrix elements on AG50W-X8 resin and purification of the Sr and Nd using Sr-Spec and Ln-Spec resins | TIMS | Demonstration of the capabilities of the latest generation of TIMS instrumentation. External precisions of 5–6 ppm (2SD) for 87Sr/86Sr and 4–5 ppm (2SD) for 143Nd/144Nd reported | 397 |
| Nd, Pb, Sr | Silicate rocks | Sequential separation of Pb, Sr and LREEs from a single aliquot of digested silicate sample. AG50W-X8, Sr-Spec and Ln-Spec resin columns employed to achieve 80–90% recovery of each element with high purity. The LREE fraction was oxidised with >5 mM NaBrO3 prior to loading on the Ln resin | TIMS | Measured Nd–Pb–Sr isotope ratios in 9 rock and sediment RMs from GSJ and USGS were consistent with recommended values within analytical uncertainty | 398 |
| Pb | Geological and cosmochemical samples | Samples digested in HF–HNO3–HClO4 mixture and enriched spike of 207Pb added. No separation procedure. Bi and Pb contents also determined | Quadrupole ICP-MS | SSB combined with matrix matching to correct for mass bias. Good agreement with published Pb isotope ratios for Allende meteorite (Smithsonian Institution) and GSJ RMs JA-2 (andesite), JB-2 (basalt), JB-3 (basalt) and JR-1 (rhyolite) within uncertainty | 399 |
| Pb | Melt inclusions | Mineral grains mounted in epoxy resin and polished until the inclusions were exposed at the surface. 24–90 μm diameter laser spots, low energy fluences (3–4 J cm−2) and low repetition rates (3–4 Hz) with a 193 nm ArF excimer LA system | LA-MC-ICP-MS | A device to remove Hg from the He and sample gas lines reduced the 202Hg background by >80%. Reference glasses KL2-G (2.07 mm Pb) and BCR-2G (11 ppm Pb) used for mass bias correction of samples with low and high Pb contents respectively. Analytical precisions for Pb isotope ratios 20xPb/204Pb in seven geological glass RMs were <1% (2RSD) when 208Pb signals >105 cps | 400 |
| Pb | Geological materials | Sample powders digested in HF–HNO3 and Pb purified on columns of AG1-X8 anion resin. Yields were 82 ± 10% | TIMS | A novel silicon nitride emitter on a Ta filament was developed as a low-cost alternative to silica gel on a Re filament. Good external precision of 0.10–0.18% (2SD, n = 6) was obtained for 20xPb/204Pb ratios in USGS RM BCR-2 (basalt) and Chinese RM GBW08401 (coal fly ash) | 401 |
| Pb, Th, U | Geological materials | Capabilities of a new technology, incorporating an extreme UV LA system operating at 46.9 nm (26.4 eV photon energy) was evaluated for Pb–Th–U isotope measurements. Sample area ablated 8 × 8 μm with depths ≤500 nm, comparable to a single spot analysis by traditional laser-based methods | Extreme UV, TOFMS | 232Th/238U ratios measured directly in geological glasses, FeMn oxide, zircons and monazite were within ±2SD of expected value without external calibration, whereas 206Pb/238U ratios were systematically low and were corrected using NIST SRM 610 (glass) as a non-matrix-matched external calibration standard | 402 |
| Ra, Th | Sediments and porewaters | Dried sediment was spiked with 228Ra before digestion in HF–HNO3–HClO4 acids. After separation from matrix elements on AG resin, Ra and Ba were preconcentrated by MnO2 precipitation before further purification on AG | SC-SF-ICP-MS | 226Ra in 20–50 mL of porewater or 100 mg sediment measured with an internal precision of ca. 1.0%, much better than ca. 3% using conventional radiometric methods. 230Th also determined by ID in separate aliquot for estimation of 226Ra flux from sediment core | 403 |
| Rb, Sr | Terrestrial and cosmochemical materials | In situ method applied to the analysis of small and precious samples | LA-MC-ICP-MS/MS | Instrument fitted with double Wien mass filter. Collision cell filled with SF6; Sr isotopes measured as SrF+ and Rb as Rb+. Accurate measurements of 87Sr/86Sr ratios in the presence of elevated 87Rb/87Sr demonstrated | 404 |
| S | Geological and biological RMs | Comparison of various preparation protocols concluded that for sulfide mineral RMs, addition of H2O2 to main digestion acid mixture significantly increased S recovery. For other silicate RMs, similar δ34S results obtained whether aqua regia or mixed acids with HF were employed | MC-ICP-MS | Good agreement for δ34S and δ33S between results from wet and dry plasma conditions, better precision for dry conditions. Si internal correction significantly improved accuracy and precision. Values obtained for δ34S and δ33S for a range of RMs agreed with published values within analytical uncertainty | 104 |
| Sb | Geological samples | Method developed for rocks with low Sb content (<1 μg g−1). Mixed HF–HNO3 digestion followed by addition of H2O2 and HNO3. A single column containing AG50W-X8 was used to separate the Sb fraction. An aliquot solution containing 5 ng Sb was mixed with 45 g Sb of high purity Sb standard solution for isotope measurements | MC-ICP-MS | SSB combined with Sn internal normalisation technique. Long-term reproducibility for δ123Sb <±0.03‰ (2SD). δ123Sb values for two Chinese RMs, GSD-11 (stream sediment) and GSS-5 (soil) were consistent with other reported values within analytical uncertainties | 405 |
| Sm | Geological samples | New 2-column procedure (AG50W-X12 and TODGA) to extract Sm quantitatively (99.4 ± 0.3%) | MC-ICP-MS | SSB and Eu internal normalisation to correct instrument mass bias. Long-term precision of <±0.04‰ (2SD) for δ152Sm/149Sm significantly better than those of existing MC-ICP-MS and double spike-TIMS methods. Values for GSJ RMs JB-2 (basalt) and JG-2 (granite) agreed within analytical uncertainties with published data | 406 |
| Sn | Geological materials | Sample equilibrated with 117Sn–122Sn during dissolution, and then Sn was purified from the rock matrix using TRU spec resin | MC-ICP-MS | For accurate results, Sn concentration match between sample and bracketing standard should be better than ±20% and Cd/Sn < 0.01. Long-term precision for δ122Sn/118Sn <±0.069‰ (2SD) for a spiked solution of 100 μg g−1 Sn. Values for nine rock RMs agreed with published data within analytical uncertainties | 407 |
| Sn | Cassiterite | In situ analysis of cassiterite embedded in epoxy resin. Natural cassiterite (#cas17) crystal used as matrix-matched RM. New digestion method developed for solution MC-ICP-MS; δ122Sn/118Sn reported as 0.36 ± 0.02‰ for #cas17 | ns LA-MC-ICP-MS | SSB with elemental Sb introduced by solution nebulisation. Precision for δ122Sn/118Sn <±0.12‰ (2SD) | 408 |
| Sn | Terrestrial rocks and chondrites | Novel two-step protocol for chemical separation of Sn using a resin based on tributyl phosphate (TBP), which had a strong affinity for Sn. Sample with ≤200 mg Sn gave an average yield of ca. 80%. Performance of TBP and TRU-Spec resins was compared | MC-ICP-MS | Instrumental mass discrimination was corrected using the exponential law and internal normalisation of 116Sn/120Sn = 0.4460 and corrections for Te and Cd isobaric interferences applied | 409 |
| Sr | Geological materials | After dissolution, Sr was purified on columns containing Sr-Spec resin | MC-ICP-MS | Zr-doped SSB method for simultaneous determinations of 87Sr/86Sr and 88Sr/86Sr resulted in better sample throughput compared to double-spike TIMS. Long-term reproducibilities of ±0.000015‰ (2SD) for 87Sr/86Sr and ±0.03‰ (2SD) for 88Sr/86Sr were comparable to double-spike TIMS precisions | 410 |
| Tc | Environmental samples | Alkali fusion instead of acid digestion prevented loss of Tc and simple Tc separation method established based on TRU Spec resin in alkaline solution | ICP-MS/MS | O2 employed as reaction gas to remove Mo isobaric interference. Spiked recoveries of Tc were >85% for 1 g solid samples. LOD of 99Tc 0.04 pg g−1 for a 1 g solid sample, suitable for rapid monitoring of 99Tc in the environment | 411 |
| Te | Terrestrial rocks and meteorites | New 3-step purification procedure developed based on AG1-X8 and TRU Spec resins. Samples with Te content <50 ng g−1 were processed through an additional step to remove residual matrix elements. Full procedural yields ranged from 85 to 95% | MC-ICP-MS | Double spike technique with 125Te–128Te. Between-run reproducibility of ±0.07‰ (2SD) for δ130Te obtained on solutions containing 6 ng Te. Values for Alexo komatiite RM KAL-1 and 3 USGS RMs agreed within analytical uncertainties with published data | 412 |
| Ti | Rutile and ilmenite | In situ analysis of 5 rutile and 4 ilmenite samples in single fixed position spot mode (30 μm diameter) to increase spatial resolution | fs-LA-MC-ICP-MS | Potential matrix effects identified, making the use of matrix-matched RMs a necessity for accurate 49Ti/47Ti data. KNW rutile (2SD = 0.08‰) and PZH12-15 ilmenite (2SD = 0.09‰) were homogeneous at the 30 μm scale and recommended as bracketing standards | 413 |
| Ti | Rutile | In situ analysis; single spot analytical mode with spot sizes of 10–20 μm | fs-LA-MC-ICP-MS | High sensitivity cones and signal smoothing device employed. Long-term precision of ±0.11‰ (2SD) obtained for δ49Ti in a rutile. Accuracy confirmed by solution MC-ICP-MS. Four rutile crystals homogeneous for δ49Ti within an uncertainty of <0.13‰, making them suitable as RMs for in situ analysis | 414 |
| Tl | Geological samples | After HF–HNO3 digestion, samples refluxed with 15% aqua regia–13% v/v Br2 solution to ensure complete oxidation of Tl to Tl3+. Two-step column method with tributyl phosphate extraction resin and AG50W-X12 cation ion-exchange resin. Recoveries >98% | MC-ICP-MS | External normalisation to NIST SRM 981 (Pb isotopes) with SSB using NIST SRM 997 (Th isotopes) to correct for instrumental mass bias. Overall precision for ε205Tl was ±0.8 (2SD) for USGS RM NOD-A-1 (Atlantic Ocean Mn nodule) expressed as per 104 deviation of 205Tl/203Tl from NIST SRM 997 | 415 |
| W | Geological RMs | 180W–183W double spike added to samples after digestion and W separated on columns of AG50-X8 and AG1-X8 resins. W yields were typically 75–90% | MC-ICP-MS | Measurement precision for δ186W/184W when analysing USGS RM NOD-A-1 (Atlantic Ocean Mn nodule) was <±0.024‰ (2SD). Data for eight USGS geological RMs agreed with published data within analytical uncertainties | 416 |
The availability of commercial ICP-TOF-MS instruments has expanded the range of spatially resolved element information that can be obtained by LA-ICP-MS. Maeda et al.230 assessed the potential of state-of-the-art LA-ICP-TOF-MS instrumentation for quantitative elemental mapping of chondritic meteorites at a spatial resolution of 5 × 5 μm square pixels by comparing it with conventional approaches such as EPMA and LA-SF-ICP-MS in spot-mode. Although the ICP-TOF-MS technique had lower sensitivity and narrower linear dynamic range than SF-ICP-MS, the main host mineral phase(s) of an element could be readily identified and the major and trace element abundances in the phase(s) could be quantified with an accuracy approaching that of the spot analysis. Savard et al.231 described a new protocol for producing elemental distribution maps (Na to U) across a variety of minerals. They used a LA-ICP-TOF-MS instrument incorporating a fast-funnel device to increase the aerosol transport speed. Geological thin sections were mapped at a rate of ca. 12 mm2 h−1 and a resolution of 12 × 12 μm per pixel. The LODs for mid- and heavy masses were 0.1–10 μg g−1. The analytical protocol employed multiple RMs with various matrices (sulfide, mafic-glasses, felsic-glasses, natural apatite) to produce calibration blocks, and quantification was performed using a recently developed data reduction scheme in IOLITE v4. After the software had identified the mineral phases present, a normalisation approach was applied to each of the phases individually, thereby avoiding the need for separate measurements of major elements to act as ISs. A new methodology was developed232 for the thin-layer sampling of zircons to determine REE mass fractions and U–Pb ages simultaneously from depth profiles by ICP-TOF-MS. Element sensitivities were enhanced with an alternative sampler cone and the S/Ns were improved using a multiple-spot LA protocol to construct a ‘moat’ around the analytical area to minimise mixing of particles released from different layers. Mass spectra were acquired every 30 μs and a single analysis sequence corresponded to a sampling depth of about 0.6 μm. Sets of blank and thin-layer measurements were repeated 21 to 31 times to obtain depth profiles for each zircon. Four Quaternary zircon samples with ages between 16 and 110 ka and three zircon RMs (91500, Plešovice and OD-3) were analysed down to sampling depths of 0.59–0.66 μm. The resulting U–Pb ages and REE abundances agreed within analytical uncertainty with previously published values. Application of the technique to zircon samples from the Himalayas revealed multiple thermal events during formation of the zircons.
Because marcasite RMs are scarce, Li et al.237 evaluated the accuracy of using a pyrite (FeS2, isometric) as the RM to calibrate the SIMS measurement of sulfur isotope ratios in marcasite (FeS2, orthorhombic). The δ34S SIMS value for a natural marcasite sample (NJUMc-1) calibrated against a pyrite RM (UWPy-1) agreed within analytical uncertainties with the values obtained by IRMS, thus confirming the reliability of this procedure. A method to determine the S isotope composition of framboidal pyrite by NanoSIMS combined238 high lateral resolution (ca. 1 × 1 μm2) with a reproducibility of better than 0.5‰ (1 SD) for δ34S. This was achieved by improving the transmission and reducing the intensity of the primary beam. Recommendations were provided to minimise the effects on the accuracy of electron multiplier aging and of the distance between the immersion lens and the sample surface.
Trace element zoning in four widely used zircon RMs (91500, Mud Tank, Temora and Plešovice) was investigated239 at sub-μm resolution using focused ion beam SEM coupled to TOF-SIMS. This technique rapidly resolved variations in trace element concentrations at the μg g−1 level with a spatial resolution of 195 nm and revealed that zircon 91500 was the least zoned of the four zircon RMs examined.
A review (49 references) of the elemental analysis of polymetallic deposits by total reflection XRF spectrometry emphasised243 the importance of an appropriate sample-pretreatment strategy to obtain accurate results. Two pretreatment methods, slurry sampling and acid digestion, were described in detail and their relative merits assessed. Pashkova et al.244 described an improved sample preparation procedure for the analysis of ores by TXRFS. Wet grinding of 100 mg of powdered copper–nickel sulfide ores in 4 mL of ultra-pure water with 20 g of grinding balls (1 mm in diameter) produced a homogeneous suspension of ultra-fine particles with a monomodal particle-size-distribution with 90% of the particles <6 μm in size. Relative analytical precisions calculated from duplicate pairs of suspensions were 10, 9, 15 and 16% for Cu, Fe, Ni and S, respectively.
The quantification of low-Z elements (Z < 14) by energy dispersive XRF spectrometry is challenging partly because of scattering from the sample dark matrix. Shao et al.245 developed a chemometric model for Al, Mg, Na and O in geological samples by training the back propagation neural network (BPNN) using the Compton scatter data combined with concentrations of measurable elements. The coefficient of determination between the true and predicted values was >0.95 for these elements, indicating that the BPNN model largely overcame the matrix effects. A new fundamental parameters approach to quantify elements using EDXRFS spectra also focused246 on the accurate measurement of low-Z elements. In this approach, quantitative absorption data for the residual matrix (e.g. contributions from C, N and O) were recorded and used to enhance the resolution of elemental spectra. The method was validated by analysing NIST SRMs 2710 (Montana soil) and 2704 (river sediment); values within 2 to 8% of the reference values were obtained. Yuan et al.247 developed a workflow for the fast recognition of Nb minerals by multi-stage filtration and accurate quantitative analysis and classification by SEM-EDS. The Nb particles were initially identified using a grey threshold value based on pyrite as the grey standard. Subsequently, the chemical composition of the Nb minerals was determined using a combination of two image scans and two EDS acquisitions. The proposed method effectively avoided spending time analysing irrelevant minerals and had potential for the rapid identification of fine mineral particles in large areas, such as in the search for REE minerals in REE deposits.
In a method to estimate the As content of geological samples by wavelength dispersive XRF spectrometry, a novel concept of concentration equivalence factor was developed248 to address the serious problem of line overlap of the As Kα1,2 lines (the most intense As lines) by Pb Lα1,2 lines of similar intensity. A LOD of <10 mg kg−1 was achieved by employing an arsenic–lead concentration-equivalence-factor for the combined As Kα1,2 and Pb Lα1,2 lines peak. This factor was constant for a variety of geological matrices regardless of their Pb content. The analysis of 22 CRMs demonstrated that it was possible to determine As concentrations below 5 mg kg−1 in the presence of lead at concentrations of up to 1000 mg kg−1.
Quantification of the water content in silicate glasses is important in understanding magma evolution and metamorphic reactions. Tu et al.253 described a confocal Raman spectrometry method to measure the content and speciation of water in silicate melts. Synthetic rhyolitic glasses prepared with water contents of 0.33 to 9.05 wt% were shown by synchrotron-FTIR mapping to be relatively homogeneous. Deconvolution of the total-water Raman bands into four Gaussian components enabled the quantification of speciation data for OH groups and (H2O)m molecular clusters; these showed a similar trend to water speciation data derived from FTIR analysis. Papers presenting new data for the water content of amphibole, clinopyroxene and orthopyroxene RMs are included in Table 10.
5.4. Software and databases
Several research groups have developed software for facilitating the processing and reduction of isotopic data. IsoCor was designed254 for the automated calculation of isotope ratios from transient signals generated by coupling chromatography or electrokinetic separation techniques (e.g. CE, GC and LC) to MC-ICP-MS instruments. This stand-alone, open-source application included baseline subtraction, peak detection, mass bias correction, isotope ratio calculation and delta calculation. The user-friendly interface allowed modification of the main parameters to enable a detailed investigation of the raw data. A software package called Parmanu-Gunak was proposed255 as a straightforward data reduction scheme for IDA that could be applied to any isotope system. This software had the advantages over other published spiked-isotope data-reduction programs of being freely available, being cross-platform-based and not requiring knowledge of any programming language to use it. The robustness of the program was demonstrated through the processing of Mo and Nd isotope data.Other freeware packages (written in Python) have become available for the reduction of U–Pb data obtained by LA-ICP-MS. One, U–Pb Saturn, offered256 dynamic graphic interfaces to view, evaluate and plot U–Pb and Pb–Pb isotope data. Online operation gave the operator freedom to change parameters and reprocess data at any stage of data acquisition. The main interface allowed the user to choose the best statistics for drift correction, to include or exclude offset factors and to apply (or not) corrections for common Pb in different modes. Spot analyses could be visualised on Concordia diagrams and all graphic windows were interactive so that any modification to the data treatment was immediately reflected in the data tables. Liu et al.257 wrote an alternative program designated Brama (Bayesian regression and age mapping application) for producing HR spatial maps of trace element and isotope ratios as well as age data from line scans. It was capable of importing data from different quadrupole mass spectrometers and linking them to laser data. Examples of U–Pb dating of calcite and apatite by LA-ICP-MS were provided to demonstrate the key advantages of Brama.
An R package called LABLASTER was designed258 primarily to quantify the elemental composition of carbonate shells and skeletons. Data from a single time-resolved LA-ICP-MS analysis were imported into the software package which automatically identified when the laser penetrated the sample or ablated across a mineral boundary. A smoothing function to de-spike and flatten elevated signals reduced the likelihood of a false-positive detection of a change in the composition of ablated material. By this means, the program was able to identify quickly the analytical signal corresponding to a particular phase for further data processing. This capability increased the transparency and repeatability of such workflows, which would otherwise be time-consuming, laborious and prone to subjective differences between operators if undertaken manually.
A welcome development is the Uranium Isotope Database that contained259 over 14000 entries of U isotope data from more than 320 publications. The data were normalised to the values for US Department of Energy CRM-145 (uranyl nitrate). Metadata provided in the original publications, e.g., sample type, concentrations and measurement technique, were included in the database together with recommended δ238U values for U CRMs and geological RMs. This database will be updated regularly.
6. Abbreviations
| 2D | two dimensional |
| AAS | atomic absorption spectrometry |
| ADMM | alternating direction method of multipliers |
| AEC | anion exchange chromatography |
| AES | atomic emission spectrometry |
| AFS | atomic fluorescence spectrometry |
| ALF | alveolar lysosomal fluid |
| ALS | alternating least squares |
| AMS | accelerator mass spectrometry |
| ANN | artificial neural network |
| APDC | ammonium pyrrolidine dithiocarbamate |
| APGD | atmospheric pressure glow discharge |
| APM | atmospheric particulate matter |
| ASU | Atomic Spectrometry Update |
| ATR | attenuated total reflectance |
| BAM | Bundesanstalt für Materialforschung und -prüfung |
| bam | beta attenuation monitor |
| BCR | Community Bureau of Reference (of the Commission of the European Communities) |
| BET | Brunauer–Emmett–Teller |
| BGS | British Geological Survey |
| BPHA | N-benzoyl-N-phenylhydroxylamine |
| BPNN | backpropagation neural network |
| C18 | octadecyl bonded silica |
| CA | chemical abrasion |
| CC | collision cell |
| CCD | charged coupled device |
| CCT | collision cell technology |
| CE | capillary electrophoresis |
| CF | continuous flow |
| CFD | computational fluid dynamics |
| CI | confidence interval |
| CNT | carbon nanotube |
| COV | coefficient of variation |
| CPE | cloud point extraction |
| CPMA | centrifugal particle mass analyser |
| cps | counts per second |
| CRM | certified reference material |
| CRPG | Centre de Recherches Petrographiques et Geochimiques |
| CS | continuum source |
| CV | cold vapour |
| CVAAS | cold vapour atomic absorption spectrometry |
| CVG | chemical vapour generation |
| DDTC | diethyldithiocarbamate |
| DES | deep eutectic solvent |
| DGA | diglycolamide |
| DGT | diffusive gradient in thin films |
| DLLME | dispersive liquid liquid microextraction |
| DMDSe | dimethyl diselenide |
| DMS | dimethyl sulfide |
| DOC | dissolved organic carbon |
| DOM | dissolved organic matter |
| DP | double pulse |
| DRC | dynamic reaction cell |
| DTW | dynamic time warping |
| EC | elemental carbon |
| ECCC | Environment and Climate Change Canada |
| EDL | electrodeless discharge lamp |
| EDS | energy dispersive (X-ray) spectrometry |
| EDTA | ethylenediaminetetraacetic acid |
| EDXRFS | energy dispersive X-ray fluorescence spectrometry |
| EMBRAPA | Brazilian Agricultural Research Corporation |
| EN | European Committee for Standardisation |
| EPMA | electron probe microanalysis |
| ERM | European reference material |
| ESI | electrospray ionisation |
| ETAAS | electrothermal atomic absorption spectrometry |
| ETH | Eidgenössische Technische Hochschule, Zürich |
| ETV | electrothermal vaporisation |
| EU | European Union |
| FAAS | flame atomic absorption spectrometry |
| FESEM | field emission scanning electron microscopy |
| FGD | flue gas desulfurisation |
| FI | flow injection |
| FIA | flow injection analysis |
| FTIR | Fourier transform infrared |
| GC | gas chromatography |
| GD | glow discharge |
| GEM | gaseous elemental mercury |
| GMD | geometric mean diameter |
| GOM | gaseous oxidised mercury |
| GSJ | Geological Society of Japan |
| HEN | high efficiency nebuliser |
| HG | hydride generation |
| HILIC | hydrophilic interaction chromatography |
| HPLC | high performance liquid chromatography |
| HR | high resolution |
| IAEA | International Atomic Energy Authority |
| IC | ion chromatography |
| ICP | inductively coupled plasma |
| ID | isotope dilution |
| IDA | isotope dilution analysis |
| IL | ionic liquid |
| IMPROVE | Interagency Monitoring of Protected Visual Environments |
| INCT | Institute of Nuclear Chemistry and Technology (Poland) |
| IP | ionisation potential |
| IPGP | Institut de Physique du Globe de Paris |
| IRMM | Institute for Reference Materials and Measurements |
| IRMS | isotope ratio mass spectrometry |
| IS | internal standard |
| KED | kinetic energy discrimination |
| k-NN | k-nearest neighbour |
| LA | laser ablation |
| LC | liquid chromatography |
| LEQ | linear electrodynamic quadrupole |
| LIBS | laser-induced breakdown spectroscopy |
| LIF | laser induced fluorescence |
| LII | laser induced incandescence |
| LLE | liquid liquid extraction |
| LLME | liquid liquid microextraction |
| LOD | limit of detection |
| LOQ | limit of quantification |
| LPE | liquid phase extraction |
| LPME | liquid phase microextraction |
| LREE | light rare earth element |
| μLIBS | micro laser-induced breakdown spectroscopy |
| μSPE | micro solid phase extraction |
| μXRFS | micro X-ray fluorescence spectrometry |
| MAC | mass absorption cross section |
| MAD | microwave-assisted digestion |
| MAE | microwave-assisted extraction |
| MC | multicollector |
| MCE | mixed cellulose ester |
| MCG | magnetic colloidal gel |
| MCR | multivariate curve resolution |
| MDL | method detection limit |
| MeHg | methyl mercury |
| MFC | mass flow controller |
| MICAP | microwave inductively coupled atmospheric-pressure plasma |
| MIP | microwave induced plasma |
| MOF | metal–organic framework |
| MP | microwave plasma |
| MPT | microwave plasma torch |
| MRI | magnetic resonance imaging |
| MS | mass spectrometry |
| MS/MS | tandem mass spectrometry |
| MWCNT | multi-walled carbon nanotube |
| MWCO | molecular weight cut-off |
| m/z | mass to charge ratio |
| NAA | neutron activation analysis |
| NBL | New Brunswick Laboratory |
| NCRM | National Research Centre for Certified Reference Materials, China |
| NCS | NCS Testing Co., Ltd (China) |
| NERC | Natural Environment Research Council (UK) |
| NIST | National Institute of Standards and Technology |
| NMR | nuclear magnetic resonance |
| NP | nanoparticle |
| NRCC | National Research Council of Canada |
| NRCSM | National Research Center for Standard Materials, China |
| NSMCC | National Standard Material Centre of China |
| NWRI | National Water Research Institute |
| OC | organic carbon |
| OM | organic matter |
| OPC | optical particle counter |
| P | pressure |
| PAN | 1-(2-pyridylazo)-2-naphthol |
| PAS | passive air sampler |
| PCA | principal component analysis |
| PD | point discharge |
| PFA | perfluoroalkyl |
| PILS | particle into liquid sampler |
| PIXE | proton induced X-ray emission |
| PLS | partial least squares |
| PM | particulate matter |
| PM2.5 | particulate matter (with an aerodynamic diameter of up to 2.5 μm) |
| PM2.5–10 | particulate matter (with an aerodynamic diameter of between 2.5–10 μm) |
| PM10 | particulate matter (with an aerodynamic diameter of up to 10 μm) |
| PMT | photomultiplier tube |
| ppb | parts per billion |
| ppm | parts per million |
| ppqv | parts per quadrillion per volume |
| ppt | parts per trillion |
| PSL | polystyrene latex |
| PTE | potentially toxic element |
| PTFE | polytetrafluoroethylene |
| PVG | photochemical vapour generation |
| pXRFS | portable X-ray fluorescence spectrometry |
| QC | quality control |
| QF | quartz fibre |
| REE | rare earth element |
| RH | relative humidity |
| RM | reference material |
| RMSE | root mean square error |
| rpm | revolutions per minute |
| RSD | relative standard deviation |
| SAA | surface area analysis |
| SAX | strong anion exchange |
| SBET | simplified bioaccessibility extraction test |
| SBF | simulated body fluid |
| SCR | selective catalytic reduction |
| SCX | strong cation exchange |
| SD | standard deviation |
| SDD | silicon drift detector |
| SDEP | semi dry electrostatic precipitator |
| SEM | scanning electron microscopy |
| SF | sector field |
| SFOD | solidified floating organic drop |
| SHRIMP | sensitive high resolution ion microprobe |
| SI | système international d’unités |
| SIMS | secondary ion mass spectrometry |
| S/N | signal-to-noise ratio |
| sp | single particle |
| SPE | solid phase extraction |
| SPME | solid-phase microextraction |
| SPS | spectrapure standards |
| SQT | slotted quartz tube |
| SRM | standard reference material |
| SSB | sample standard bracketing |
| SSID | species specific isotope dilution |
| T | temperature |
| TBP | tributyl phosphate |
| TC | total carbon |
| TD | thermal desorption |
| TEM | transmission electron microscopy |
| THF | tetrahydrofuran |
| TIMS | thermal ionisation mass spectrometry |
| TOA | thermal optical analysis |
| TODGA | N,N,N′,N′-tetraoctyl diglycolamide |
| TOF | time-of-flight |
| TOR | thermal optical reflectance |
| TOT | thermal optical transmission |
| TSP | total suspended particle |
| TWA | time weighted average |
| TXRFS | total reflection X-ray fluorescence spectrometry |
| UA | ultrasound-assisted |
| UAE | ultrasound-assisted extraction |
| UAV | unmanned aerial vehicle |
| USGS | United States Geological Survey |
| UV | ultraviolet |
| VCDT | Vienna-Cañon Diablo Troilite |
| VG | vapour generation |
| VOC | volatile organic carbon |
| VPDB | Vienna Peedee Belemnite |
| VSM | vibrating sample magnetometry |
| VSMOW | Vienna Standard Mean Ocean Water |
| WDXRFS | wavelength-dispersive X-ray fluorescence spectrometry |
| WEEE | waste electrical and electronic equipment |
| WSOC | water soluble organic carbon |
| XAFS | X-ray absorption fine structure |
| XAS | X-ray absorption spectroscopy |
| XRD | X-ray diffraction |
| XRF | X-ray fluorescence |
| XRFS | X-ray fluorescence spectrometry |
| Z | atomic number |
Conflicts of interest
There are no conflicts to declare.References
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