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

Received 12th October 2022

First published on 3rd November 2022


Abstract

In the field of air analysis, highlights within this review period included: a new in situ method for measuring resuspended road dust arising from vehicular movements; new ink-printed filter reference materials for black- and elemental-carbon measurements; coupling of a scanning mobility particle sizer to a single-particle-ICP-MS instrument for improved nanoparticle characterisation; developments in total-reflection XRF spectrometry for trace analysis and evaluation of vibrational spectroscopic techniques for measuring respirable crystalline silica in the workplace. The increasing availability of ICP-MS/MS instruments is revolutionising the analysis of environmental samples such as waters for trace elements. The advent of the mass shift mode makes some elements such as P and S much easier to quantify and allows the REEs and some radioisotopes to be determined at much lower concentrations than previously possible. Advances in vapour generation methods are mostly limited to photochemical and chemical vapour generation as reflected in the new table listing the main advances. Solid or liquid phase extraction prior to analysis remains of great interest, although a notable trend is the synthesis of new materials rather than optimisation of commercially available chelating agents and columns. The analytical effort presented in a paper is sometimes much less than the effort put into the synthesis of the materials so one wonders about the likelihood of methods actually being used and results replicated. Notable in the analysis of soils and plants was the unusually large number of review articles – possibly because practical research was hampered by the Covid-19 epidemic. Areas of continued growth were research on nanoparticles, the application of high-resolution continuum source AAS for multielement analysis, the development of miniaturised AES instruments that may ultimately be field-portable and application of LIBS to the analysis of plant materials. A concerted effort to characterise natural minerals that are sufficiently homogeneous to act as reference materials in the microanalysis of geological materials has resulted in the availability of new materials for isotope ratio determinations. Tied to this has been research into U–Pb dating of zircon and a variety of other accessory minerals by LA-ICP-MS and SIMS. New chemometric models have been developed to handle the complex LIBS data arising from the analysis of geological matrices in the field and during ore processing. Studies on the use of ICP-MS/MS to reduce polyatomic interferences in geological applications were widespread, reflecting the availability of such instruments. In contrast, the potential offered by integrating LIBS data with those from LA-ICP-MS has only just started to be explored but is likely to increase with the development of commercial instruments.


1 Introduction

This is the 38th annual review of the application of atomic spectrometry to the chemical analysis of environmental samples. This Update refers to papers published approximately between August 2021 and June 2022 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 critical insights 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 Review papers

It was concluded7 in a review (59 references) of analytical techniques for determining the elemental content of APM that whilst direct analysis of filter samples by XRFS could potentially replace ICP-based approaches, new filter-based calibrants were required. Similarly, new calibrants and autosamplers were required if the potential of LA-ICP-MS were to be exploited. In a comprehensive review (167 references) of techniques for the chemical characterisation of indoor-air particles, the authors highlighted8 the challenges posed by noise effects and space requirements associated with indoor sampling and the need for handling and interpreting large complex data sets. They also suggested that there is a need for closer collaboration between scientists making indoor and those making outdoor measurements, as well as with epidemiologists and toxicologists. It was concluded9 in a review (39 references) of recent developments in the determination of the chemical composition of PM2.5 that new representative RMs and new portable analytical systems for in situ measurements are needed. As vehicle engines become cleaner and tailpipe emissions decrease, attention is now focusing on the contribution of non-exhaust emissions, e.g. road dust, as pollutant sources. An editorial review paper (35 references) presented10 16 themed papers that discussed the sources, composition, accumulation, pathways, impact and management of road dust in urban and industrial environments. Similar topics were discussed11 in a review (257 references) in which it was noted that to date there have been few source-specific studies and that current toxicological and epidemiological evidence did not provide a clear picture of the health risks posed.

2.2 Sampling techniques

An eclectic mix of new sampling platforms has been reported. The “SCAMPER” (System for the Continuous Aerosol Measurement of Particle Emissions from Roads) system measured12 road-dust resuspension values by determining the PM10 concentrations both ahead of a vehicle, through use of an isokinetic sampling inlet attached to an OPC mounted on or near the bonnet, and in the vehicle’s wake, through use of a second OPC unit mounted on a flatbed trailer towed behind. The “CC-TRAIRER” (Climate Change-TRailer for AIR and Environmental Research) system13 was a small towed-caravan with OPCs for PM1, PM2.5, PM4 and PM10 measurements, NOx and O3 gas analysers and a filter sampler for gravimetric and chemical analysis. Information on power requirements, cabin climate control and data transmission systems were summarised and a useful tabulation given of mobile laboratory equipment used in 16 other air monitoring studies. The sampling of emissions from cooling towers is challenging due to concerns over accessibility and working at heights. A unique pallet-based system incorporated:14 a phase Doppler interferometer to measure size and velocities of emitted droplets; a sampling manifold that included a drier unit to capture both PM2.5 and PM10 particles on filters for laboratory-based XRF analysis; and both APS and OPC instrumentation for monitoring particles in real-time.

Brown carbon particles contribute to global warming because they can absorb sunlight at relevant wavelengths but understanding of their prevalence and impact is limited by the lack of atmospheric measurements. Systems that utilised either a particle-into-liquid sampler (two variants examined) or a mist chamber sampler coupled to an absorption spectrometer were evaluated15 for use on-board a survey aeroplane. A new instrument developed for ground-based black carbon measurements consisted16 of a CEN-compliant PM-filter-based sampler (with either a PM2.5 or PM10 inlet) together with an integral optical module that enabled passing particles to be monitored prior to their deposition on a filter. The analysis of filter samples in the laboratory for EC and OC enabled calculation of a MAC value for each specific sampling location so that the black carbon absorbance measurements at 635 nm could be converted to the equivalent mass concentrations.

Two new air sampler designs of note were reported. The Versatile Aerosol Concentration Enrichment System (VACES) enabled17 simultaneous sampling of ultrafine particles both on filters and in a liquid suspension for subsequent chemical and toxicity measurements. The Time Resolved Atmospheric Particle Sampler (TRAPS) coupled18 a rotary cascade impactor to an OPC so that both coarse particles (1 μm) and fine particles (0.1 μm) could be monitored at high temporal resolution.

The sampling of volatile metal(loid) species remains a challenge. The microbial-mediated volatilisation of Sb is a poorly understood component of its biogeochemical cycle, so a study was undertaken19 to ascertain suitability of sampling methods to trap volatile Sb. Although sampling into impingers containing HNO3/H2O2 best preserved volatile trapped Sb species, preconcentration onto solid-phase traps containing AgNO3-impregnated silica gel was preferable for remote locations and for achieving a lower method LOD. The performance of both KCl-impregnated sorbent traps and KCl-liquid impinger samplers, widely used to trap gaseous oxidised mercury (GOM), were evaluated20 using a novel 197Hg radiotracer procedure. Reduction of some of the collected Hg2+ species to Hg0 resulted in losses from the sorbent traps even when spiked only with a mass (<1 ng) typical of that collected when clean ambient air is sampled. In contrast, a positive GOM bias observed when spiked KCl-liquid impingers were used was attributed to a small portion of the co-sampled gaseous elemental mercury (GEM) being oxidised. Atmospheric GEM concentrations far exceed GOM concentrations so this finding suggests that the use of impinger-based samplers for GOM is not appropriate.

2.3 Reference materials, calibrants and interlaboratory comparisons

It is encouraging to see development of new reference materials for air analysis. New multielement RMs for XRFS analysis were prepared21 by re-aerosolisation onto PTFE filters of small quantities (0.5 and 5.5 mg) of either NIST SRM 2583 (trace elements in indoor air (nominal mass fraction of 90 mg kg−1 Pb)) or NIST SRM 2584 (trace elements in indoor air (nominal mass fraction of 1% Pb)). A procedure for preparing filter-based RMs for the measurement of both black carbon and brown carbon by optical techniques and for measuring OC and TC fractions by combustion techniques involved22 a novel approach in which a commercially available inkjet printer was used to print ink containing organic and inorganic components onto filter media at programmable print densities. In order to address the lack of RMs for studies using the oxygen-isotope mass-independent fractionation signal, a useful metric for probing the pathways of atmospheric sulfates, purified O3 was reacted23 with sodium sulfite to produce three 17O-enriched sulfate candidate RMs that were analysed using a pyrolysis method calibrated using USGS RM 35 (nitrogen and oxygen isotopes in sodium nitrate).

Testing of a mini inverted soot generator revealed24 that soot particles from the combustion of propane had higher EC[thin space (1/6-em)]:[thin space (1/6-em)]TC ratios and absorbed more light than particles generated from the combustion of ethylene. The coupling of a micro smog chamber to a miniCAST 5201™ soot generator made25 it possible to generate stable and reproducible model aerosols that mimicked combustion particles found in ambient air. The particles produced ranged from “fresh” soot (typically <100 nm in size, SSA < 0.05, AAE ca. 1 and EC[thin space (1/6-em)]:[thin space (1/6-em)]TC > 0.9) to “aged” soot (up to 200 nm in size, SSA up to 0.7, AAE up to 1.7 and EC[thin space (1/6-em)]:[thin space (1/6-em)]TC < 0.1) and will be useful for method standardisation and intercomparison exercises.

The provision of new isotopic data for existing RMs is beneficial for supporting the growing interest in the use of isotopic fingerprinting in source apportionment studies. A high-yielding (82–97% recoveries) column-based chromatographic procedure was used26 to isolate Hf, Nd and Sr from NIST SRM 1633b (coal fly ash), 1648a (urban particulate matter) and IRMM CRM BCR 723 (vehicular road dust) for isotopic analysis by MC-ICP-MS. Provisional Hf176/Hf177, Nd143/Nd144 and Sr87/Sr86 data were reported. Similarly, the NIST SRM 1648a (urban particulate matter) and NIST SRM 1649a (urban dust) were analysed27 by MC-TIMS and MC-ICP-MS to determine the Am, Np, Pu and U contents and isotopic ratios. The high Np, Pu and U concentrations measured in these two SRMs are indicative perhaps of the legacy of atmospheric fall-out of radioactive particles from nuclear bomb tests.

2.4 Sample preparation

Innovations in sample preparation are always welcome. The coupling of a microextraction assembly directly to an ICP-MS instrument enabled the direct isotopic analysis of either Pu28 or U29 particles collected on cotton swabs for rapid nuclear-safeguarding purposes. A flow of 2% (v/v) HNO3 solvent rinse flushed deposited actinide material from a swab directly into the ICP-MS instrument for analysis. Validation involved the successful analysis of several Pu and U CRM particles that had been deposited on test swabs using a particle manipulator. Although stable Hg isotope measurements are used in environmental tracer studies, the acid digestion of samples remains fraught with potential problems of analyte loss and cross-contamination. To overcome these problems, a combustion-based analyser was modified30 to enable the thermal release of Hg and trapping in a solution of 10% HCl–BrCl (5[thin space (1/6-em)]:[thin space (1/6-em)]1 v/v) prior to analysis by CV-MC-ICP-MS. No appreciable carryover was noted as blank values were <1% of the concentration of Hg introduced. Recoveries were >90% and samples were processed in <15 min. The isotopic data for several CRMs were statistically indistinguishable from the reported values. Gravimetric analysis of air filter samples remains a tedious and time-consuming activity but the development of robotic systems has made unattended automated operations a reality. The development of AIRLIFT extended31 measurement operations beyond just filter weighing. The system consisted of a sealed environmentally-controlled chamber, a 6-axis articulating robotic arm, a 6-place balance for filter weighing and an optical measuring system for determining black carbon content. Up to 240 filters could be processed in a day with an estimated four-fold reduction in labour requirement.

Two studies on sample preparation for XRFS are noteworthy. In the first, a stirring device ensured32 that ZnO NPs remained suspended in water whilst being interrogated in an X-ray beam. Otherwise, agglomeration and sedimentation occurred rapidly as indicated by a 2.5% per min reduction of the fluorescence signal. In the second study, a casting procedure for the analysis of a SiO2 powder involved33 dispersing a measured quantity of SiO2 in a known amount of epoxy resin that was then poured into a plastic X-ray sample cup and cured to prepare sample discs. The good linearity (R2 = 0.997) for test discs (30 mm diameter, 5 mm thickness) doped with 1–5% (m/m) SiO2 indicated that this approach could be a useful alternative to methods involving either fused beads or pressed pellets.

2.5 Instrumental analysis

2.5.1 Atomic absorption and emission spectrometries. A review (154 references) on the use of AAS considered34 papers published in the period 2000–2020. The review focussed on the use of line source ETAAS and CS-ETAAS for elemental determinations in various matrices and included references to six application papers in which the concentrations of the elements Al, As, Cd, Cr, Cu, Fe, Mn, Ni, Pb and Zn in APM were determined. A new method for the determination of Hg0 in workplace air involved35 sampling onto a graphitic sorbent from which Hg0 was released thermally within a combustion-based analyser for analysis by AAS. Recoveries from spiked sorbents were ca. 100%. The LOQ of 0.44 ng corresponded to 29 ng m−3 for a nominal air sample volume of 15 L.

A review (130 references) on the use of LIBS for online measurements of air pollutants showcased36 the analysis of APM and the determination of S and halogens in gaseous VOCs. Further developments in the application of LIBS and SIBS to the analysis of APM are summarised in Table 1.

Table 1 Developments in LIBS and SIBS for APM measurements
Analyte Matrix Study aim Technique Findings Reference
Ag-coated glass particles Test spherical particles Development of a direct reading particle sizer and elemental analyser for large inhalable particles LIBS Prototype instrument was able to provide accurate sp measurements of aerodynamic diameter over 25–125 μm range using a TOF calculation in a laboratory setting using spherical particles 295
Ti particles Successful integration of LIBS without compromising TOF measurements
Future work to include determining LIBS detection efficiencies and testing in the field with non-spherical and polydisperse aerosols
Fe, Ni, Ti Air filter samples of exhaust gas from a boiler operation Investigation into the use of a double-pulse LIBS procedure to enhance emission intensity LIBS Combination of 355 and 1064 nm laser wavelengths provided the best enhancement effect 296
The intensity of emission lines by a double-pulse laser was ca. 10× that of a single-pulse laser
Various Air filter samples from Antarctica Rapid elemental APM characterisation on filters in remote locations LIBS New approach enabled the elemental composition of APM sampled onto filters to be determined rapidly 297
Undertaken with minimal sample preparation and preparation in field conditions at remote locations without recourse to use of complex equipment
Various Test aerosols generated using nebulised elemental standards Evaluation of the performance of a prototype SIBS instrument SIBS Machine-learning models seemed to have better predicative accuracy and lower LODs than conventional univariate calibrations 298
The least absolute shrinkage and selector operator model performed best with R2 > 0.8 achieved and LODs of 0.04–0.17 μg m−3 determined at a flow rate of 15 L min−1 with a sampling duration of 30 min
Various Test aerosols generated using nebulised elemental standards Evaluation of the performance of a prototype SIBS instrument SIBS LODs between 0.05 and 0.81 μg m−3 determined for elements such as Co, Cr, Cu, Fe, Ni and Zn at a flow rate of 15 L min−1 with a sampling duration of 30 min 299
Spectral overlaps, matrix effects and instrumental sensitivity issues currently hinder measurement of other elements of interest such as As, Cd, Hg, Pb, Sb and Se


2.5.2 Mass spectrometry.
2.5.2.1 Inductively coupled plasma mass spectrometry. A review (80 references) on the application of ICP-MS/MS to environmental studies included37 analyses of atmospheric particles, NPs and road dusts. Other pertinent reviews were on the application of FFF-ICP-MS to the characterisation of engineered metal NPs (103 references)38 and on advances in sp-ICP-MS (301 references).39

Although papers that advocate use of LA-ICP-MS for the analysis of APM collected on filter samples have been published in recent years, a more critical insight has now been presented.40 Useful conclusions reached were that: the NIST RM 8785 (air particulate matter on filter media) was unsuitable as a LA calibration standard; analysing a representative portion of a filter in minimal time required a judicious selection of laser beam size and ablation area; and use of less energetic 213 nm lasers was preferable to the use of 193 nm lasers because this minimised the ablation of the quartz filter media itself and thus reduced background elemental contributions to the analytical signal. It was noted that further instrumental developments were required before this approach could be deployed routinely. These included: lasers with increased beam sizes for increased filter ablation coverage; ablation cells with faster wash-out characteristics; and autosamplers for the automated processing of filter samples.

The coupling of a SMPS to a sp-ICP-MS instrument for improved interrogation of NPs involved41 connecting a differential mobility analyser unit, in which charged aerosol particles in a flow of N2 gas were separated by means of their electrical mobility, to a modified RDD. The latter enabled both the aerosol particle stream to be diluted and an Ar carrier gas to be introduced to sustain the ICP-plasma. A sample splitter placed after the RDD allowed aerosol to be sent both to a CPC (to count particles) and to the sp-ICP-MS instrument (to provide data on particle size, count and mass distributions). The novelty of this configuration was that the switching between N2 and Ar gas flows could be carried out downstream of the differential mobility analyser thereby enabling this device to work efficiently. This had not been possible in previous studies in which Ar carrier gas was used throughout.

Further ICP-MS applications are summarised in Table 2.

Table 2 Application of ICP-MS for APM measurements
Analyte Matrix Sample preparation Technique Findings Reference
Fe, Ni Air filter samples Microwave-assisted digestion as per EN 14902 ICP-MS/MS H2 collision gas (Fe) and H2 + NH3 gas (Ni) mediated mass-shift cell-chemistry optimised for improved Fe and Ni measurements in supporting future air quality and potential source apportionment measurements 300
Fe, Ti NPs emitted from coal-fired power stations Extracted from particle emission control devices e.g., bag filtration sp-ICP-MS Mass of NPs that escape chimney stacks determined to be low 301
Fe and Ti were the most abundant elements in those NPs released at a rate of up to 1.9 × 1018 and 1.6 × 1018 particles per h
Other metals release in NPs included Pb and Zn
Sr Atmospheric particles (PM10) Acid digested ICP-MS/MS CH3F-mediated mass-shift cell-chemistry optimised for improved Sr87/Sr86 measurements 187
No need for prior Rb/Sr separation
Various Gunshot residue particles Inside of shooters’ gloves rinsed with a detergent/water sp-ICP-TOF-MS Rinsing method useful to extract small particles where extraction via tape-lift or adhesive stubs was inadequate 302
Elemental profiling of <100 nm particles possible
Complemented existing SEM-EDS methods
Various Nanoscale mineral dust aerosol (MDA) in snow Melting snow sp-ICP-TOF-MS Median MDA composition largely equated to known crustal elemental abundance ratios 303
Particle size and composition of MDAs were effectively measured in wet deposition samples but there was a greater uncertainty in measuring the particle number



2.5.2.2 Mass spectrometry techniques other than ICP-MS. New and improved instrumental approaches are always welcome. Use of a new sampling inlet, the Soot Particle Agglomeration Inlet, made42 it possible to analyse NPs by aerosol mass spectrometry. This had not previously been possible because the small size of the particles made them undetectable. The NPs were passed initially through a soot chamber so that they agglomerated on the surface of larger soot particles and so became detectable. A possible application could be the analysis of particles <23 nm in size emitted from engines for which there is growing regulatory interest. A new QMS method for the quantification of sea-salt particles employed43 a graphite particle collector and a CO2 laser ionisation system so that high desorption temperatures (up to 930 °C) could be achieved. The prototype system was equipped with an inlet optimised for the sampling of <1 μm particles so further development is required to design an inlet which can sample larger sea-salt particles effectively.

Identifying sources of actinide-containing particles collected on swab samples is important for nuclear safeguarding purposes. A new thermal ion emitter improved44 U ionisation efficiencies in a new procedure in which particles of interest were initially identified using SEM-EDS and then transferred by a micromanipulator for TIMS analysis. The relative errors for 13 certified U particles (1.3–4.7 μm in size) were <2.7, <1.1 and <4.5% for 234U/238U, 235U/238U and 236U/238U, respectively. The corresponding RSDs were 1.6, 0.5 and 3.3%.

2.5.3 X-ray spectrometry. Although the sensitive TXRFS and allied techniques have potential in air pollution studies because elemental concentrations in APM can be in the low ng m−3 range, attenuation and depth effects can arise from the analysis of overloaded samples. Experiments into the use of a grazing incidence set-up at a synchrotron facility made45 it possible to extend the quantifiable range of TXRFS. This approach could, it was suggested, be transferable to portable TXRFS units for field operations. Researchers at the University of Brescia used46 their proprietary SMART STORE® sample preparation procedure to encapsulate and thereby sandwich Pb-containing calibrant filters between transparent PP film sheets in order to produce ideal flat samples for TXRFS analysis. Filters were analysed under grazing incidence conditions which enabled a broader sample area to be illuminated and hence enhancement of the fluorescence emission. The LOD of 0.0065 μg cm−2 provided potential for trace measurements in ambient air. Further work will consider other elements of regulatory interest such as As, Cd, Hg and Ni. By sampling onto 20 × 20 mm polished Si wafers using a 7-stage May-type cascade impactor sampler, it was possible47 to use portable TXRFS to quantify the elemental composition of size-fractioned particles 70 nm to 10 μm in size. The LODs were as low as ca. 0.1 ng m−3. The optimum sampled air volume of ca. 4 m3 (4 h sampling at 16.7 L min−1) balanced the need for timely measurements to track short-lived pollution episodes with the need for sufficient sample mass for analysis. Complementary TXRFS and XANES measurements undertaken at a synchrotron facility provided useful morphological information to support source identification and apportionment studies.

The application of SEM-EDS, a well-established technique for the determination of the elemental composition of imaged particles, was reported in two aerosol-related studies. In the first,48 the analysis of 98 TSP dust samples from various ore processing operations within a nickel refinery plant generated compositional data for individual particles. Process-specific emission sources could be identified so plant operatives could implement dust control systems optimised for location and activity. Future work will examine the composition and morphology of fine (<2.5 μm) and ultrafine (<100 nm) particles because these can be inhaled by workers and may have different toxicities than larger TSPs. From an occupational exposure perspective, it will be interesting to compare new particle data with elemental fractionation data generated using the industry-specific Zatka leaching protocol, which involves the sequential leaching of air filter samples in extractants of increasing potency and subsequent analysis by ICP spectrometry. In the second publication,49 use of the SEM-EDS technique helped elucidate the morphology, chemical composition and wear alteration of brake assembly components (pads and discs) and of released particles. Findings will help the industry to optimise pad components for more efficient operation whilst simultaneously minimising emitted wear particles, the presence of which in the urban atmosphere is of growing concern.

Other applications of XRFS to the analysis of APM are presented in Table 3.

Table 3 Application of X-ray techniques for APM measurements
Analyte Matrix Study aim Technique Findings Reference
As Ambient air particles (TSP and PM2.5 fractions) As speciation study SR-XRFS The AsIII[thin space (1/6-em)]:[thin space (1/6-em)]AsV ratio determined in TSP was 82[thin space (1/6-em)]:[thin space (1/6-em)]18 304
SR-XANES Total As determined in TSP was 2.7 ± 0.7 ng m−3
Total As determined in PM2.5 was 1.6 ± 0.6 ng m−3
As, Cr, Se Coal fly ash Solubility/toxicity study SR-XANES Soluble hence mobile fractions that contained AsV, CrVI and SeIV species determined and various treatment to render them immobile recommended 305
LC-ICP-MS
Cr, Zn Fine (PM2.5) and coarse (PM10–2.5) aerosol fractions Cr and Zn speciation study EDXRF Cr2O3 and Cr2(SO4)3 dominant species found in both fractions 306
SR-XANES Zn2SiO4 and ZnSO4 found in both fractions
ZnCl2 found only in coarse fraction
ZnC2O4 found only in fine fraction
Origin of Cr and Zn species suspected to be from local anthropogenic sources such as combustion sources and/or resuspended road dust
Fe Antarctic aerosol samples Fe speciation and oxidation study to understand better factors affecting Fe solubility and bioavailability in the surface ocean SR-XRFS Fe mineral-phase contained mostly hematite and biotite 307
SR-XANES FeII content in particles ranged between 60% (summer) and 71% (winter)
Fe Urban aerosols Fe speciation study SR-HERFD-XANES Better resolution with HERFD-XANES over conventional XANES for improved Fe species identification 308
Mg Aeolian dust originating from semi-arid regions of Asian continent transported by westerly winds to Japan (KOSA dust) Mg speciation study SR-XANES Mg mostly found in phyllosilicates rather than carbonate minerals suggesting that the contribution of Mg to neutralisation reactions in the atmosphere may be lower than previously expected 309
Ni PM10 aerosol fraction Identification and sources of Ni-containing emissions in an industrialised location Near real-time in situ XRFS Hourly air samples analysed with concentrations up to 2480 ng m−3 determined 310
Dominant emissions sources identified were a Ni refinery (90%) and a steel-mill (10%)
Ti Size fractionated aerosol particles Ti speciation study SR-XANES Several different Ti species determined in particles including anatase, ilmenite, rutile and titanite suggesting that the photochemical reactivity of Ti in aerosols, as determined in laboratory simulation studies, may be over-estimated because only TiO2 is employed as a model species 311
Various PM2.5 and PM10 aerosol fractions in an urban environment Identification and sources apportionment of the elemental fraction of APM Near real-time in situ XRFS Thirteen sources of elements identified including: biomass burning (7.2%); construction (4.3%); dust (22.1%); heavy-vehicles (17%); industry (3.3%); light-vehicles (5.4%); railways (6.6%); wind-blown dusts (9.5%); sea-salt (5.4%) and sulfates (15.4%) 312
Various PM2.5 and PM10 aerosol fractions in an urban environment Intercomparison of online (XRFS) and offline filter measurements (ICP-MS) Near real-time in situ XRFS Highly correlated (R2 > 0.8) for major elements such as Al, Ba, Ca, Fe, K, Mn, Pb, Ti and Zn. However, differences of 10–40% noted for some elements. Suggested variables here could include: distance between respective PM2.5 sampling inlets; spectral overlaps in XRFS measurements; filter digestion efficiencies and sample-to-sample variation in element contents in blank filters 313
ICP-MS


2.5.4 Other techniques. New ways of measuring exposure to diesel fumes included the first use of micro-Aethalometers™ sensors to measure50 the exposure of workers to black carbon in the harsh environment of a platinum mine. From a process-control perspective, the fast measurement response rate of this sensor was beneficial for assessing the magnitude of the often-transient emissions from various engines employed in the mine. However, from a worker’s exposure perspective there remains a need to convert transient black carbon data to equivalent time-weighed EC data as this latter metric underpins workplace diesel fume exposure limits. Both the OC and EC contents of DPM collected on filters were predicted51 by FTIR analysis. Spectral measurements in the region between 3000 and 2800 cm−1, associated with the stretching of aliphatic CH2 and CH3 functional groups, were used to estimate OC content. The EC content was estimated by integrating the absorbance in the 4000–3796 cm−1 spectral region associated with a broad π → π* transition in the aromatic ring structures. Analysis of the same filter samples by the existing NIOSH 5040 TOA combustion method enabled a TOA-FTIR linear regression model to be developed and hence a means of cross-calibration. Further work is however required to test this FTIR approach in other environments in which DPM is emitted and assess its potential for timely measurements in the workplace using portable instruments. This would contrast with TOA measurements which require filter samples to be shipped to a laboratory for analysis. The sub-μm size of DPM results in deep penetration of the particles into the lung and its large surface area facilitates transport of toxic gases into the lung as species condensed on particle surfaces. There is therefore growing interest from a health perspective in looking at new metrics such as particle surface area. Black carbon measurements were undertaken52 in different locations in Helsinki using an Aethalometer™ and lung deposited surface area (LDSA) measurements were made using an ELPI+™ instrument. The average LDSA per black carbon mass determined in DPM sampled in the harbour region was 2.4–2.7 times the value determined in particles from a road traffic environment. This finding indicated that the make-up of emitted particles depended upon the type of diesel engines used, their mode of operation and the fuels consumed, and their subsequent interaction with other airborne species.

The portability of vibrational spectroscopic techniques such as FTIR spectrometry makes it possible to undertake occupational RCS measurements in workplaces. Such measurements are, however, prone to interferences from other minerals co-sampled onto air filter samples. In a comparative testing53 of FTIR and XRD methodologies using 253 air filter samples from representative activities such as road construction and tunnelling, coal mining and kitchen benchtop manufacturing, the FTIR results were on average 9% higher than the XRD data. This discrepancy was largely attributed to spectral interferences around the 800 cm−1 region where characteristic Si–O stretches are measured. The authors recommended that, to obtain better FTIR data, spectra should be examined for potential matrix interferences, a peak height ratio method should be used for quantification and filters should not be overloaded. In order to minimise such interferences, a PCR chemometric model was developed54 using coal dust mixtures on filter samples and verified by comparison with the results from XRD analyses. This model allowed quartz to be measured in several coal dust types with a LOD of 5 μg per filter and met the method performance requirements set out in ISO 20581 if airborne silica concentrations of 100 μg m−3 were to be sampled using a nominal 500 L sample volume. Further work will examine the wider applicability of chemometric models for predicting quartz contents in other workplace dusts and whether such models can be used universally with different portable FTIR instruments. In a Raman-based method, test RCS aerosols were sampled55 onto a small 1.5 mm filter spot and analysed either with a hand-held instrument (ca. 0.5 kg) or a larger probe-based portable unit (ca. 5 kg). The best LOQ of 17 μg m−3 was attained for a nominal 24 L air sample collected at a flow rate of 0.4 L min−1 over 60 min using the handheld instrument. Results were within 23% of those obtained using a reference XRD method. Future studies will assess instrumental performance on real-world RCS samples.

3 Water analysis

3.1 Reviews

A review56 (210 references) on the determination of phosphorus and its species in environmental samples highlighted the use of DGT samplers for in situ sampling of water and pore water in soils and sediments and the use of ETAAS, ICP-MS, ICP-AES for subsequent analysis.

A review (291 references) on the characterisation of nanomaterials in the environment covered,57 amongst other topics, the preconcentration of nanomaterials from aqueous samples, their quantification by sp-ICP-MS and XRFS and their characterisation by techniques such as FFF-ICP-MS and LA-ICP-MS. A more specific review (74 references) on the trends and challenges in determining engineered NPs in seawater drew58 the reader’s attention to the important fact that the main limitation of many studies is the use of spiked samples at concentrations much higher than those found in real samples. Of note was the table on atomic spectrometric methods used and the sample preparation procedures required prior to analysis.

3.2 Sample preconcentration

Two useful reviews on analytical sample preparation were published. The first (157 references) focussed59 on the use of MOFs (a type of coordination polymer with an inorganic metal centre surrounded by organic ligands) as specific adsorbents for trace elements in environmental and food matrices. The second review (146 references) covered60 sample preservation, storage and extraction techniques for the elemental speciation analysis of environmental samples.

An electrodialytic enrichment device for the preconcentration of trace ions from ultrapure water before analysis by ICP-MS generated61 an effluent with a tenfold trace element enrichment. As part of the procedure, the effluent was acidified with HNO3, thereby making QC easier. The “waste” water that had been stripped of trace elements was recycled to make the analytical blanks and standards.

Tables 4 and 5 present the most significant advances in analyte preconcentration using SPE or LPE for water analysis.

Table 4 Preconcentration methods using solid-phase extraction for the analysis of water
Analytes Matrix Substrate Coating or modifier Detector Method LOD in μg L.1 (unless stated otherwise) Validation Reference
Ag, Cd, Pd, Re, Zn Fresh water and seawater AmberChrom® 1-X8 resin ICP-MS/MS 0.11 (Re) to 19 (Zn) ng L−1 NRCC CRMs SLRS-6 (river water), CASS-6 (near shore seawater) and NASS 7 (seawater) 314
Am, Pu, Sr, U Lake water, seawater, urine DGA branched resin and Sr resin both 50–100 μm N,N,N′,N′-Tetra-2-ethylhexyldiglycolamide (DGA resin) and 4,4′(5′)-di-t-butylcyclohexano 18-crown-6 in 1-octanol (Sr resin) ICP-MS/MS 0.56 (239Pu) to 1.75 (90Sr) pg L−1 Spike recovery and IAEA proficiency scheme water samples 315
AsV Water SAX disk filter Quaternary ammonium groups LA-ICP-MS 0.028 Spike recovery 316
AsIII, AsV, DMA, AB Water, seawater, and urine Graphene oxide Fe2O3 and [1,5-bis(2-pyridyl)-3-sulfophenylmethylene] thiocarbonohydrazide (from a previous paper) HPLC-ICP-MS 0.2 (AsV) to 3.8 (AB) ng L−1 NRCC CRMs TMDA 64.3 (fortified lake water) and CASS 6 (near shore seawater) 317
As Water and seawater Gold NPs (at 350 °C) HG-AAS 6.5 pg mL−1 NRCC CRMs AQUA-1 (drinking water), NASS-5 (seawater) and IRMM CRM ERM-CA713 (wastewater) 318
As, Bi, Sb Fresh, sea, waste and ground waters Cellulose fibres Trapping of hydrides on Ag NPs ICP-MS 1 (Bi) to 15 (As) ng L−1 Spike recovery 319
Bi, Cr, Pb, Zn Water Fe3O4 NPs coated with SiO2 A ZrIV metal–organic framework with tetrakis(4-carboxyphenyl)-porphyrin (MPCN-224) ICP-MS 0.9 (Bi) to 11.4 (Zn) ng L−1 Chinese Ministry of Environmental Protection CRMs GSB 07-3186-2014 (200934) (water quality standard) and BY400143 (B2003113) (environmental water) 320
Cd Tap, mineral and lake waters, and physiological solution A ZrIV metal–organic framework with terephthalic acid (UiO-66) FAAS with Ni furnace in the flame 0.03 Spike recovery 321
Cd, Co, Cr, Cu, Fe, Mn, Ni, Pb Wastewater Silica gel V2O5 FAAS 8.4 (Cd) to 50.6 (Cu) Spike recovery 322
Cd, Co, Ni Waste, sea, tap and reservoir waters A thiol-functionalised covalent organic framework of 1,3,5-triformylphloroglucinol (Tp) and 2,5-divinyl-p-phenylenediamine ICP-MS 0.1 (Cd) to 1.46 (Co) Beijing Weiye Research Institute of Metrology and Technology CRM GBW08608 (metal elements in water) and spike recovery 323
Cd, Cu, Ni Eye drops, serum and tap, mineral and spring waters Silica gel N-N′-Bis(5-methoxsalicylidene)-2-hydroxy-1,3-propanediamine ICP-AES 28 (Cd) to 62 (Cu) ng L−1 Spike recovery and a multi-elemental ICP grade standard as an unknown 324
Cd, Cu, Pb Sea and stream waters, pepper, black cabbage, eggplant, tomato Melon peel biochar CoFe2O4 FAAS 0.41 (Cu) to 3.16 (Pb) Spike recovery 325
Cd, Pb, Te, and Sb Drinking water (3-Aminopropyl)triethoxysilane (multi-ion imprinted polymer) APDC ICP-AES 0.037 (Sb) to 0.93 (Te) Spike recovery and comparison with ICP-MS reference method results 326
CrIII, CrVI Spring water and sewage wastewater Chelate resin (Lewatit TP207) and anion exchange resin (Lewatit MP68) LIBS 88 (CrIII) to 270 (CrVI) Spike recovery and comparison with ICP-AES results 327
CrIII Tap water and green tea Styrene and 4-vinylpyridine ion imprinted polymers 1,10-Phenanthroline ETAAS 0.35 ng mL−1 Spike recovery and NIST SRM 1643e (trace elements in water) 328
Cr, Cu, Ni, Pb Aqueous solutions, bottled water Glass GO LIBS 14 (Pb) to 15 (other analytes) Spike recovery 329
135Cs, 137Cs Seawater Ammonium molybdophosphate adsorption ICP-MS/MS 15 fg L−1 IAEA CRM IAEA-443 (Irish seawater) and comparison with TIMS analysis 330
Cu Water Activated carbon Ion-imprinted polymer with N-methoxymethyl melamine and ethylenedinitrilotetraacetic acid, disodium salt FAAS 0.038 NIST SRM 1643e (trace elements in water) and ERML-CA021e (soft drinking water) 331
Hg Water Carbon fibre (3-Mercaptopropyl)trimethoxysilane ICP-MS 2 ng L−1 Spike recovery 332
Hg, MeHg, EtHg, PhHg Lake water and fish Fe3O4 NPs Polymer of 2,4,6-triformylphloroglucinol and methacrylic anhydride modified with 1,2-ethanedithiol HPLC-ICP-MS 0.43 (Hg) to 1.1 (PhHg) ng L−1 Spike recovery and NRCC CRM DORM-2 (dog fish) 333
Hg, MeHg Lake and ground waters Ultrasint® PA11 or PA12 3D printer powder 3-Mercaptopropyl-functionalized silica gel ICP-MS 0.02 (MeHg) and 0.08 (Hg) ng L−1 IRMM CRM ERM CA615 (ground water) 334
In Drinking water Silica gel Covalently immobilised azolium groups ETAAS 5.5 ng L−1 Spike recovery 335
MnII, MnVI Tap water, ice tea, an energy drink, mineral water, Sprite ZnFe2O4 nanotubes (selective adsorption MnVII) 1-Phenyl-3-methyl-4-benzoyl-5-pyrazone and 1-undecanol (SFOD selective extraction of MnII) ETAAS 0.005 (MnII) and 0.007 (MnVII) Chinese RM GSBZ 50019-90 (Fe and Mn water quality standard) and spike recovery 336
εNd (143Nd/144Nd) Seawater Fe hydroxide coprecipitation DGA Resin® MC-ICP-MS No LOD reported. The blank was 2 pg from 3 L of sample Comparison with TIMS results 337
Pb River water Calcium alginate beads FAAS 2 Spike recovery and comparison with ICP-MS results 338
Pd Estuarine water Presep® PolyChelate chelating resin ICP-MS 0.010 ng kg−1 Spike recovery 339
Pd Seawater Biorad AG® 1-X8 anion exchange resin ICP-MS 0.060 pmol L−1 Spike recovery 340
226Ra (system also evaluated for Cd, Co, Cu, Pb, U and Zn) Fresh, sea and fracking waters Biorad AG® 50 W-X8 cation exchange resin, Nobias Chelate-PA1 and Eichrom Sr spec resin in series on a lab on a valve ICP-MS/MS 4.3 ± 0.1 mBq L−1 (1.75 fg L−1) Spike recovery and NRCC CRM CASS 6 (near shore seawater) 341
REEs Water and atmospheric particulate extracts and digests SiO2 coated Fe3O4 NPs Phytic acid ICP-MS 0.002 (Lu) to 1.1 (Nd) ng L−1 Spike recovery 342
TlI and TlIII Tap, spring, river, sea and bottled waters Graphene–Fe3O4 composite Aliquat 336 ETAAS 0.01 NIST SRM 1640a (trace elements in natural water), Environment Canada CRMs TMRain-04 (simulated rainwater), TM-23.4 (fortified lake water), TM-25.4 (low level fortified lake water) and SPS RM SW2 (surface water) 343


Table 5 Preconcentration methods using liquid-phase extraction for the analysis of water
Analytes Matrix Method Reagents Detector LOD in μg L−1 (unless stated otherwise) Method validation Reference
AgI Water and soil CPE Citric acid and Triton™ X-100 FAAS 0.04 Spike recovery and comparison with spectrophotometry data 344
Ag2S NPs Water CPE Bis(p-sulfonatophenyl)phenylphosphane dehydrate dipotassium salt, Na2S2O3, Triton™ X-114 and glycerol sp-ICP-MS Size LOD 22 nm, particle number LOD 5 × 104 particles per L Spike recovery 345
Al Tap and river waters, rock, soil CPE 3,4,5-Trihydroxybenzoic acid, Triton™ X-114 and back extraction into HNO3 ICP-AES 0.31 Spike recovery and NIST SRM 1643f (trace elements in water) 346
Be Seawater, air filters DLLME Dioctylsulfosuccinate, acetylacetone and chloroform ETAAS 10 fg mL−1 Spike recovery and NIST SRMs 1640 and 1640a (trace elements in natural water) 347
Cd Drinking, tap and ground waters CPE Pyridyl-azo-naphthol and Triton™ X-114 HR-CS-ETAAS 1.3 Spike recovery 348
Cd, Fe, Pb Drinking water CPE 2,6-Diamino-4-phenyl-1,3,5-triazine and 3-amino-7-dimethylamino-2-methylphenazine, and Triton™ X-114 FAAS 5 (Pb) to 25 (Fe) Spike recovery 349
Co, Cu, Ni Water, blood, urine CPE (E)-2-(2,4-Dihydroxybenzylidene)-N-phenylhydrazine-1-carbothioamide (DHBPHC) and Triton™ X-114 FAAS 0.34 (Co) to 0.94 (Ni) Spike recovery 350
CrVI Natural and waste waters Deep eutectic solvent microextraction Hexanoic acid and tetrabutylammonium bromide ETAAS 5 ng L−1 Spike recovery 351
FeIII Water, food DLLME 4,5-Dihydroxy-1,3-benzendisulfonic acid, 1-hexadecyl-3-methylimidazolium bromide, back extract in decanoic acid in tetrahydrofuran FAAS 1.0 Spike recovery 352
Pd Water CPE 2-(5-Bromo-4-methyl-2-pyridylazo)-5-dimethylaminoaniline and Triton™ X-114 ETAAS 0.05 Spike recovery 353
REEs Ground water, mining water run off DLLME 2-(5-Bromo-2-pyridylazo)-5-(diethylamino)-phenol, ethanol and a 1[thin space (1/6-em)]:[thin space (1/6-em)]1 mix of carbon tetrachloride and trichlorethylene EDXRFS 1.1 (U) to 10.5 (Eu) Spike recovery 354
SeIV Tap, river and well waters, food LLME (3,4-Dihydroxyphenyl)-3,5,7-trihydroxychromen-4-one (quercetin), menthol and lauric acid HG-AAS 0.25 ng L−1 Spike recovery (water samples) and NIST SRMs 1567a (wheat flour) and 1548a (typical diet) 355
Zn Tap water DLLME Dithiazone, choline chloride and dodecanol FAAS 0.09 Spike recovery 356


3.3 Speciation analysis

A review (60 references) on the determination of SeIV by CVG coupled with AFS detection covered62 all the main chemical strategies for reducing SeVI to SeIV together with species-specific preconcentration methods. This paper demonstrates that there are now a sufficient number of analytical methods for this application.

An investigation on the preservation of As species in water established63 that the bottle type had little effect on species stability and that acidification of the samples to 0.018 M HCl or 0.019 M HNO3 was sufficient to preserve the original sample composition for up to 12 weeks. The use of HNO3 was preferred over that of HCl in order to avoid polyatomic interferences when using ICP-MS. It was suggested that HNO3 had no oxidising effect but this assertion was unfortunately not tested on real samples. It should be noted that chromatographic separations typically separate chloride from As species and that most ICP-MS instruments these days have collision cells that successfully remove the ArCl+ interference so HCl can in fact be used without the risk of species oxidation by HNO3. A different approach was adopted64 for groundwater samples with significant concentrations of iron sulfide and oxide minerals. To overcome the problem of a >60% reduction in AsIII concentrations that occurred after 36 h of collection, samples were preconcentrated on-site onto strong cation- and anion-exchange cartridges. Recoveries of As species were quantitative when the Fe2+ concentrations were <10 mg L−1.

Species-selective preconcentration can be used to improve the sensitivity of speciation methods. Turbulent flow chromatography is a commercial and patented SPE method typically used in clinical analysis to separate low- and high-molecular-weight fractions by diffusion-controlled mass transfer instead of by chemical interaction with a stationary phase. It was tested65 for the preconcentration and fractionation of Gd in surface waters. All low-molecular-weight compounds were retained at loading flow rates above 1 mL min−1 whereas compounds of 5.7 kDa and above were not. The recovery of low-molecular-weight Gd species from the samples (92 ± 5%) was a slight improvement over the 87 ± 4% achievable using standard cation-exchange SPE preconcentration cartridges. The mercury species Hg2+, MeHg+ and EtHg+ were selectively extracted66 offline from sea, lake and river waters onto a C18 column functionalised with 12.5 μg of dithizone. Once extracted, the immobilised species were stable for up to 10 days. The column was then mounted onto the HPLC injection valve for elution and HPLC-ICP-MS detection. The LODs for 50 mL samples ranged from 0.007 (EtHg+) to 0.02 (Hg2+) ng L−1.

The fractionation of trace elements in waters and soil porewaters remains an important topic. An investigation into the environmental bioavailability of Co, Fe, Pb, U and Zn at a mine reclamation site used67 DGT to sample extractable metals from soils and ICP-MS pore-water analysis to estimate their lability and biotoxicity. Although the metals were highly labile and so potentially had high toxicity, analysis of tree core samples, surprisingly, revealed little uptake into the xylem of nearby trees. Dissolved AsIII, SbIII, and SeIV concentrations within a river catchment were successfully mapped68 using a DGT sampler loaded with aminopropyl and mercaptopropyl bi-functionalised mesoporous silica spheres. The time-weighted average data obtained were comparable to data from high frequency sampling and HPLC-ICP-MS analysis. The spatial resolution that can be obtained with these samplers was exploited to follow redox-constrained spatial-patterns of these analytes associated with root penetration. Results obtained using passive DGT sampling and ICP-MS detection for the labile forms of Cd, Ni and Pb in transitional and coastal waters were compared69 with those obtained by standard ASV analysis. Although the concentrations of labile Cd and Pb obtained by the two methods were highly correlated, the values obtained for Pb by ASV were always similar to or lower than the results obtained by DGT-ICP-MS. As ASV cannot be used to determine the labile fraction of Ni due to the irreversible reduction of Ni at the electrode, this new method had a considerable advantage for the analysis of estuarine waters.

3.3.1 Instrumental speciation. A review (103 references) of FFF-ICP-MS for the determination of engineered NPs in the environment covered38 the separation theory of FFF and application to the determination of engineered NPs in wastewaters, environmental waters, soils and organisms.

Although the combination of HPLC with ICP-MS for elemental speciation is facilitated by the ease of interfacing these two instruments, HPLC mobile phases containing large amounts of organic solvents are often incompatible with ICP-MS. To overcome the problems of high reflected power and carbon deposition on the interface, dimethyl carbonate was used70 as an organic-mobile-phase modifier for the RP chromatography of a series of Br-, Cl- or S-containing organic compounds in urine. A 10% v/v concentration of dimethyl carbonate had an elution capacity equivalent to 23 and 48% v/v concentrations of acetonitrile and methanol, respectively, but didn’t require the addition of oxygen to the plasma. Use of this mobile phase might also have potential for water samples but it is less miscible with water so the maximum usable concentration of dimethyl carbonate in a mobile phase is 10% v/v.

As ICP-MS is a multi-elemental detector, it is always gratifying to see the development of multi-elemental separations. The species CdII, CrIII, CrVI, HgII, MeHg+, EtHg+, PbII, TEL and TML were preconcentrated71 on a C18 SPE column modified with 10 mM 2-hydroxyethanethiol and then eluted with 5 mM cysteine onto a C18 HPLC column from which separation of all the analytes was achieved in 8 min using the eluent as the mobile phase. The LODs ranged from 0.001 (MeHg+) to 0.007 (TML) ng L−1. Accuracy was verified by spike recoveries from real samples and by analysis of the Chinese RMs GBW08602 (Cd in water), GBW08603 (Hg in water) and GBW08601 (Pb in water). The separation and quantification of 5 Gd MRI contrast agents by IC-ICP-MS used72 the PrepFast sample introduction system fitted with a proprietary polymer-based IC column functionalised with quaternary ammonium alkyl groups. Complete separation in less than 2 min was achieved with a gradient of ammonium nitrate buffers at pH 9.2. The LODs of 11 (gadoterate) to 19 (gadobenate) pM were sufficient for the monitoring of these compounds in a river in Germany.

The ReVII and ReIV species have similar physicochemical properties and electrophoretic behaviour to 99Tc and so were determined73 by CE-ICP-MS/MS in simulated contaminated groundwater samples as stable analogues of 99Tc. The CE-ICP-MS interface added a sheath liquid to the CE flow to increase the flow rate for ICP-MS analysis. The LODs were 0.01 (ReVII) and 0.02 (total Re) μg L−1. The authors considered this method to be a promising candidate method for monitoring 99Tc species in contaminated groundwater.

3.4 Instrumental analysis

3.4.1 Atomic absorption spectrometry. A review (154 references) of simultaneous or sequential multi-elemental AAS analysis over the last 20 years included34 relatively few examples of water analysis but was still a useful summary of the state-of-the-art. The determination of Cd, Mn and Zn in gas-field-strata waters by sequential FAAS was improved74 through a sequence of steps involving evaporation and redissolution under sonification with HNO3, Triton™ X-100 and acetyl acetone. The LODs were 4 (Mn and Zn) and 7 (Cd) μg L−1. The method was validated by spike recoveries and ICP-AES analysis of the same samples. Undiluted seawater was successfully analysed75 for Cu and Mn by HR-CS-ETAAS, use of which allowed more accurate background correction to be made than possible with low-resolution line source instruments. When optimised pyrolysis and atomisation temperatures were used, the LODs were 0.07 (Mn) and 0.6 (Cu) μg L−1 for a 20 μL sample injection. The method was validated by spike recoveries.

The determination of AsIII by FAAS with a quartz tube atomiser was improved76 by using a Pt-coated tungsten coil heated at 60 °C to trap arsine gas after HG. The LOD of 0.016 μg L−1 was a considerable improvement over that (0.26 μg L−1) achievable without the coil. Results for the NIST SRM 1640a (trace elements in natural water) and the SCP science RM EnviroMAT (drinking water high) were not significantly different from the certified values at the 95% confidence level.

3.4.2 Atomic fluorescence spectrometry. The quantification of mercury and its species remains one of the main applications of AFS. Dissolved elemental, reactive and total Hg fractions were determined77 in seawater using an on-ship FI dual-channel purge-and-trap CV-AFS system. The method was validated using the IRMM CRM BCR-579 (coastal seawater). The LOD was 0.05 ng L−1. A commercially available instrument designed specifically to automate the laborious US EPA method 1630 (methyl mercury in water by distillation, aqueous ethylation, purge and trap and cold vapour atomic fluorescence spectrometry) was investigated78 for the determination of MeHg in seawater. The Hg2+ and MeHg+ species were ethylated using tetraethyl borate, trapped on Tenax® and determined by GC-AFS. Automation of the method meant that up to 72 samples per day could be analysed and gave an LOD of 0.0004 ng kg−1 (as Hg). The method was validated by gravimetric spiking, participation in the GeoTraces laboratory intercomparison exercises and analysis of IRMM CRM BCR-579 (coastal seawater).
3.4.3 Vapour generation. Photochemical vapour generation is the most common methodology reported in the literature for producing volatile metal compounds from water samples. The main advances in the technique are summarised in Table 6.
Table 6 Methods for photochemical vapour generation in the analysis of water
Analyte Matrix Vapour generation reagents Detector LOD Validation Reference
As Lake and river waters, sediments Acetic acid, formic acid and Fe3O4 NPs, 60 s irradiation time ICP-MS 0.01 μg L−1 Spike recovery (water) and against Chinese CRMs GBW07303 and GBW07305 (both stream sediment) 357
Bi Drinking and tap waters Fe3O4 NPs as a SPE adsorbent and photocatalyst, acetic acid and formic acid. Online photochemical reactor AFS 0.07 μg L−1 Spike recovery 358
Br, BrO3 Water Cu2+ catalyst and acetic acid. Flow through UV reactor with a 14 s irradiation time ICP-MS 0.01 μg L−1 No validation, proof of concept on artificial samples 359
Br, Cl Bottled and sea waters Copper acetate, 58 s irradiation time SF-ICP-MS 0.03 (Br) and 3 (Cl) μg L−1 Spike recovery 360
Hg Water Ivy root extract in ethanol, 30 s irradiation time AFS 0.03 μg L−1 Spike recovery 361
Ru Well, spring, contaminated and sea waters Cd and Co catalyst with formic acid, 31 s irradiation time ICP-MS 20 pg L−1 Spike recovery 362
Ru, Os Water Cd and Co photocatalyst and formic acid, 45 s irradiation time ICP-MS 0.5 (Os) and 5 (Ru) ng L−1 Spike recovery 363
SeIV, SeVI Mineral and river waters Cd ion photocatalysis and acetic acid, irradiation time not directly reported HPLC-AFS 0.16 (SeIV) and 0.21 (SeVI) μg L−1 Spike recovery and analysis of Chinese RMs GBW(E)080395 (Se in simulated water) and BWB2261-2016 (water quality Se standard) 364


Microplasmas or discharges can also be used to produce volatile metal compounds. An anodic GD was developed79 for the CVG of Cd and Hg in waters and sediment digests prior to ICP-AES detection. The LODs of 0.3 (Cd) and 0.2 (Hg) μg L−1were improvements over those achievable with pneumatic nebulisation. The VG efficiencies were 28 and 69% for Cd and Hg, respectively. Unfortunately, there was no comparison with “traditional” monoelemental CV or HG methods. A nebulised-film DBD was successfully employed80 to vaporise 2,2,6,6-tetramethyl-3,5-heptanedione chelates of REEs prior to ICP-MS detection. The sample introduction efficiency of 51–66% gave an 8–9 fold sensitivity improvement over that achievable by nebulisation. The LODs ranged from 0.002 (Gd and Tb) to 0.328 (Y) ng L−1. The accuracy of the method was checked by spike recoveries from lake and rainwaters as well as by analysis of the Chinese RM (GBW(E)082428) (multielement solution).

The inorganic, monomethyl and dimethyl Ge species in fresh and seawater samples were determined81 following production of volatile species by hydride generation. The species were preconcentrated by cryotrapping and then selectively released by gradual heating of the trap. The LODs of 0.003 (DMGe) to 0.015 (iGe) ng L−1 achievable with ICP-MS/MS detection were low enough to provide values for these species in the NRCC CRMs CASS-4 to 6 (near shore seawater), NASS 5 and 7 (seawater) and SLRS 4 to 6 (river water). The values obtained were consistent with values previously reported for total Ge in these CRMs. The concentration of Pb in water was determined82 by HG-MIP-AES using K3Fe(CN)6 as an additive to improve the generation of PbH4 with NaBH4. The LOD of 0.54 μg L−1 allowed the accurate determination of Pb in the Laboratorio Tecnólogico del Uruguay CRM MRC.INO.101 (trace elements in water).

3.4.4 Inductively coupled plasma atomic emission spectrometry. When analysing water samples with high concentrations of solutes, ICP-AES remains a relevant analytical technique. The determination of I in oilfield brine samples was facilitated83 (paper in the Chinese language) by oxidation of iodide to I2(g) with a mix of NaNO2 and HNO3 and isolation of the vapour using a gas liquid separator. The LOD was 1.65 μg L−1. Method validation was by spike recoveries from real samples. Only Ca had any appreciable matrix effect. The determination of Li in geothermal waters demonstrated84 (paper in the Chinese language) the robustness of ICP-AES analysis. Careful matrix matching allowed the determination of Li in undiluted samples with an LOD of 0.2 μg L−1. The results compared well with those obtained by ICP-MS analysis of diluted samples. When Antarctic snow samples were preconcentrated85 by freeze drying from 20 g to a final volume of 200 μL, the resulting samples had appreciable solute contents. The determination of Al, Ba, Ca, Fe, K, Mg, Na and Sr in these small-volume samples was only possible with a low-uptake total-consumption nebulisation device. The LODs obtained at a sample uptake of 50 μL min−1, ranged from 0.003 (Sr) to 0.39 (Na) μg L−1 and were sufficient to determine these elements in snow from the Antarctic Plateau. The method was validated by analysis of NIST SRM 1640a (trace elements in natural water).
3.4.5 Inductively coupled plasma mass spectrometry. A tutorial review (109 references) on the use of aerosol dilution with ICP-MS covered86 the use of this simple sample “preparation” method for various applications including those in food, environmental, biological and clinical studies.

The optimum sample dilution of 1 + 9 for the determination of REEs in seawater samples by SF-ICP-MS was determined87 from analyses of the NRCC CRM CASS-6 (near shore seawater). Although this method was suitable for the analysis of near-shore samples, the analysis of oceanic samples presented problems. It is suggested that these could be overcome by the use of high-efficiency heated nebulisers with aerosol desolvation. The interference effects of Ba polyatomic ions on the determination of Eu were evaluated88 by “Pseudo ID”. Polyatomic ions were treated as surrogates for Eu ions and their contribution quantified by spiking the sample with natural abundance Eu. The LOD was 0.007 pg mL−1. The method was validated by the analysis of NRCC CRMs CASS-4 and 5 (near shore seawater), NASS-5 and 6 (seawater) and SLRS 4 and 5 (river water) for which literature and information values for Eu were used.

The determination of S in lacustrine DOM by ICP-MS/MS was achieved89 by measurement of 32S16O+ formed in the collision cell after removal of 48Ca+ in the first quadrupole. The LOD was 0.2 ng g−1 in dried DOM. Results agreed well both with those obtained previously using FT-ICR-MS and with reference values for the IHSS RM Suwannee River fulvic acid. The same method was employed90 for the determination of δ34S in coastal seawaters and sediment pore waters. Results that were not significantly different to the certified values were obtained for the analysis of IAES RMs IAEA-S-1 (sulfur isotopes in silver sulfide), IAEA-S-2 (sulfur isotopes in silver sulfide) and the IAPSO CRM (seawater) but the precision of 1.1–1.5‰ was an order of magnitude poorer than that obtained using a MC instrument.

Seventeen water CRMs from NRCC and IRMM were analysed91 for REEs and technology-critical elements by ICP-MS/MS. The MS instrument was used in combination with a commercial preconcentration-unit fitted with Nobias chelate-PA1® columns. The REEs, Sc, Ti and Y were measured in O2 mass-shift-mode and Al, Cd, Co, Cu, Fe, Ga, In, Mn, Mo, Ni, Pb, Sn, Th, U, V, W and Zn in He-collision mode. Apart from the values obtained for Mo, Ni and U in three of the 17 CRMs analysed, the results were not significantly different from the certified values. There had been no or few results presented previously in the literature for Ga, In, Sc, Sn, Th, Ti and W in these CRMs so this paper provided the first published values for most of these elements. These new data were combined with data from an extensive literature survey to provide new consensus values for those elements without certified values.

In the ICP-MS/MS determination of radioisotopes using a commercial high-efficiency desolvating nebuliser, the 97Mo isobaric interference on 97Tc was eliminated92 by adding O2 as a reaction gas to form MoO+ and MoO2+. Using 97Tc as a yield tracer for 99Tc, the absolute LOD was 0.9 fg (0.6 mBq). In a similar procedure, the 129Xe+ isobaric interference on 129I+ decreased93 substantially when I was reacted with O2 and measured as 129I16O+ at m/z 145. In this way a LOD of 11 mBq L−1 was achieved without the need for any sample pretreatment. The method was validated by spike recoveries from river and synthetic water samples and IDA.

A 304-reference review of sp-ICP-MS covered39 all aspects from basic principles and sample preparation to analytical applications, such as the detection of NPs in various kinds of waters. Although 0.45 μm filters are often used in the preparation of samples for sp-ICP-MS, it was reported94 that the NP affinity for filter materials differed according to the filters used. Best recoveries of NPs (>75%) were obtained when polypropylene membranes were used. Preconditioning of the filters with a multi-element solution improved recoveries by up to 80% but recoveries were dramatically dependent on the water matrix. The authors concluded that to decrease losses either their filtration protocol or centrifugation of samples at <1000g should be used before analysis of water samples. This finding was partially supported95 by a study on the determination of metallic NPs in waste waters and sludges produced at water treatment plants. Samples were centrifuged at 5000g or less for 10 min before sp-ICP-MS analysis. Recoveries of silver NPs from spiked samples were >84%. Particle mass concentrations of <1 ng L−1 for cadmium NPs and ca. 100 μg L−1 for magnesium NPs were found in samples of waste waters and sludges. Most particles were <100 nm in diameter but magnesium particles could be much larger at up to 1500 nm in diameter.

Notably different approaches have been taken for the determination of non-metallic NPs. A review (44 references) of the use of metal tagging or labelling considered96 this strategy to have the advantage of making the most of the detection power of ICP-MS whereas C monitoring was beset with many difficulties. The advantages and disadvantages of different kinds of tagging for polystyrene microplastic standards were discussed. In contrast, microplastics and unicellular algae have been counted and sized97 in seawaters by ICP-MS/MS by monitoring 12C and 13C. Online aerosol dilution was used to reduce drift effects and to make size calibration more repeatable. The best size-LODs were obtained using 12C. Size calibration using polystyrene microplastic standards made it possible to calibrate cellular masses in real samples. The measured results of 51–83 pg (equivalent to sizes of 7.6 to 10 μm) were consistent with results obtained using Coulter counting, TOC analysis and microscopy.

A review (151 references) of the determination of 137Cs and226Ra by ICP-MS covered98 sample preparation, pretreatment and separation steps for a wide range of matrices, including soils, sediments and biological materials as well as several waters.

The quantification of radionuclides in water by ICP-MS is of increasing interest. The low instrument LODs of 0.02 (Pb) to 0.14 (U) ng L−1 made99 it possible to determine stable Pb isotopes, 232Th, 234U, 235U and 238U in drinking water by SF-ICP-MS without any sample pretreatment. In contrast, the detection of 227Ac in fresh and seawaters was only possible100 following preconcentration from 30 L of sample using manganese coprecipitation and extensive column purification. As the yield was known to be <100%, ID was used for quantification by MC-ICP-MS. The method was validated against an in-house RM and spiked seawater samples and internal QC was carried out using duplicate riverwater samples. The absolute LOD of 10 ag was sufficient for monitoring this radioisotope in seawater and could result in a rapid increase in the use of 227Ac as a marine tracer. An automated SPE column method with UTEVA® resin was used101 to extract Th (230Th, 232Th) and U (234U, 235U, 238U) from 20 mL of sea and river waters prior to elution with 0.01 M HNO3–0.01 M HF and quantification by ICP-MS/MS. Results were not significantly different from the certificate values for the NRCC CRMs CASS-6 (near shore seawater), NASS-7 (seawater) and SLRS-6 (river water) and the IAEA CRM IAEA-443 (Irish Sea water). The LODs ranged from 0.02 (230Th) to 5.89 (235U) fg mL−1.

A review (149 references) of the use of “non-traditional” stable isotope ratios in studies of the geochemical and ecotoxicological aspects of marine metal contamination included102 the application of MC-ICP-MS to studies of contaminated marine environments. It was concluded that measurement of isotope ratios will detect changes caused by mankind and follow interactions with marine biota.

A collaborative study by two expert laboratories used various ICP-MS instruments (including SF- and MC-) to determine the trace element mass fractions and isotope ratios in the NRCC CRM AQUA-1 (drinking water) standard. The article provided for the first time103 consensus or indicative values for the mass fractions of B, Cs, Ga, Ge, Hf, Li, Nb, P, Rb, Rh, Re, S, Sc, Se, Si, Sn, Th, Ti, Tl, W, Y, Zr and the REEs. In addition, six isotopic ratios were proposed for Pb and Sr. The NRCC CRM SLRS-6 (river water) was used as a control standard.

Sample preparation for isotope ratio analysis continues to receive attention. A single column method for isolating Ba from geological and water samples used104 a Bio-Rad AG® 50W-X8 200–400 mesh column. Barium was separated from the major interference elements in geological materials, river water and gas and oil brines using a double elution procedure with 2.5 M HCl followed by 2.0 M HNO3. The δ138Ba value was determined by MC-ICP-MS. Dissolved gaseous Hg and reactive Hg fractions were purged105 from 10 L batches of water samples after addition of acidic SnCl2. The Hg0 generated was captured on a Cl-impregnated activated-carbon-trap before thermal desorption and trapping in a 40% reverse aqua regia solution for determination of δ202Hg, Δ199Hg, and Δ200Hg by MC-ICP-MS.

The determination of236U/238U ratios in seawater and marine corals by MC-ICP-MS was improved106 by adding a secondary electron multiplier to the instrument. The detector was fitted with a retarding-potential quadrupole lens that reduced the size of the 238U tail signal on the 236U signal, so the abundance sensitivity of 238U at m/z 236 improved from 10−6 to 10−10. As a result, the sample mass required for successful analysis (0.7 μg U) was 60- to 100-fold lower than that required for ICP-MS or AMS procedures.

3.4.6 Laser induced breakdown spectroscopy. Several reviews on the application of LIBS to environmental monitoring were published. One (152 references) covered107 the period 2010–2019 and had a section dedicated to preparation and analysis of water samples. Another review (85 references) concentrated108 more on calibration strategies for those elements (N, P and some heavy metals) that can be detected directly in contaminated liquid samples such as wastewaters and landfill leachates. A more general review (201 references) noted109 the generally high LODs of LIBS and discussed how these might be improved for trace element detection in a large number of matrices, including environmental ones.

Research continued into methods for improving the sensitivity of LIBS. The determination of N concentrations in waters was achieved110 by detecting the molecular emission of CN radicals from a dried sample spot in an Ar atmosphere. The LOQ of 1.98 μg mL−1 was close to the Chinese upper permissible limit for avoiding water eutrophication. The results were not significantly different from those obtained using the standard method of alkaline potassium persulfate digestion followed by UV-VIS spectrophotometry. The quantification of Pb in dried water samples was enhanced111 by using resonant LA for interrogation of the target. Collection of fluorescence instead of atomic emission spectra provided a LOD of 2 μg L−1. Adding 13 nm gold NPs to a LIBS target improved112 the LIBS emission intensities for Cr, Cu and Pb in dried water samples by up to 26 times (Cr) and resulted in LODs of 5 (Cu) to 22 (Pb) μg L−1. In a similar vein, copper oxide NPs deposited on a PTFE target increased113 by a factor of 10 the emission intensities of Be and Cr from dried water samples and resulted in LODs of 5 and 33 μg L−1, respectively.

3.4.7 X-ray fluorescence spectrometry. The determination of 226Ra in water by TXRFS was made possible114 by calibrating with the NIST SRM 4967A (radium standard solution) and the MCNP6.2 Monte Carlo simulation code. When Ga was used as an IS, the LOD was 0.047 Bq L−1. Almost a litre of water had to be evaporated to dryness in order to overcome spectral interferences in real samples and so achieve the WHO drinking water upper limit of 1.0 Bq L−1 226Ra. Portable TXRFS could be used115 to detect Cr in waters down to concentrations of 0.13 μg L−1 when a 200 μL sample droplet was dried onto a hydrophobic-film sample holder.

4 Analysis of soils, plants and related materials

4.1 Review papers

A useful review (275 references) summarised116 and evaluated analytical methods for use in the emerging discipline of agrometallomics. Consideration was given to the determination, speciation and spatial mapping of elements in numerous types of materials of agricultural interest, not only soil and plants but also animal feed, seeds, fertilisers, pesticides, bacteria, fungi and NPs.

Nanoparticles were the topic of a comprehensive review (290 references) that covered57 advances in methods for determination of their abundance, morphology, composition and structure in water, soil, sediment and biological samples. Laser- and plasma-based approaches for NP characterisation were included117 in a broader review (596 references) that also covered monitoring of NP synthesis and the use of NPs for signal enhancement.

Element- or nuclide-specific reviews featured the measurement of total, inorganic and organic P in plant tissue (95 references)118; mapping and speciation of P in soil (105 references)119; speciation of As in traditional Chinese medicines, including medicinal plants (79 references);120 and determination of 129I concentrations and 129I/127I isotope ratios in environmental samples (96 references).121

Analytical methods for the determination of PTEs in plants were the topic of two reviews. The first (206 references) focused122 on medicinal plants and emphasised the need for more widespread QC to ensure the products sold are fit for consumption. The second (109 references) called123 for the development of standard methods of speciation analysis to increase reliability and comparability of results obtained by different laboratories.

4.2 Reference materials

Although new or improved isotopic data for CRMs or RMs are generally not certified, they can be valuable benchmarks for other researchers. Examples included:

δ7Li values in four soils and four sediments by MC-ICP-MS.124

δ30Si values in 13 soils and five sediments by MC-ICP-MS.125

δ30Si values in four soils and one plant (ERM CD281 (rye grass)) by MC-ICP-MS.126

δ44Ca/40Ca values in nine soils and five sediments by TIMS.127

δ88Sr/86Sr values in five soils and two sediments by MC-ICP-MS.128

δ87Rb values in two soils, one loess and two sediments by MC-ICP-MS.129

δ114Cd/110Cd values in one soil and 13 sediments by MC-ICP-MS.130

129I/127I ratios in six soils and 14 sediments by AMS.131

Re-analysis of a suite of environmental CRMs, including some soils and sediments, produced towards the end of the 20th century for the actinide elements gave27 results that agreed with literature or certified values but had lower uncertainties. The authors recommended that many of these CRMs should be re-certified using modern high-precision MS data.

4.3 Sample preparation

4.3.1 Sample dissolution and extraction. Studies on the minimisation of contamination during dissolution included132 one on cross-contamination between samples arising from the use of magnetic stir bars. Elements adsorbed on Teflon-coated stir bars during the MAD of soil samples were subsequently released during microwave-assisted cleaning cycles with HNO3 and H2O2 (30%). The elements Cr, Cu, Sb, Sn and Pb were detected at ppb levels in second, third and even fourth cycles. The authors suggested that microscopic cracks in the Teflon, observed with SEM/EDS, allowed penetration of elements below the Teflon surface, and they proposed the incorporation of additional bar-cleaning steps to avoid transfer of adsorbed PTEs to subsequent samples. A protocol designed to remove HF from samples following microwave digestion had133 the aim of preventing the introduction of impurities frequently observed with open-vessel HF evaporation. The ‘vessel-inside-vessel’ technique involved sample digestion (with HF and HNO3) in a small (5 mL) loosely-capped inner PFA vessel, after which HF was transferred from the inner vessel into the larger (70 mL) outer PTFE sealed vessel by means of two further microwave cycles at 500 W for 10 min. When ultra-pure water was the scavenger solution in the outer vessel, HF migration of up to 99.9% was achieved and so provided a safe closed-vessel contamination-free method of HF removal. An initial step involving soil wetting with 30% H2O2 at 50 °C on a hot plate prevented analyte loss from the loosely-capped inner vessel during sample digestion. The relative measurement errors ranged from −5 to +8% for all 27 elements determined in NIST SRM 2710 (siliceous soil).

Investigations into the use of strong acids for digestion134 included a comparison (in the Chinese language) of the efficiency of combinations of HF, HCl, H2O2, HNO3, and sample calcination for the digestion of soil standard materials IGGE GSS-1a to GSS-8a. Digestion efficiency was greatest when samples were initially calcinated at 550 °C and then digested with HF–HNO3. The use of H2SO4 and H2O2 for MAD followed by AAS was proposed135 as a safer and cheaper alternative to the use of HF and ICP-MS for the monitoring of trace elements in soils. Digestion (200 °C, 10 min) of 0.5 g Supelco CRM SQC001 (metals in soil) with 9 mL of H2SO4 and 3 mL H2O2, however, gave relative measurement errors for As, Cd, Co, Cr, Cu, Ni and Pb of −13% (Cd) to +13% (Cr). The fact that values for As, Co, Cr, Cu, Ni and Pb from nine soil samples were less than half of those obtained for digestion with HF + HClO4 further highlights that H2SO4 + H2O2 did not digest all soil types completely.

An example of an element-specific extraction was a method136 for the determination of As in the field. The optimised slurry sampling process involved addition of 0.4 mL HF + 4 mL HNO3 to 200 mg of soil, UA irradiation of the resultant mixture for 25 min, dilution with 6% HCl (v/v), addition of thiourea (40 g L−1) and further irradiation for 10 min to obtain a homogenised slurry. This was introduced into the HG-DBD trap-AES system using a coupling method described previously.137 The LOD was 0.18 mg kg−1. The results (n = 5) for the analysis of Chinese CRMs GBW 07430, 07447 and 07449 (soils) of 18 ± 2, 10.7 ± 0.5 and 8.7 ± 0.6 mg kg−1, respectively, agreed with the certified values of 20 ± 2, 10.3 ± 0.6 and 8.5 ± 0.8 mg kg−1, respectively. It is noteworthy that the entire procedure was carried out in the field even though the use of HF clearly imposed limitations on transportation and handling on site.

The occurrence of high concentrations of naturally occurring NPs is a major obstacle in the determination of engineered metal-NPs, as is the lack of RMs. Philippe et al.138 proposed colloidal extraction for the separation of anthropogenic TiO2 NPs from naturally occurring particles, of which only a small fraction was colloidal in size. Background correction with Nb as a proxy for natural TiO2 gave an ICP-MS LOD of ca. 10 μg g−1 TiO2. The recoveries from four different soil types spiked at between 200 and 600 μg g−1 were 29.1% (sand) to 86.7% (clayey soil) but could be improved by repeating the extraction. A sonication–sedimentation procedure with a sedimentation time of 6 h and a sediment[thin space (1/6-em)]:[thin space (1/6-em)]water ratio of 2[thin space (1/6-em)]:[thin space (1/6-em)]5 was proposed139 for the separation of Ti- and Zn-containing NPs from larger sediment particles in sediment, soil and road dust samples. For efficient separation in samples with TOC > 5%, sonication times had to be increased from 20 to 30 min and temperatures from 15–25 to 25–35 °C. Method efficiency was assessed by spiking the samples with silver and gold NPs. Recoveries were 44 to 68% and 54 to 83%, respectively. The magnetic properties of zero-valent Fe were exploited140 to separate the nanoscale engineered-particles widely used for soil and water decontamination from naturally occurring colloidal and dissolved Fe. Under optimised extraction conditions (2.5 mM tetrasodium pyrophosphate extractant, 30 min sonication), the LODs of the procedure based on UAE, magnetic separation and sp-ICP-MS were 43.1 nm and 50 μg g−1 for particle size and concentration, respectively. Six soil samples with OM contents of 7.0–64.6 g kg−1 were spiked with 50 or 100 nm-sized Fe NPs at concentrations of 50, 100 or 500 μg g−1. The recoveries were 62.0 ± 10.8% to 96.1 ± 4.8% for number of particles and 70.6 ± 12.0% to 119 ± 18% for mass of Fe. The authors noted that although the method had potential for general application, care should be taken with unknown samples which might have high background levels of magnetic Fe.

An extraction procedure for the separation of naturally occurring mercury NPs from soils was based141 on using tetrasodium pyrophosphate (10 mM) for the dispersion of soil particles and Na2S2O3 and 2,3-dimercaptopropanesulfonate sodium salt (0.5 mM) for the chelation of Hg. The procedure involved shaking (200 rpm, 70 min), sonication (40 kHz, 15 min), agitation and sedimentation (2 h). Quantification was by sp-ICP-MS. The authors considered the very significant and frequently overlooked effect of ageing when assessing the efficiency of the extraction protocol and found no statistically significant difference between the recoveries of Hg from spiked samples that had been stored for either 24 h or 30 days.

Extraction methods for radionuclides continued to be developed. In the analysis of contaminated soil from the Fukushima Daiichi nuclear-power-plant, the concentration of the extracting acid influenced142 the Cs isotope ratios determined by TIMS. Extraction with dilute (3 M) HNO3 resulted in a statistically significant 3‰ higher 135Cs/137Cs average isotope ratio than extraction with concentrated acid. Alkali fusion was proposed143 for sample dissolution in a procedure for the determination of Th and U. The optimised method utilised NaOH–Na2O2 fluxes in the fusion process, radiochemical separation of Th and U and analyses using ICP-MS and α-particle spectrometry. Relative measurement errors for U in five CRMs ranged from −39% for IAEA 385 (Irish Sea sediment) to −9% for IAEA 327 (soil from Moscow, Russia). The corresponding errors for Th ranged from −16% for IAEA-326 (soil from Kursk region, Russia) to −7% for IAEA-447 (soil from Hungary). Determination of 107Pd at low levels (<2 ng kg−1) was achieved144 through a multistep separation process involving Pd retention on a Ni resin and determination with ICP-MS/MS. The method was applied to sediment from the cooling pond at Chernobyl.

The bioaccessibility of As, Cd, Cr, Pb and Sb in NIST SRMs 2710 (Montana soil), 2710a (Montana I soil) and 2711 (Montana II soil) and in BGS 102 (Ironstone soil) was determined145,146 with the continuous online leaching method (COLM) already employed in food studies. The US EPA, United States Pharmacopeia, and UBM simulated gastrointestinal fluids were used for extraction. Although there were no statistically significant differences in results from the online and batch extraction procedures, the COLM procedure significantly decreased extraction times from up to 5 h to 5–15 min. An appealing option for bioaccessibility studies when using online leaching was the possibility of determining Pb isotope ratios, thereby providing additional information on contamination sources.

New methods for extraction from plants included147 MAE with dilute TMAH as a rapid method for the extraction of halogens. Under optimised extraction conditions (6 mL 100 mM TMAH, irradiation at 5 min and 240 °C) and ICP-MS analysis, there was no statistical difference between measured and certified concentrations for Br, Cl and I in NIST SRMs 1572 (citrus leaves) and 1547 (peach leaves). Two UAE procedures based on a HNO3–H2O2 mixture as the extractant were proposed as greener alternatives to extractions with concentrated acid. In an optimised method, Iftikhar et al.148 used both FAAS and ICP-AES to determine essential and non-essential nutrients extracted from carrot, cauliflower, pumpkin and spinach by 0.5 M HNO3–10% H2O2. Extraction efficiency was validated with NIST SRMs 1515 (apple leaves) and 1570a (spinach leaves) for which low relative measurement errors (<−5%) were obtained for all elements. In the method of Curti et al.,149 extraction with 7 M HNO3–30% H2O2 yielded relative measurement errors of −18% (Zn) to +10% (P) when applied to the Chinese RM NCSZC7310 (maize). Low LODs (0.04–0.12 ng g−1) were the attraction of a procedure150 for the determination of Se species in rice that was based on enzyme extraction, ion-pairing RP chromatography and ICP-MS/MS analysis. When protease XIV extraction was used, the sum of the extracted species SeIV, SeVI, SeCys2, SeMeCys and SeMet accounted for 93–109% of the total Se content of rice. Spike recoveries were 96–103% for all species except SeCys2 for which the recovery was 66–77%. Already well established in sample preconcentration procedures, NADESs are gaining popularity for metal extraction because of their non-toxic nature. The efficiencies of nine NADESs selected by predictive modelling were assessed151 for the extraction of Cu, Mn, Mo and Zn from barley grass. Optimum extraction efficiency was obtained when the water content of the solvents was >50%. The accuracy of the optimised method was tested using CRM ERM-CD281 (rye grass). The concentrations of Cu, Mn and Mo, as determined by ICP-MS, agreed with certified values but the Zn content was overestimated.

4.3.2 Analyte separation and preconcentration. Several reviews covered separation and preconcentration techniques. Methods for the extraction, preconcentration and analysis of a range of nanomaterials in natural waters, waste waters, soils and sediments and biological samples were critically reviewed (291 references) by Jiang et al.57 The review (146 references) of Viana et al.60 on extraction from waters, soils and sediments for metal speciation included techniques such as MAE, UAE, SPE, SPME and LPME. Jalili et al.152 reviewed (113 references) supramolecular solvent-based microextraction techniques, primarily for the analysis of waters but also for the analysis of soils. The mesoporous silica sorbents summarised153 in a review (113 references) included magnetic materials, materials functionalised with organic carbon and molecularly imprinted polymers. The selectivity and enrichment ability of sorbent materials such as carbon nanotubes, aerogels, covalent-organic frameworks and MOFs were considered154 in a review (152 references) in the Chinese language. The sample matrices covered in a review (157 references) by Gumus and Soylak59 on applications of MOFs included waters, waste waters, soils and sediments, plants, fish and industrial effluent. Carbon-nitride frameworks were reviewed by Kang et al.155 (132 references). The reviews of Andruch et al.156 (85 references) and of Herce-Sesa et al.157 (69 references), discussed DES in LLME procedures.

Numerous preconcentration procedures for specific analytes have been reported. 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 Tables 7 (LPE methods) and 8 (SPE methods).

Table 7 Preconcentration methods involving liquid-phase microextraction used in the analysis of soils, plants and related materials
Analyte(s) Matrix Method Reagent(s) Technique LOD (μg L−1, unless otherwise stated) Validation Reference
Ag Water, sand CPE 2,4-Dimethyl pentane-3-one, NaNO3 salting out agent, Triton X-114 FAAS 0.05 Spike recovery (water samples) 365
Ag Water, soil CPE Vitamin C, KNO3 salting out agent, TritonX-100 FAAS 0.035 Spike recovery (water samples) 344
As Honey, rice, water VA LLME DES benzyl triphenylphosphonium chloride and ethylene glycol, ethylenediamine-N,N′-disuccinic acid chelating agent HG-AAS 6.5 ng L−1 NIST SRM 1568a (rice flour) and 1643e (simulated fresh water), spike recovery (water, waste water samples) 366
Cu Olive leaves Sieve-linked double syringe LLME [2-(((E)-2-(((E)-2-Hydroxybenzylidene)amino)benzylidene)amino)], DCM FAAS 1.5 Spike recovery (olive leaf extract) 367
Fe Apple, human milk, rice, water In-syringe supramolecular DLLME Tiron (4,5-dihydroxy-1,3-benzendisulfonic acid) complexing agent; 1-hexadecyl-3-methylimidazolium bromide IL; extraction in reverse micelles of decanoic acid in THF FAAS 1.04 Spike recovery (water samples) 352
Pb Water, soil LLE Switchable hydrophilicity solvent N,N-dimethylcyclohexylamine-HAc; dithizone complexing agent; Triton X-114 ICP-AES 0.07 Spike recovery, Chinese CRM GBW (E) 080393 (simulated water) 368


Table 8 Preconcentration methods involving solid-phase (micro)extraction used in the analysis of soils, plants and related materials
Analyte(s) Matrix Substrate Substrate coating Technique LOD (μg L−1, unless otherwise stated) Validation Reference
Ag, Au Oak leaves, sunflower, tobacco, water Fe3O4 magnetic mesoporous silica Cetyltrimethylammonium bromide FAAS 0.4 Ag Spike recovery (oak leaves, sunflower, tobacco, water) 369
0.7 Au
Cu as 1-(2-pyridylazo)-2-naphthol ligand Eggplant, garlic, water Fe3O4@XAD-16 FAAS 10.2 NRCC HR-1 (river sediment) 370
Environment Canada RM TMDA 53.3 (fortified lake water)
Hg Beverages, biological samples, plants, seafood, water GO/thiosemicarbazide EDXRFS; TXRFS TXRFS: 2.1 pg mL−1 for liquids and 1.8 ng g−1 for solids Spiked recovery (water, apple juice, beer, wine); JRC ERM-CA615 (groundwater), CA713 (waste water), BB186 (pig kidney); Sigma-Aldrich QC3163 (seawater); Consortium MODAS LGC standards M-3 HerTis (herring tissue), M-4 CormTis (cormorant tissue), M-5 CodTis (cod tissue); NRCC Tort-2 (lobster); INCT-OBTL-5 (tobacco leaves); NACIS NCSZC73033 (scallion), 73032 (celery), 73013 (spinach) 371
EDXRSF: 60 pg mL−1 for liquid and 73 ng g −1 for solid samples
Pb Water, cooked meats, fish Tergitol@SiO2@Fe3O4 magnetic nanomaterial FAAS 0.07 INCT-TL-1-(tea leaves); NIST SRM-1643e (trace elements in water) 372
Pb Garlic, kefir, tea, tobacco, tuna MgCo2O4 FAAS 0.39 Spike recovery (garlic, kefir, tea, tobacco, tuna); NWRI TMDA-64.3 water; INCT-OBTL-5 (tobacco leaves) 373


4.4 Instrumental analysis

4.4.1 Atomic absorption spectrometry. Although traditionally considered as a technique for measuring one element at a time, ETAAS can also be used for multielement analysis by incorporating either multiple HCLs or a CS. A review (154 references) on advances in simultaneous or sequential multielement analysis by ETAAS in the period 2000–2020 advocated34 further development and greater use of HR-CS-ETAAS. A solid sampling HR-CS-ETAAS method for the determination of Cd, Fe and Ni in seeds used158 5 μg Pd + 3 μg Mg + 15 μL H2O2 as matrix modifier and aqueous standards for calibration. Cadmium was determined first at an atomisation temperature of 1600 °C and then the other elements were determined at 2500 °C. A background correction using the time[thin space (1/6-em)]:[thin space (1/6-em)]absorbance ratio was proposed159 as a potential improvement over least squares background correction for overcoming spectral overlap in HR-CS-ETAAS. The advantage of this approach was that the nature of the spectral interference did not need to be known a priori. Application of this correction method improved results for Pb in NIST SRMs 1570a (spinach leaves) from 0.350 ± 0.130 to 0.241 ± 0.068 mg kg−1 (reference value 0.2 mg kg−1). Although analyte oxide species are often the source of interference in CS-ETAAS, they can sometimes be used to advantage as demonstrated in a method160 for the determination of Si based on molecular absorption by SiO. This was successfully applied to the analysis of solid sample suspensions, including two soil and two sediment CRMs.

Use of a novel platinum-coated tungsten coil atom trap improved76 sensitivity for the determination of As by over an order of magnitude relative to conventional HG-AAS. The LOD was 0.016 μg L−1 for a trapping time of 90 s. Although primarily intended for use in (potable) water analysis, the method was tested with Supelco CRM 023 (sandy loam 7) for which the result of 375 ± 3.8 mg kg−1 agreed with the certified value of 380 ± 6.7 mg kg−1.

A single-point standard-addition method161 was proposed as an alternative to conventional external calibration in the ETAAS and ICP-AES determinations of trace elements in complex sample matrices. When silty soils BIM-1 and NES-1 from the GeoPT proficiency testing programme were analysed using the new method, the results for As, Cd, Pb, Sb, Se and Te agreed with the assigned values.

4.4.2 Atomic emission spectrometry. Research has continued in development of miniaturised AES systems with the ultimate goal of creating field-portable instruments. Different approaches have been taken for sample introduction and microplasma generation. Two methods optimised for the determination of As were based on HG-DBD-AES. Dried and powdered seaweed was digested162 to generate arsine which was preconcentrated on the DBD’s inner surface leading to improved sensitivity on ignition of the excitation plasma. The solution LOD was 0.2 μg L−1 and the method LOD 0.25 mg kg−1. Results for Chinese CRMs GBW 08521 and 10023 (both laver bread) agreed with the certified values. In a method described in more detail in Section 4.3.1 of this ASU, soil samples were introduced136 into the HG-DBD-AES system as a slurry. Swiderski et al.163 investigated hanging-drop-cathode APGD as an excitation source for AES. Incorporation of a Dove prism, to rotate the discharge image by 90°, and addition of 8% (m/m) formic acid together enhanced the intensity of analyte lines relative to background. Following optimisation by a DoE approach, results for INCT CRM TL-1 (tea leaves) were statistically in agreement with the certified values for Pb and Tl. The recovery of a Ag spike was 102%. Cai and Wang79 took a different approach with the aim of eliminating the need for CVG reagents and pneumatic nebulisation. They used a solution anode GD not as an emission source but as a vapour generator for the determination of Cd and Hg by ICP-AES. Signal intensity was increased by almost a factor of 12 for Cd and of 90 for Hg. The result for Cd in Chinese CRM GBW 07312 (aquatic sediment) was 3737 ± 102 μg kg−1 (certified value 3935 ± 63 μg kg−1). A solution cathode GD was also proposed164 for VG in the determination of Hg by ICP-AES. Spike recoveries from samples of fish, human hair and soil were 92–104% and the LOD at 194.1 nm was 0.22 μg L−1.

In the determination of F in plant-based materials by solid sampling ETV-ICP-AES, addition of H2 to the carrier gas improved165 LODs to 0.05–0.8 μg kg−1, depending on the F emission line studied. Multivariate optimisation yielded: rf power 1.7 kW; Ar carrier gas flow 0.15 L min−1; Ar bypass gas flow 0.2 L min−1 and H2 reaction gas flow 3 mL min−1. The analysis of 2 mg solid samples with a pyrolysis temperature of 200 °C and a vaporisation temperature of 2200 °C gave results for NIST SRMs 8432 (corn starch) and 8437 (hard spring wheat) that were not statistically different from information values according to Student’s t-test at 95% confidence.

Environmental analysis was included in a review by Fontoura et al.166 (95 references) of recent advances in MIP-AES for trace element determination. It was concluded that the technique could offer a lower-cost alternative to ICP-AES for some applications. A similar conclusion was reached by Proch and Niedzielski167 who compared HPLC-MIP-AES and HPLC-ICP-AES for Fe speciation analysis in soil, sediment and plant samples. As expected, the LODs for the MIP approach were poorer – by roughly an order of magnitude – than those obtained with ICP-AES, but it was still possible to quantify FeII and FeIII in some samples. The determination of Pb by HG-MIP-AES was demonstrated82 for the first time. The experimental conditions for the generation of plumbane were optimised and the effect of acid concentration on signal intensity studied. A relative measurement error of −9.3 ± 4.6% was achieved for duplicate analyses of the Embrapa soil RM Agro E2002a. To assess whether the high salt content of reagents typically used to estimate trace element mobility and availability in soils and sediments would preclude their analysis by MIP-AES, Serrano et al.168 investigated the effects of MgCl2, CaCl2, acetic acid, Na2EDTA, NaNO3, NaOAc–acetic acid and NH2OH·HCl on emission intensities for 15 elements. Although atomic lines with Eupper level values of <4 eV were generally enhanced relative to their intensity in 5% HNO3, the remaining atomic and ionic lines were suppressed. Matrix effects were worse in reagents containing elements with low IPs, such as sodium. Either Rh or OH molecular emission was recommended for use as a IS. Krogstad and Zivanovic169 carried out a more empirical comparison of MIP-AES, ICP-AES and ICP-MS for measurement of Ca, Cu, Fe, K, Mg, Mn, P, Zn in ammonium lactate extracts of soil. The lower-cost MIP technique was deemed suitable for monitoring of nutrient levels and fertilisation planning.

4.4.3 Atomic fluorescence spectrometry. The advantages and drawbacks of CVG-AFS methods for Se speciation analysis were discussed170 in a review (60 references). A pre-requisite for the determination of total Se is reduction of SeVI to SeIV but this reaction can be slow. Approaches described for overcoming this limitation included conventional heating, microwave irradiation and exposure to UV light.

A microplasma-induced CV-AFS method for the rapid screening and quantification of Hg in fruit gave171 results within 7% of those obtained by HG-AFS when applied to tomatoes, lemons and oranges. Whole fruit samples were punctured with a needle and the resulting juice droplet drawn into a stainless-steel capillary. A voltage was applied between the far end of the capillary and a tungsten electrode, and an argon microplasma generated in which Hg ions were converted to Hg0 before being swept into an AFS detector. The LOD of 0.3–0.5 μg L−1 depended on the type of juice analysed.

4.4.4 Inductively coupled plasma mass spectrometry. Recent advances in FFF-ICP-MS for characterisation of engineered NPs in environmental media were reviewed38 (103 references). The advantages of asymmetrical flow FFF and hollow fibre flow FFF were discussed and examples of their application to soil and sediment provided.

A critical and comprehensive review of sp-ICP-MS (301 references) discussed39 the evolution and principles of the technique, together with methods for the study of NPs in numerous sample matrices including soils and plants. Another review (159 references) focussed172 specifically on metallic NPs in biological samples. Both sets of authors identified the paucity of properly validated standardised methods and the lack of suitable NP CRMs as major factors hampering progress in the field.

Such issues did not deter other researchers from proposing sp-ICP-MS methods for determination of various types of nanoparticles, some of which are discussed in more detail in Section 4.3.1 of this ASU. These methods included: a procedure140 for determining nanoscale zero-valent Fe in soil that involved UAE in 0.25 mM tetrasodium pyrophosphate followed by magnetic separation; a procedure141 for determining nanoparticulate Hg in soil that employed 0.5 mM tetrasodium pyrophosphate + 0.5 mM sodium thiosulfate + 0.5 mM 2,3-dimercaptopropanesulfonate sodium salt + 0.01 mM sodium nitrate extractant; a procedure173 for determining gold NPs in plants that featured enzymatic digestion with Macerozyme R-10; and a procedure139 for determining gold, silver, titanium and zinc NPs in estuarine sediments, road dust and soil that was based on UAE in deionised water.

A versatile, open-source Python-based data-processing-platform with interactive graphical user-interface was developed174 for processing ICP-MS data from the analysis of single particles or biological cells. The capabilities of the algorithm were demonstrated by determination of TiO2 NPs in surface waters, microplastics in soil (using sp-LA-ICP-MS) and C in algal cells.

Holbrook et al.175 developed a sp-LA-ICP-TOF-MS procedure for the direct determination of nanoparticles in road-deposited sediment. The method was first evaluated using model gold and silver NPs, then tested on extracts of the sediments and finally applied to solid sediment mounted on double-sided tape. Element signals were classified into three groups. Group 1 consisted of elements (e.g. Al) present in such abundance that it was impossible to distinguish single particles from the background, group 2 consisted mainly of the REEs and group 3 was the PGEs. Single particles could be distinguished in both groups 2 and 3.

Several new metal-assisted PVG-ICP-MS methods used a ‘sensitiser’ – typically a transition metal ion – to enhance the generation of volatile species. A procedure for the determination of Cd in rice used176 a Fenton-like digestion and 20 mg L−1 Co2+ to improve the PVG yield. The LOD was 1.6 μg kg−1 and results for Chinese CRMs GBW 100351 and 100357 (both rice flour) were not significantly different from the certified values. The analysis of a 0.7 mL sample containing 10% formic acid, 300 mg L−1 Co2+ and 30 mM Cl enhanced177 the photochemical reduction of Ge to give a LOD of 0.008 μg L−1. Results for the two soil CRMs IGGE GSS-3a and GSS-5a were not significantly different from the certified values. Dong et al.178 reported the first use of vanadium species as sensitisers in PVG. The addition of 40 mg L−1 VV (in the form of VO3) increased the response for both TeIV and TeVI up to 55-fold compared with direct solution nebulisation and 1.5-fold relative to Co2+-assisted PVG. The LOD was 2.9 ng L−1 and accurate results were obtained for Te in the Chinese CRMs GBW 07303a and 07305a (both stream sediment). A method for the determination of Os used179 50 mg L−1 Fe2+ (or Fe3+) as a sensitiser to achieve a LOD of 0.16 pg mL−1. The method was validated by spike recovery because few CRMs certified for Os are available. Recoveries of 1 ng mL−1 Os added to water, sediment and fish protein samples were 94–109%.

The coupling of chromatographic separation with ICP-MS remained of interest. Of particular note was a HPLC-ICP-MS method180 for determination of inorganic As species in rice. A novel on-column species-specific internal-calibration-strategy was proposed to overcome challenges associated with ID, such as cost and non-availability of suitable isotopically enriched standards. A species-specific ID HPLC-ICP-MS method previously applied to other foodstuffs was shown181 to be applicable to the Cr speciation analysis of rice. When 10 rice samples of different origin were analysed, no CrVI was detected. Indeed, a CrVI spike added to basmati rice was reduced to CrIII within 2 h thereby confirming that Cr in rice is present solely as CrIII. An HPLC-ICP-MS method was developed182 and applied, together with LA-ICP-MS, to study Cr uptake in Taraxacum officinale (dandelion). Two methods for Se speciation analysis, one for rice150 and the other for plant-based foods,183 were based on enzymatic extraction and RP IC-ICP-MS. A species-specific ID-GC-ICP-TOF-MS method was developed184 for the determination of MeHg in canal sediment. The LOQ and precision for measurement of the 201Hg/202Hg isotope ratio were similar to those obtained by ID-GC-ICP-Q-MS and ID-GC-ICP-SF-MS. It was noted that the superior performance of ICP-TOF-MS previously observed with continuous liquid-sample-introduction was not achieved for analysis with transient signals.

Rapid data acquisition is important in the elemental mapping of botanical tissues by LA-ICP-MS in order to obtain high-resolution images in minimal time. Careful optimisation of the type of ablation cell, the mixing bulb and the inner diameter of the aerosol-transport tubing reduced185 the single-pulse response for Hg and Se to 50 ± 2 and 61 ± 4 ms, respectively. This represented a 5-fold improvement over the standard instrument configuration and allowed mapping of a segment of mushroom tissue at up to 20 pixels s−1. A simple calibration strategy based on aqueous standards deposited on filter paper was proposed186 for the determination of Cu and Zn in tree rings. Although most results were significantly different statistically from those obtained for the analysis of wood digests, even when normalised using 13C as an IS, the method was nevertheless able to reveal trends in analyte concentrations.

Wider availability of instrumentation led to an increase in publications featuring ICP-MS/MS. A review (79 references) considered37 articles published in the period January 2018 to July 2021 and included some featuring the analysis of soil or plant materials. A method for the Sr isotopic analysis of microsamples combined187 a syringe-driven pump delivering a stable 20 μL min−1 microflow of sample with a high-efficiency sample introduction system, originally designed for the introduction of single cells, to compensate for the low uptake rate. Even though no chromatographic separation of Rb and Sr was undertaken, the 87Sr/86Sr ratio could be determined at ng g−1 concentrations in as little as 240 μL of sample. In a multielement method, N2O was preferred188 to O2 in the ICP-MS/MS collision/reaction cell because it improved sensitivity and selectivity for the determination of “technologically critical elements” in sediments. A procedure for ultra-trace level quantification of 241Am in soils involved189 radiochemical separation followed by the introduction of 0.09 mL min−1 He containing 20% O2 and 12 mL min−1 He reaction/collision gas mixture into the cell for determination of the isotope in mass-shift mode as AmO+. The LOD was 0.017 fg g−1. Results for the two soil CRMs IAEA Soil 6 and IAEA 375 were similar to values reported in the literature.

Several research groups have recommended different collision/reaction cell gas combinations in the determination of Pu isotopes by ICP-MS/MS. The aim was to eliminate the interferences from uranium hydrides. Zhang et al.190 quantified Pu in soil by combining gas flows of 0.15 mL min−1 O2/He and 12 mL min−1 He both to dissociate interfering polyatomic ions and to form PuO2+. In their measurement of Pu in lake sediments, Xu et al.191 used 0.4 mL min−1 NH3 to remove interferences by formation of adduct species such as UH(NHm)n+. Bu et al.192 also used NH3 (30% NH3 in 5 mL min−1 He) to eliminate UH+ interference in the measurement of the 240Pu/239Pu ratio in soil and sediment. The LODs of all three methods were sub-fg.

Precise measurement of the 234U/238U and 235U/238U isotope ratios in Fukushima soil samples was facilitated193 by an improved sample preparation method for MC-ICP-MS analysis. Of various combinations of resin tested three sequential UTEVA™ columns provided the highest recovery of U and the smallest mass bias. Lead isotope analysis was performed194 by a novel combination of plasma-induced CVG and MC-ICP-MS. Although mass-dependent fractionation of the Pb isotopes occurred, this was successfully corrected by a 205Tl/203Tl external normalisation combined with SSB. The method gave results for the two USGS basalt RMs BCR-2 and BHVO-2 that were said to be in good agreement with GeoReM preferred values although no statistical comparison was actually reported. The method was applied to soil samples, mine waste and ore. A procedure for determining Cd isotopes involving MAE and resin purification gave195 results similar to those reported by previous authors for a suite of soil, sediment and plant CRMs. Enrico et al.30 made novel use of a direct mercury analyser as a rapid means of solid sample preparation. Mercury in the effluent from the instrument was trapped with >90% efficiency in a 5[thin space (1/6-em)]:[thin space (1/6-em)]1 v/v mixture of 10% HCl and BrCl and the solution then analysed by MC-ICP-MS. No significant isotopic fractionation was observed and δ199Hg and δ202Hg values for NIST SRM 1775a (pine needles) and NRCC MESS-2 (sediment) were similar to literature values.

A reminder of the need to choose the correct IS for ICP-MS analysis was provided by Alvarado et al.196 who compared 6Li, 45Sc, 69Ga, 89Y, 103Rh, 115In, 159Tb and 209Bi for the determination of As in soil. Significant analytical bias occurred when the ‘native’ concentration of the nuclide selected as IS in the soil digest approached or exceeded the concentration added.

4.4.5 Laser-induced breakdown spectroscopy. Numerous review articles featuring soil and plant analysis have been published. Goncalves et al.108 (83 references) provided a brief introduction to LIBS principles and instrumentation and described some recent applications featuring analysis of environmental samples, including soils and sediments. In their review (151 references) of articles published in the period 2010–2019, Zhang et al.107 focussed on environmental applications, including the analysis of soils and sediments. The use of ANN-based chemometrics in LIBS was discussed by Li et al.197 (149 references). Wang et al.198 highlighted (244 references) that measurement uncertainty and matrix effects were two major (and interlinked) factors hindering progress in LIBS analysis and proposed a useful research framework for improving quantification. Hu et al.199 reviewed (137 references) calibration-free LIBS in which the measured concentration is derived from an algorithm rather than from the analysis of standards. Ren et al.200 summarised (134 references) applications of LIBS in agriculture in the period 2017 to 2021 with particular reference to the detection of nutrients and PTEs in soils, fertilisers, waters and crops. Khan et al.109 included the analysis of plants and plant-derived foodstuffs in their review (207 references) which also featured a useful comparison of the advantages and disadvantages of different types of LIBS analysis.

A novel signal-enhancement strategy for LIBS analysis of soil combined201 APGD and cylindrical (plasma) confinement. The LODs of 2, 31, 21, 35, 49, 67, 43, 20 and 18 mg kg−1 for Ba, Cu, Eu, La, Lu, Ni, Ti, Y and Yb, respectively, were significantly better than the values (10, 133, 102, 175, 262, 356, 246, 158 and 105 mg kg−1, respectively) achievable using conventional LIBS. An alternative approach involved202 addition of 15% KI to soil samples to increase plasma temperature and electron density. The new technique of multidimensional plasma grating-induced breakdown spectroscopy also improved203 emission intensities (ca. twofold relative to 1D plasma-grating induced breakdown spectroscopy). The LOD for the determination of Mn in soil at 403.17 nm was improved from 394 to 306 mg kg−1.

Amongst other advances in the analysis of soils by LIBS was a combined atomic- and ionic-line algorithm204 that improved spectral stability and therefore reduced uncertainty in calibration and a method205 designed specifically for analysis of wet soils that could be used to estimate the sample moisture content and to correct for its influence on the ablation process. A procedure for the determination of Cr combined206 the adaptive least absolute shrinkage and selection operator with support vector regression. Different amounts of Cr(NO3)3 were added to the Chinese soil CRM GBW 07403 in the method development but a linear response was obtained (R2 = 0.998) only for Cr concentrations of 0.02 to 1.0% which are far higher than the Cr concentrations typically found in soils.

The influence of laser-spot size on the determination of Al, Ca, Cr, Fe, Mg, Mn, Ti and V in stream sediments by fibre-optic LIBS was studied.207 A change in lens-to-sample distance of as little as 1 mm resulted in a larger ablation crater, lower laser fluence and decreased analyte emission intensities. Under optimised conditions, results close to target values were obtained for a CRM from Tanmo Quality Inspection Technology Co., China.

Interest in the analysis of plant materials by LIBS is growing and it is welcome to see many authors including CRMs or comparisons with established techniques in their work. A single calibration model208 based on matrix-matched RMs was applied to the DP-LIBS determination of Ca, Mg, Mn and P in soybean and sugar cane leaves. Results for the majority of samples were 100 ± 20% of ICP-AES target values. In the CF-LIBS analysis209 of Maerua oblongifolia, a medicinal plant native to Pakistan, results for Al, Ca, Fe, K, Mg, Na and Sr were similar to those obtained by ICP-MS whereas Si was underestimated and Ba, Li, Rb and Zn were overestimated. Another CF-LIBS method was tested210 using both plant and soil CRMs. Results for Al, Ca, Mg, N and Na in Chinese RMs NCSZC73014 (tea leaf) and NCSZC73012 (cabbage leaf) were generally within 80 to 120% of the certified values, provided the analyte concentration was normalised to that of a major element such as K.

4.4.6 X-ray spectrometry. Reviews on the use of XRFS in soil and plant analysis covered methods related to the in situ mapping and availability of P in soils119 (106 references), advances in plant imaging211 (172 references) and potential problems commonly encountered during forensic soil analysis212 (46 references).

Improving the accuracy of XRFS analyses of dried plant samples through the modification of sample preparation methods such as sample[thin space (1/6-em)]:[thin space (1/6-em)]binder ratio and pelletising pressure was the aim of several XRFS studies. A sample mass of 20 mg per 5 mL dispersant and a particle size of 200–300 mesh improved213 analytical performance in the determination of medium and high atomic number elements in tea powder by TXRFS. In the standardless WDXRFS analysis of the conifer species Pinus nigra and Abies alba, a wax binder ratio of 20% in the pellet preparation led214 to a statistically significant underestimation of the concentrations of the light elements Al and Mg but an overestimation of those for Fe and Mn. Variations in pellet mass (1–5 g) and pressure (10 and 25 t) did not have a significant effect on the results. Orlic et al.215 compared the performance of WDXRFS using a standardless calibration based on fundamental parameters (UniQuant) with that obtained by external calibration using cellulose standards, prepared either with a wax binder or as a thin film. The accuracy, precision and LODs obtained with standard calibration using 20% wax binder were better than when either the thin layer or the semi-quantitative standardless methods were used. These last two methods overestimated most element concentrations with a marked drop in accuracy for light elements at concentrations of <50 mg kg−1.

5 Analysis of geological materials

5.1 Reference materials and data quality

The annual Geostandards and Geoanalytical Research bibliographic review (over 600 references) provided216 an overview of papers published in 2020 that contributed important data for geoanalytical RMs. A substantial number of the publications focused on newly developed RMs and analytical data for existing RMs obtained using improved methods. All the data referred to in this review have been entered into the GeoReM database that is freely available online (http://georem.mpch-mainz.gwdg.de).

Much of the current effort has been directed toward identifying natural minerals that are sufficiently homogeneous to act as reference materials for microanalytical techniques. Particularly prominent in this review period was the characterisation of new materials for isotope ratio determinations; these have been collated in Table 9. Although most of these materials are available from the authors, many do not exist in sufficient quantities to facilitate their widespread use and so in reality are little more than in-house QC materials.

Table 9 New geological reference materials for isotope measurements
Isotopes Matrix Technique RM name RM or other validation Reference
C, O Carbonate of Jurassic age IRMS SHP2L NBS 18 (carbonatite) and NBS 19 (limestone; normalised to VPDB) 374
Cu Chalcopyrite LA-MC-ICP-MS TC1725 Ratios expressed relative to NIST SRM 976 (Cu metal) 375
Fe, S Iron sulfides LA-MC-ICP-MS Synthetic pyrite and chalcopyrite RMs using plasma-activated sintering S ratios normalised to VCDT 376
Fe, S Iron sulfides SIMS, LA-MC-ICP-MS JC-Po (pyrrhotite), JC-Pn (pentlandite) Fe ratios by LA-ICP-MS normalised to IRMM-014 (Fe metal), and S ratios by SIMS to VCDT 377
Hf, O and U–Pb Zircon SIMS, LA-MC-ICP-MS, IRMS, TIMS Zircon ZS Zircon RMs TEMORA, 91500, Tanz, GJ-1 378
Nd and U–Pb Apatite LA-ICP-MS, LA-MC-ICP-MS Sumé-570 apatite U–Pb ages: zircons 91500 and Mud Tank. Range of RMs used to assess accuracy of Nd ratios 379
Nd, Sr and U–Pb Apatite ID-TIMS, LA-ICP-MS MRC-1 and BRZ-1 Apatite RMs MAD, Durango, McClure 380
O Calcite IRMS, SIMS NJUCal-1 Normalised to VPDB 381
O, Zr and U–Pb Zircon LA-ICP-MS, LA-MC-ICP-MS, SIMS, ID-TIMS, IRMS Tanz zircon megacrysts Zircon RMs: 91500, GJ-1, Plešovice, M257 and Jilin 382
O, Zr and U–Pb Zircon ID-TIMS, SIMS, LA-ICP-MS, IRMS Jilin Zircon RMs: Plešovice Qinghu, GJ-1 383
O O17-enriched sodium sulfate Pyrolysis Sulf-A, Sulf-B, Sulf-C Nitrate RM USGS35 23
O Apatite SIMS, IRMS MGMH#133648, MGMH#128441A, MZ-TH, ES-MM SARM 32 (phosphate rock). Ratios expressed relative to VSMOW 384
Os, Re Chalcopyrite MC-ICP-MS, NTIMS XTC chalcopyrite (with low Re mass fraction) NIST Henderson molybdenite RM 8599, NRCG CRMs HLP (molybdenite), JDC (molybdenite), JCBY (Cu–Ni sulfide) 385
S Sulfide and sulfates LA-MC-ICP-MS Synthetic pyrite, chalcopyrite, sphalerite, galena, arsenopyrite, barite, and gypsum RMs Targets synthesised from sulfide or sulfate NP powders mixed with epoxy resin. S ratios normalised to VCDT 386
S Chalcopyrite LA-MC-ICP-MS, IRMS TC1725 IAEA-S-2 and IAEA-S-3 (Ag2S powders from IAEA). S ratios normalised to VCDT 387
Si Si powder MC-ICP-MS GBW04503 Blends of synthetic isotopically-enriched Si solutions 388
U–Pb Scheelite LA-SF-ICP-MS Scheelite WX27 Wolframite YGX 251
U–Th Zircon SIMS, LA-ICP-MS, LA-MC-ICP-MS SS14-28 Overall isochron with data from three different analytical techniques 389
Zr Solution MC-ICP-MS ZIRC-1 (NRC) IPGP-Zr and USGS RMs BHVO-2 (basalt) and AGV-2 (andesite) 390


An alternative strategy has been to characterise well-known geological RMs for additional elements and isotope systems not included in the original characterisation. These new data are summarised in Table 10. Many of these materials are powdered RMs that are quite widely available; it should be noted that after a hiatus of several years, the USGS plan to sell some of their more popular geological RMs once again.

Table 10 New data for existing geological reference materials
Determinand Matrix Technique RM or other validation Comments Reference
B and δ11B Geological RMs MC-ICP-MS δ 11B values normalised to NIST SRM 950 (B isotope solution) δ 11B values for 18 geological RMs reported 391
B, Hf, Li, Mg, Nd, O, Pb, Si, Sr isotopes, Fe2+/ΣFe Andesite glass RMs SIMS, LA-MC-ICP-MS, EPMA, TIMS, colorimetric Cross-checking of data from different techniques and labs Expansion of available data for andesite glass RMs ARM-1, ARM-2 and ARM-3 392
δ 44Ca/40Ca Geological RMs TIMS IAPSO seawater and NIST SRM 915a (Ca carbonate) 34 Chinese geological RMs 127
δ 114Cd/110Cd Geological and environmental RMs MC-ICP-MS Cd ratio normalised to NIST SRM 3108 (Cd isotope solution) Cd isotope ratios reported for 34 RMs 130
Cr isotopes Geological RMs MC-ICP-MS Cr ratios normalised to NIST SRM 979 (Cr isotope solution) Cr isotope ratios reported for 18 existing RMs for the first time 393
Cu, Pb and Zn isotopes Geological and biological RMs MC-ICP-MS Normalisation to Cu ERM-AE647 (Cu), NIST SRM 981 (Pb) and IRMM-3702 (Zn) Cu, Pb and Zn isotope data for 23 geological RMs 394
Li isotopes Geological RMs MC-ICP-MS Lithium carbonate RMs IRMM-016 and NIST SRM 8545, 8 geological RMs and seawater New δ7Li data reported for 10 geological RMs 124
Nd–Sm Allanite LA-ICP-MS, LA-MC-ICP-MS In situ data consistent within uncertainty with solution methods Daibosatsu and LE40010 suitable as RMs for allanite Nd–Sm microanalysis 395
Re, PGEs and 187Os/188Os Organic-rich geological RMs N-TIMS, MC-ICP-MS RM 8505 (crude oil), RM 8505 (asphdiene) New data for USGS RMs: SBC-1 (marine shale), SGR-1b (oil shale), SCo-2 (marine shale), ShTX-1 and ShCX-1 (calcareous organic-rich shales) 396
Si isotopes Quartz and zircon SIMS NIST 8546 (previously NBS-28) quartz RM and NIST 610 (glass) Quartz RMs: Qinghu-Qtz and Glass-Qtz. Zircon RMs: Qinghu-Zir and Penglai-Zir. Test materials found to be more homogeneous in Si isotopes than NIST 8546 397
Si and Zr isotopes Zircons LA-MC-ICP-MS Si ratios normalised to NIST NBS28. Zr ratios normalised to IPGP-Zr Zircon RMs SA01 and SA02 398
U isotopes U ore concentrates MC-ICP-MS, ICP-MS, SIMS, AMS, TIMS Various validation strategies depending on analytical technique 13 labs reported data on 3 candidate NRCC CRMs (UCLO-1, UCHI-1 and UPER-1) 399
U–Pb ages Apatites ID-TIMS Derived from 3D linear regressions Reference ages for Durango and Wilberforce apatite RMs 400
U–Th–Pb ages Allanite LA-ICP-MS, LA-MC-ICP-MS U–Th–Pb ages consistent within uncertainty with literature and ID-TIMS values Allenite LE40010 suitable as RM for U–Pb dating and CAPb for Th–Pb dating 395
Zn isotopes Zn metal, sphalerite fs LA-MC-ICP-MS, MC-ICP-MS, EPMA δ 66Zn normalised to JMC-Lyon Zn metal RMs NIST SRM 683 and NBS 123 suitable as RMs for in situ Zn ratio measurements; matrix effects between sphalerite and Zn-rich minerals discussed 401


While RMs are an important cornerstone of method development and quality assurance, proficiency testing is another facet of good laboratory practice. Meisel et al.217 reviewed (35 references) some lessons learnt from 25 years of the GeoPT, the highly successful proficiency-testing programme for the geochemical analysis of geological materials. The data submitted to GeoPT provided a valuable resource that allowed detailed comparison of different methods of sample preparation and measurement principles. Examples included in the discussion were the recurring problems with the dissolution of the refractory minerals zircon and chromite when only acid digestion is involved, and issues related to preparing samples for XRFS analysis.

In a commendable initiative to promote a more efficient and transparent system for curating geochemical data, a consortium of Australian research laboratories collaborated218 to build a platform called AusGeochem to preserve, disseminate and collate geochronology and isotopic data. The cloud-based system is an open relational data platform designed to be a geosample registry, a geochemical data repository and a data analysis tool. The next stage is to create a global geochemical data network through coordination and collaboration among international geochemical providers via an EU-funded project called OneGeochemistry. At the very least, this will require global agreement on international standards, best practices and vocabularies.

5.2 Sample preparation, dissolution, separation and preconcentration

For whole rock determinations by acid digestion, complete sample digestion is essential for the accurate determination of trace element mass fractions in geological materials, as highlighted by Meisel et al.217 In recent years, NH4HF2 has been proposed as a “green” alternative to HF-based dissolutions but complete digestion can be time-consuming. Zhang et al.219 designed and manufactured a PTFE digestion vessel with a lid that could be operated safely at 300 °C in a procedure to reduce the time for sample evaporation and redissolution in a NH4HF2 digestion. Microwave heating was employed at the redissolution stage to suppress formation of insoluble fluoride residues during the high-temperature evaporation stage. The optimised procedure reduced the time for sample evaporation and redissolution from 9 h to 21 min. Results were within ±10% of the reference values for 37 elements in seven rock RMs with a range of lithologies. To overcome the problem of insoluble fluorides formed during an HF digestion, Kagami and Yokoyama220 adjusted the Ca–Al–Mg composition of the samples prior to digestion in a high-pressure system for the determination of 27 elements, including the HFSEs, by ICP-MS. Whereas mass fractions of Hf, Ti and Zr were determined by an ID method, all other elements were determined by an ID-IS procedure using solutions containing enriched spikes of 91Zr–179Hf or 113In–203Tl as ISs. One drawback of this method was the need to know the Al, Ca and Mg contents of the sample before analysis but the method was considered particularly beneficial for the analysis of valuable materials, such as samples returned from space missions, because of the wide range of elements that could be determined on as little as 0.50 mg of material. Alkaline fusion is an alternative approach to sample dissolution for silicate rocks. The sodium peroxide sintering method was adapted221 successfully for the determination of B mass fractions and δ11B by MC-ICP-MS. The sintering was carried out in glassy carbon crucibles in a muffle furnace at 490 °C for 30 min with a flux-to-sample ratio of 3 + 1. The elements were isolated by single-column ion-exchange chromatography using Amberlite 473 resin and aliquots were spiked with 10B-enriched NIST SRM 952 for determining B mass fractions by ID. All solutions were analysed in 2% HNO3. Advantages of this method were that it removed Na and Si from the sample matrix effectively and was capable of generating accurate B mass fraction and isotopic data within a day without the need for expensive laboratory equipment and reagents. A table of measured and published data for a range of geological RMs, seawater and coral demonstrated the accuracy and precision of the procedure.

Sample preparation procedures for the precious metals and PGEs continue to attract attention. Conventional procedures involve lead or nickel sulfide fire assays but a novel method for the determination of Au and the PGEs involved222 bismuth fire assay combined with ICP-MS analysis. The bismuth bead produced from the fire assay at 1060 °C was cupellated for 30 min in a magnesia cupel at 850 °C before microwave digestion of the bismuth granule in 40% (v/v) aqua regia. The method accurately quantified Au, Ir, Pd, Pt and Rh and the volatile element Ru and was applied to a range of geological samples including chromite, black shale and polymetallic ores. The LODs were 0.002 (Rh) to 0.025 (Au) ng g−1. Wu et al.223 developed a method for the determination of trace amounts of Ag in geological samples using extraction with inverse aqua regia and ICP-MS analysis. An online aerosol-dilution strategy involving dilution of a sample aerosol with argon prior to the plasma was adopted to reduce the amount of water and acid entering the plasma and thereby eliminate interferences from polyatomic Nb and Zr species. This helped to maintain the high temperature of the plasma while minimising the formation of oxides and other polyatomic ions. The method had a LOD of 0.2 μg g−1 and was applied to 68 geological RMs.

5.3 Instrumental analysis

5.3.1 Laser-induced breakdown spectroscopy. Laser-induced breakdown spectroscopy (LIBS) was described198 as the “future superstar for chemical analysis”. However, as indicated in various reviews, the technique has several major challenges to overcome before it can live up to this claim. Zhang et al.107 (152 references) summarised progress of LIBS technology and its application to environmental monitoring between 2010 and 2019. The review included a helpful introduction to LIBS, signal enhancement techniques and chemometric methods and a discussion of progress in its application to soil, water and atmospheric monitoring. A review (245 references) aimed at LIBS researchers with a basic knowledge of the technique summarised198 recent hardware improvements and advances in quantification. The impacts of signal uncertainty and matrix effects were explained and different strategies for improving LIBS quantification compared. Generally, there are two types of quantification model: one is based on calibration with RMs and the other type is calibration-free. A detailed overview199 (137 references) of calibration-free LIBS covered the basic theory, together with improvements proposed to overcome non-stoichiometric ablation, self-absorption effects and the complexity of algorithms. Many of the existing problems blighting the practical application of calibration-free LIBS were discussed and future perspectives considered. Liu et al.224 (102 references) reviewed the application of LIBS to the analysis of coal over the last decade (2011–2020). Suitable LIBS instruments, pretreatment of samples, processing of spectral data and methods for coal analysis were assessed. Matrix effects were considered to be the main obstacle to the application of LIBS to the quantitative analysis of coal.

As highlighted in several of the reviews, problems in the use of LIBS are the extraction of useful information from complex LIBS data and the need to reduce interference effects such as background signals, noise and overlapping peaks. As a consequence, much effort has been devoted to chemometric methods for handling LIBS data. These included: a convolutional neural network model for the analysis of phosphate ore slurry;225 a convolutional neural network model with a 2D algorithm for the determination of the lithology and major element compositions in rocks;226 rapid LIBS multielement imaging combined with deep-learning theory for the classification of rocks;227 and machine-learning algorithms to determine structural water in rocks.228

The ability of LIBS to detect virtually any element in the periodic table on-site with little or no sample preparation is very attractive to the mining industry. The application of LIBS to ore prospecting and processing included: evaluation of gold-bearing rocks in Canada;229 determination of the total Fe content in Australian iron ores;230 measurement of the chemical composition of Cu ores;231 study of matrix effects in the analysis of coal;232 identification of the major and accessory minerals in lithium-bearing pegmatites;233 and quantification of six REEs in graphite pellets at the ppm level.234

Various strategies have been adopted for the analysis of rock samples by LIBS. In a novel method for the determination of F in geological samples, pure SrCO3 was placed235 orthogonally to the sample and ablated using an additional laser to provide sufficient Sr atoms for promoting the formation of SrF radicals. The SrF radical spectra have a stronger intensity and suffer from less interference than F atomic emission spectra so the ability of LIBS to detect F in rocks was enhanced. The LOD was 6.36 μg g−1. Of great relevance was a study236 on how best to quantify measurement limits when analysing geological materials using multivariate analysis modelling techniques. The aim was to provide a template for calculating LOQs based on multivariate LIBS regression models and to understand how this value was affected by factors such as instrumentation, method of outlier removal and different atmospheres (air, vacuum or simulated Martian conditions relevant to the ChemCam instrumentation). By studying the effect of the LOQ on model validation, it was demonstrated that the LOQ was an essential metric for a better understanding of model quality.

The development of the LIBS technique has benefitted greatly from its successful deployment in the SuperCam instrument on Mars. Compensation for spectral differences caused by varying distances between sample and sensor usually involve conventional spectral data processing but a new chemometrics model with powerful learning ability has been constructed237 for this correction. The performance of the convolutional neural network designed in this project surpassed those of four alternative chemometric approaches, making it a promising methodology for geochemical sample identification in future space missions. Associated with the LIBS equipment in the SuperCam instrument suite was a microphone, which was used238 to retrieve the physical properties of ablated targets by listening to the laser-induced acoustic signal. Sound data recorded during the LA of hematite, goethite and diamond showed a sharp increase in the amplitude of the acoustic signal during the first laser shots. Examination of the laser craters using Raman spectroscopy and SEM indicated that hematite and goethite had been transformed into magnetite and that diamond had been transformed into amorphous-like C. It was concluded that these transitions were the root cause of the increase in acoustic signal and that this behaviour occurred only for specific phases. This concept was further explored239 by probing Fe-based and Ca-based minerals at a sampling distance of 2 m to test whether merging the acoustic signals with the LIBS spectra could improve the discrimination of spectrally similar minerals in a remote LIBS configuration. Once validated under Earth conditions, the approach was tested in a Mars-like atmosphere. From these preliminary experiments, it was concluded the implementation of this strategy in an open environment needed to be conducted with care and that instruments with a better S/N could improve the results obtained in a Mars-like atmosphere. A portable standoff LIBS instrument was designed240 and constructed within three weeks to monitor changes in the composition of lava streams from an active volcano in the Canary Islands at a minimum of 20 m from the lava flow. This strategy was adopted after several drones carrying compact LIBS instruments had crashed during low-level flights because of the hostile environmental conditions. In spite of there being only subtle spectral differences between samples but considerable signal variability induced by the wind, sufficient information could be extracted from the data using PCA for sample classification.

An exciting development in recent years has been the potential afforded by the integration of LIBS data with data obtained by complementary techniques such as LA-ICP-MS. This was demonstrated241 in the elemental imaging of a uranium ore sample prepared as a thin section. A preliminary view of the elemental distribution on a large area was obtained by LIBS and then a detailed survey of selected areas was performed using LA-ICP-MS. Specially-developed software allowed the imaging data from the two techniques to be merged so that detailed structures (from ICP-MS) could be superimposed on the overall sample image obtained by LIBS. Using this approach, structures responsible for migration of elements in the uranium ore could be identified. Several combined LA-ICP-MS/LIBS instruments are now commercially available, making it possible to acquire simultaneously both spatially resolved data for elements such as C, F, H, O and N and conventional MS data. This configuration provides a wider elemental coverage and greater dynamic range than either instrument alone and we expect to see more reports of its use in geological applications before too long. A novel procedure242 for the analysis of volcanic brines involved freezing the fluids before analysis by LA-ICP-MS/LIBS. Liquid RMs were prepared by adding elements of interest at known but varying concentrations to a natural brine sample taken from a volcanic crater lake. Differences in ablation yield were accounted for by adding Li as an IS and all samples were run as line scans rather than point analyses to prevent the samples thawing. Data for Al, Ca, Cl, Fe, K, Li, Mg, Na and S in volcanic brine determined by cryo-LIBS and cryo-ICP-QMS in collision cell mode were within 10% of the values obtained by solution ICP-AES. The only exception was the determination of Fe by LIBS for which the difference was 17%. The attraction of the cryo-analytical method was the ease of sample preparation and the potential for determining major and trace elements simultaneously. However, care needs to be taken to ensure homogeneity of the frozen brines.

5.3.2 Dating techniques. Improvements in sample preparation procedures for dating techniques included243 a method for separating and concentrating zircons from mafic rocks that combined physical separation with chemical dissolution. This was more efficient than conventional density and magnetic-separation methods, particularly for medium- to fine-grained mafic rocks in which zircons were rare, small in size and commonly associated with ferromagnetic minerals. Overall, there was a 15- to 1000-fold increase in the zircon yield so analytically viable amounts of zircon for U–Pb geochronology could be recovered from relatively small samples (<1 kg). Li et al.244 developed a new H2SO4–Na2CrO4 method for digesting black shales for Re–Os dating. The initial Re blank of the Na2CrO4 reagent was greatly reduced by purification with acetone and the overall procedural blanks of <1 pg for Os and 1–2 pg for Re were an order of magnitude lower than those in the widely-used H2SO4–CrO3 digestion method.

There has been much research activity focused on the U–Pb dating of accessory minerals other than zircon by microanalytical techniques. Minerals investigated included: apatite245 by LA-ICP-MS/MS, carbonates246 by LA-MC-ICP-MS, cassiterite247 by LA-SF-ICP-MS, garnet248 by SIMS, ilmenite249 by LA-ICP-MS, rutile250 by LA-ICP-MS, scheelite251 by LA-SF-ICP-MS, titanite250,252 by LA-ICP-MS and SIMS, vesuvianite253 by LA-SF-ICP-MS, wolframite254 by LA-ICP-MS and xenotime255 by APT. The continued development of U–Pb dating methods to a wide range of minerals is fundamental in increasing the number of geochronological tools available for unravelling geological processes.

In a review of detrital zircon U–Pb data, Powerman et al.256 noted various obstacles in making use of the growing volume of available data and proposed guidelines for publishing detrital zircon geochronology data. They designed a new software tool called Dezirteer, which could rapidly process and analyse large amounts of detrital zircon analyses (102–105) in batches and prepare tables and images ready for publication. In a new statistical approach for improving the regression of low-count U–Pb geochronology data, Davis et al.257 took LA-ICP-MS line-scan data from samples with low-U mass fractions and regressed them as count rates in a 3D space rather than as ratios on a 2D plot. They demonstrated that the maximum-likelihood estimation for the best-fit mixing surface in a 3D signal-count-space gave accurate results consistent with geological and synthetic data. They observed that this approach did not replace commonly-used programs such as Isoplot but allowed optimal interpretation of LA-ICP-MS data for samples with low U contents. Lin et al.258 assessed factors affecting downhole fractionation in zircon crystals during the rapid LA-MC-ICP-MS acquisition of U–Pb data at high spatial resolution (≤10 μm spot). Two analytical modes using various combinations of FCs and ion counters were employed to cover a wide range of U and Pb mass fractions in the study of three zircon RMs. By correcting for downhole fractionation using Iolite software, U–Pb ages with an accuracy of <1% and a precision of <0.5% could be obtained. A problem encountered in LA-ICP-MS analysis is that the laser focus can vary during routine operation with both manual and automatic focusing systems. Huang et al.250 demonstrated that a 30 μm variation of laser focus led to a systematic shift of 4–6% in 206Pb/238U ratios when ablating zircon RMs. They suggested that poor focusing could explain the relatively poor reproducibility of U–Pb dating by LA-ICP-MS when compared with SIMS analysis.

There has been increasing interest in in situ Rb–Sr dating using LA coupled to either MS/MS or MC-ICP-MS instruments. Rösel and Zack259 presented a procedure to measure, calculate and validate Rb–Sr ages from individual laser spots on detrital micas. The Sr isotopic composition was measured in mass-shift mode using N2O as the reaction gas and mica-Mg as the primary RM. Data reduction was undertaken using a script written by the authors for Iolite. The procedure was validated using various mica samples of known ages; the Rb–Sr ages determined were not significantly different from the respective reference values. A nanopowder pellet called mica-Fe was proposed as a secondary RM for Rb–Sr geochronology. In a study of LA-ICP-MS/MS applied to the Rb–Sr dating of celadonite to decipher alteration conditions after accretion of oceanic crust, methyl fluoride was employed260 as the reaction gas and the 87Rb/86Sr ratios calibrated using several of the MPI-DING glass RMs. Bevan et al.261 demonstrated the capabilities of a prototype “tribrid” MS system coupled to a UV LA system for in situ Rb–Sr dating. The instrument consisted of a quadrupole mass filter and collision cell coupled to a MC-ICP-MS system to provide enhanced ion transmission and simultaneous collection of all Sr isotopes. These features improved the precision on the 87Sr/86Sr ratio by a factor of ca. 25 compared to that of a quadrupole ICP-MS/MS instrument operated under the same conditions with SF6 as the reaction gas. The importance of mass filtering before the collision cell for in situ Sr ratio measurements was highlighted; without this feature, the measured 87Sr/86Sr ratios were inaccurate. No corrections for atomic or polyatomic isobaric interferences were necessary when only ions of m/z 82–92 were allowed to enter the collision cell. The greatest benefits of the improved precision occurred for relatively young samples with low 87Rb/86Sr (<30) contents and so offered new opportunities in geochronological studies. Subsequently, replacement of the quadrupole mass filter in this prototype instrument with a new precell mass filter resulted262 in an improvement in abundance sensitivity of more than an order-of-magnitude. This new setup was capable of producing a stable and flat transmission window between m/z 82 and 94, a vital prerequisite for in situ LA-MC-ICP-MS/MS Rb–Sr dating.

In studies of other geochronometers, a fully automated system was developed263 for in situ measurements of K–Ar ages. The automated prototype consisted of a laser system, an optical spectrometer, a vacuum line, a noble gas mass spectrometer and control software and was designed to date many samples at low cost and with a precision suitable for applications in exploration geology. The K content was quantified by LIBS and Ar in gases produced by the laser was measured by noble gas MS. The system was capable of performing 100 K–Ar analyses within 24 h with uncertainties typically below 5% (1 RSD). Data were reported for different reference minerals including biotite, glauconite, phlogopite, sanidine and tektites. In contrast to K–Ar dating, 40Ar/39Ar dating requires samples to be irradiated in order to produce sufficient 39Ar from 39K for accurate age determination while minimising the production of 40Ar and 36Ar. Zhang et al.264 discussed recent advances in analytical technology and the optimisation of irradiation parameters for Ar–Ar dating. A new approach265 to U/Th dating using fs LA-SF-ICP-MS enabled small archaeological carbonate specimens (shells) with low U contents (ng g−1) to be dated. After optimising the LA coupling to improve the U and Th transmission in the mass spectrometer, image processing was performed to identify contaminated and leached areas at the mm scale and to determine a correction for any detrital material incorporated within the shell structure. Measured ages were consistent with those determined by luminescence methods and with the ages of speleothems dated by conventional solution U/Th techniques. In order to resolve the problem of isobaric interferences of 176Lu and 176Yb on 176Hf in the Lu–Hf geochronology of garnets, apatites and xenotime, Simpson et al.266 proposed a LA-ICP-MS/MS method with NH3 as the cell gas. The resulting age uncertainties were as low as ca. 0.5% (95% CI). Although not as precise as the Lu–Hf ages obtained following chemical separation, the rapid analysis combined with high spatial resolution afforded by this technique offered the opportunity for cost-effective reconnaissance campaigns in complex terrains that record many phases of metamorphism.

5.3.3 Inductively coupled plasma mass spectrometry. A tutorial review (136 references) on isotopic measurements by ICP-MS covered267 the use of enriched stable isotopes and the measurement of natural variations in elemental isotopic composition. These two fields of study are often treated separately in the literature even though they share many fundamental principles. The review concentrated on the similarities between both fields and provided detailed information on terminology, mass bias, interferences, measurement precision and RMs. Another review article (129 references) focused268 on challenges and new developments in the measurement of Ca isotope ratios by ICP-MS, SIMS and TIMS. Advancements in purification techniques and the application of collision-cell technology were highlighted together with the need to adopt common RMs to confirm data quality, aid inter-laboratory comparisons, assist method development and improve the usefulness of published Ca isotope datasets.

The considerable research effort focussed 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 diverse, this 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 breakthroughs, as many of the studies provided modest improvements to existing separation procedures or analytical protocols.

Table 11 Methods used for the determination of isotope ratios in geological materials
Isotope Matrix Separation and purification Technique RMs and figures of merit Ref.
B Marine carbonates Modified microsublimation technique using droplet (<70 μL) of carbonate or RM solution MC-ICP-MS Method validated with 3 ERM boric acid RMs, NIST RM 8301 (foram) and a carbonate RM. δ11B long-term reproducibility for NIST 8301 was 14.48 ± 0.18‰ (2SD, n = 11) for B masses of 2.5 and 5 ng 402
C Carbonates Not applicable fs LA-MC-ICP-MS δ 13C reported relative to VPDB and compared with bulk values determined by IRMS for calcite, dolomite, magnesite and siderite samples. External reproducibility <0.45‰ (2SD) 403
Ca Geological materials Chemical purification using DGA resin followed by separation from Sr on Sr Spec resin CC-MC-ICP-MS Normalised to NIST SRM 915b (CaCO3). 100 ng Ca sufficient to obtain precision of <100 ppm (2SD) for δ44Ca/40Ca. Validation using 9 rock RMs with a range of compositions 404
Ca Carbonates, seawater Automated IC with methanesulfonic acid as the eluent MC-ICP-MS Precision of 0.14‰ (2σ, n = 56) for δ44Ca/40Ca. Data reported relative to IAPSO seawater RM 405
Ca, Fe Geological materials Matrix removal on single TODGA resin column MC-ICP-MS, TIMS Procedure validated with USGS RMs AGV-2 (andesite), BCR-2 (basalt) and BHVO-2 (basalt) 406
Cd, Zn Marine carbonates Different chemical cleaning methods assessed. Cd and Zn purified by double-pass AEC on AG-MP1 resin MC-ICP-MS Cd data reported relative to NIST SRM 3108 (Cd solution) and Zn data normalised to JMC Lyon-Zn. Precision (2SE) < 0.05‰ for δ114Cd and <0.02‰ for δ66Zn 407
Cu Geological materials Separation protocol with 2 columns in tandem: (i) Cu-selective resin (Cu separation from matrix elements); (ii) AG50W-X12 resin to purify Cu MC-ICP-MS δ 65Cu long-term precision <0.07‰ (2SD). Protocol validated with 7 USGS RMs and 5 Chinese RMs (GBW series) 408
Cu, Fe, Mo, Ni, Zn Geological materials Multi-step ion-exchange procedure for purification of selected metals from one sample aliquot MC-ICP-MS 5 USGS RMs: basalts (BCR-2, BHVO-2), Fe–Mn nodules (Nod-A1, Nod-P1) and organic-rich shale (SGR-1) for validation 409
Eu Geological materials Two step CEC on AG50WX-8 resin with 2-hydroxyisobutyric acid eluent for complete separation of Gd from Eu MC-ICP-MS Procedure validated using a range of USGS and GSJ rock RMs. Mass bias correction using 147Sm–149Sm or 147Sm–154Sm provided the most accurate and precise Eu ratios 410
Fe Geological materials Modified AEC procedure on AG1-X8 resin with two passes to purify Fe further MC-ICP-MS With double-spiking technique, long-term precision and accuracy <0.02‰ (2SD) for δ56Fe. 5 USGS rock RMs for validation 411
Fe Fe-dominated minerals Samples mounted in epoxy resin LA-MC-ICP-MS Non-matrix-matched calibration achieved by introduction of water vapour mixed with N2 after LA cell. δ56Fe reported relative to IRMM-014 (iron wire). Precision and accuracy <0.10‰ (2SD) 412
Fe Fe-rich minerals No column chromatography; digested samples measured after dilution with 2% HNO3. Comparison with δ56Fe data obtained after column chromatography MC-ICP-MS δ 56Fe reported relative to IRMM-014 (iron wire). Long-term reproducibility for δ56Fe < 0.05‰ (2SD, n = 123) on pyrite. USGS and IGGE rock RMs used to assess accuracy 413
Hf–Lu Columbite-group minerals Chemical separation of Hf from Ta using 2-column procedure: (i) Ln Spec resin to separate Hf, Lu and Ta from matrix; (ii) AEC on AG1-X8 resin to separate Hf from Ta MC-ICP-MS and LA-MC-ICP-MS Normalisation to 178Hf/177Hf = 1.4672 using exponential law in preference to 179Hf/177Hf = 0.7325 for LA technique 414
K Geological RMs Single column CEC with AG50-X8, K recovered with 0.5 M HNO3 eluent MC-ICP-MS Precision of ca. 0.08‰ (2SD) for 41K/39K on NIST SRM 3141a (K solution) using cold plasma technique. Procedure validated using NIST SRM 999c (KCl powder) and six USGS RMs 415
K Geological materials, seawater Two-stage column separation by CEC on AG50W-X12 resin followed by purification on AG50W-X8 resin MC-ICP-MS External reproducibility for 41K/39K of <0.10‰ (2SD) for K solutions of 1 ppm or greater. Five USGS rock RMs used to assess accuracy and data normalised to NIST SRM 3141a (K solution) 416
K Geological and biological RMs Two-stage column separation required for geological materials: CEC on AG50W-X12 followed by purification on AG50W-X8 resin CC-MC-ICP-MS Long-term reproducibility for 41K/39K of <0.07‰ (2SD, n = 12). Wide range of RM types to evaluate performance 417
K Geological RMs K separated from matrix elements by CEC on AG50W-X8 resin using the same elution protocol twice CC-MC-ICP-MS Intermediate precision for 41K/39K of <0.05‰ (2SD). Data reported relative to NIST SRM 3141a (K solution). 9 RMs including 4 USGS rocks to evaluate accuracy 418
K, Mg Geological materials Single column CEC procedure on AG50W-X8 with 0.5 M HNO3 (K) and 1.0 M HNO3 (Mg) as eluents MC-ICP-MS Procedure validated using six USGS RMs 419
Li Geological materials 2-column separation using cation-exchange resin AG50W-X8 SF-ICP-MS Measurement uncertainty (U; k = 2) 1.2‰ on RM IRMM-016 (Li carbonate) and δ7Li values for 19 silicate RMs reported 420
Mg Geological materials Mg purification by single-column CEC using AG 50W-X12 resin in micro-column with 4.0 mm internal diameter MC-ICP-MS Procedure validated using a range of USGS rock RMs. Long-term precision <0.06‰ for δ26Mg 421
Mg Silicate rocks Not applicable fs LA-MC-ICP-MS Data reported relative to DSM-3 (Mg solution, Cambridge University). Validation using USGS and DING glass RMs. Long-term precision (2SD) for δ26Mg was 0.10‰ 422
Mg Low-Mg rocks Three-step chromatographic procedure using a single column containing AG50W-X8 resin MC-ICP-MS Long-term reproducibility for δ26Mg was 0.06‰. Validation using six felsic rock RMs with MgO contents from 0.05 to 0.96 wt% 423
Mo Low-Mo rocks Three column purification procedure using Muromac®1X8 (similar to AG1-X8) anion and AG50W-X8 cation resins MC-ICP-MS δ 98Mo/95Mo external precision <0.06‰ (2SD). Data normalised to NIST SRM 3134 (Mo solution). Data for 43 RMs reported 424
Nd Geological materials Nd purification using single column containing Eichrom TODGA resin MC-ICP-MS SSB with Eu as IS. Method validated using three pure Nd standards and 7 geological RMs. Reproducibility for δ146Nd/144Nd < 0.030‰ (2SD) 425
Nd Fe-rich silicates Single column diglycolamide-based extraction chromatography using DGA resin to isolate Nd in presence of high levels of Fe MC-ICP-MS No significant difference in 143Nd/144Nd precision for two iron-rich RMs (from CRPG France) compared to 5 × 10−6 < 2SE < 10−5 for GSJ RM JNdi-1 (Nd isotope solution) 426
Nd Silicate rocks Modified CEC method to separate REEs using AG50W-X8 resin followed by Nd purification on AG50W-X4 resin with 2-methylactic acid eluent TIMS Precision of ±2–5 ppm for 142Nd/144Nd for BHVO-2 (basalt) 427
Nd Foraminifera Rigorous cleaning protocol prior to dissolution and ion-exchange chromatography on Sr, TRU and LN resins to purify Nd TIMS External reproducibility for 143Nd/144Nd of <90 ppm (2RSD) for 100 pg Nd loads 428
Ni Geological materials Three-step column chemistry: (i) CEC on AG50W-X8 resin; (ii) AEC on AG1-X8 resin; (iii) purification of Ni from Co, Cu and Zn using AG1-X8 resin MC-ICP-MS 60Ni/58Ni in 20 geological RMs measured to validate method. Precision of 0.006–0.084‰ (2SD) for samples containing 100–200 ng Ni 429
Pt Iron meteorites Single-column AEC on AG1-X8 resin; Pt eluted with 13.5 M HNO3 MC-ICP-MS RM IRMM-010 Pt and NIST SRM 129c (high-sulfur steel) doped with RM IRMM-010 (PtS) prior to digestion to mimic S and Pt content of iron meteorites. Typical between-run precision for δ198Pt was 0.06‰ (2SD) 430
Rb Silicate rocks Two column procedure: sample purified in two passes on AG50W-X12 followed by removal of residual K on Sr-Spec resin MC-ICP-MS Data reported relative to NIST SRM 984 (Rb isotopes). Long-term precision <0.05‰ (2SD) for δ87Rb 129
S Sulfates and sulfides SO2 from offline combustion trapped in aqueous BaCl2 and precipitated as BaSO4 after oxidation with H2O2 EA/IRMS IAEA and NIST RMs for validation. Long-term reproducibility and accuracy of δ34S similar to those by direct EA/IRMS 431
Sb Sb minerals Not applicable fs LA-MC-ICP-MS Long-term reproducibility <0.045‰ for in situ δ123Sb values, normalised to NIST SRM 3102a (Sb solution) 432
Sr Geological materials Three-step column procedure using Eichrom Sr resin to: (i) remove Fe; (ii) separate Sr from matrix elements; and (iii) purify Sr TIMS Multidynamic method with fractionation drift correction yielded precisions of 29 ppm for 84Sr/86Sr and 5 ppm for 87Sr/86Sr 433
Sr Limestones Samples subjected to acetic acid extraction before online Sr separation based on CEC with 1M HNO3 as eluent in the presence of 3.8 mM 18-crown-6 HPLC-MC-ICP-MS Method validated using NIST SRM 987 (Sr carbonate) and JCp-1 (Porites coral) RM from GSJ 434
U Carbonates, seawater, U mill tailings Column chemistry based on AG1-X8 or UTEVA resins to separate U from other actinides MC-ICP-MS Estimated LOD for 236U/238U of 2 × 10−10 using new SEM method with retarding potential quadrupole lens. Precision ±4% for 5 fg 236U at a 236U/238U of 1 × 10−8 106
V Marine carbonates Fe coprecipitation plus AEC on AG1-X8 to remove Fe before 4-step chromatographic procedure to separate V from matrix elements MC-ICP-MS Long-term precision <0.14‰ (2SD) for δ51V. Validated using in-house V isotope solution USTC-V and USGS RM COQ-1 (carbonatite) 435
Zn Geological materials Zn purification with two column AEC method using Eichrom AG1-X8 MC-ICP-MS Long-term reproducibility <0.025‰ (2SD) for δ66Zn/64Zn, normalised to JMC-Lyon. Method validated with IRMM-3702 (Zn isotope solution), and basalt RMs from the USGS and GSJ 436
Zn Zn-rich minerals No column chromatography; digested samples diluted in 2% HNO3 prior to analysis. Comparison with Zn isotope data obtained after column chromatography MC-ICP-MS SSB with Cu IS. Long-term precision (2SD, n = 42) of <0.03‰ for δ66Zn and <0.05‰ δ67Zn 437


A case study investigated269 instrumental conditions that govern oxide formation in MC-ICP-MS and how different oxide formation rates affect the measurement error of Nd isotope ratios. The several instrumental setups investigated included wet and dry plasmas, different sample introduction methods, the addition of N2 and various sampler and skimmer cone geometries. The oxide-induced isotopic offsets were mostly associated with the introduction system and cone geometry. A qualitative model was developed to predict the expected isotopic offsets and recommendations were given on how to reduce measurement errors in the determination of Nd isotopic ratios by MC-ICP-MS.

For over 20 years, LA-ICP-MS has been the technique of choice for quantifying the elemental composition of fluid inclusions. However, the resultant short transient signals are difficult to sample representatively with single collector ICP-MS instruments. Laurent et al.270 demonstrated that this issue could be overcome by reducing quadrupole settling times significantly through use of a fast-scanning quadrupole mass spectrometer. This allowed faster cycling through a given element list and therefore better resolution of the signals. Short quadrupole settling times of 0.2 ms allowed the analysis of smaller inclusions (down to 4 μm) than usually targeted to be made for more elements (up to 52 in this study) without impeding the basic instrument performance.

Multielement imaging by LA-ICP-MS for geological and other applications continues to be a study area with significant growth. Tanaka et al.271 improved the spatial resolution of fs LA-ICP-MS images by combining a newly designed small-volume ablation cell (internal volume 4 mL) and in-torch mixing of Ar make-up gas to provide a shorter washout time. In addition, they employed a “shaving ablation” protocol in which the distance between line profiles was smaller than the size of the laser pit. Although this research was conducted on biological samples, the authors felt it could be adapted for geochemical applications. A new, open-source, stand-alone software called Ilaps272 was written in Python and designed for processing LA-ICP-MS data for bulk analysis and imaging. It was planned that future versions of this software would be capable of processing data from other techniques such as LIBS, thereby facilitating the intercomparison of results. In order to obtain a signal of short duration for element imaging using LA-ICP-TOF-MS, Neff et al.273 designed a parallel flow ablation cell to speed up aerosol washout. The two-volume LA cell was based on a tube cell design and included a recess in the cover for an improved gas flow pattern at the ablation site. At a LA sampling frequency of ≥1000 Hz, the system was capable of acquiring a 1 megapixel image in less than 20 min, thereby increasing the sample throughput significantly.

The benefits of the reduction in various polyatomic interferences obtained when using ICP-MS/MS in geological applications have been highlighted in several contributions. Klein et al.188 developed an ICP-MS/MS method for the determination of technologically critical elements such as Ga, Ge, In, Nb, Sc, Ta, Te and REEs in sediment digests using N2O rather than O2 as the reaction gas to eliminate spectral interferences selectively. The LODs were between 0.00023 μg L−1 (Eu) and 0.13 μg L−1 (Te) and, except for Te, the results for RMs were within ±20% of certificate values. In contrast, O2 was employed274 as the reaction gas in an ICP-MS/MS procedure to determine REEs in uranium ore samples. Specific chemical separation procedures were established to remove the uranium matrix before measurement and all the REEs were measured as REE oxides in a mass-shift approach. The method was validated using GSJ RMs JA-2 (andesite), JB-2 (basalt), JR-2 (rhyolite) and USGS RM BCR-2 (Columbia River basalt). The significant suppression of polyatomic interferences resulted in LODs of <1 pg mL−1 for all REEs. Lindahl et al.275 observed large irregular biases during repeated measurements of U isotopic ratios using two identical ICP-MS/MS instruments. The source of these variations was drift in the mass calibration of the two mass filters which was more pronounced for heavier isotopes. Considerable improvement in the precision and accuracy of U isotope ratios was achieved by optimising the hardware settings for the mass filter peak resolution. This resulted in a precision of 0.07% RSD for long-term measurements of 235U/238U. An investigation by Bolea-Fernandez et al.276 on whether the ISs used in mass-shift approaches should also be subjected to a mass-shift or could simply be monitored on-mass revealed differences in the behaviour of atomic ions compared to reaction product ions. However, it was found that these differences could always be attributed to insufficient time for stabilisation within the reaction cell.

Examples of laser ablation split stream analysis applied to geological materials included277 the simultaneous determination of S isotope ratios and the trace element composition of several sulfides and sulfates. Although the smaller sample volume introduced into the quadrupole ICP-MS detector in the LASS setup resulted in lower sensitivity and poorer LODs for trace element determinations than for when LA-ICP-MS was used alone, the measurement precision and accuracy for the S isotope ratios by MC-ICP-MS were not compromised. Obtaining data for both S isotope ratios and element concentrations provided the ability to identify relationships between individual pyrite minerals and their formation histories. Simultaneous determination of Sm–Nd isotope ratios and trace element compositions together with U–Pb ages of titanite were achieved278 by splitting the aerosol from a LA system into two gas streams. One line was connected to a MC-ICP-MS instrument for Sm–Nd isotope analysis while the other was used for trace element analysis and U–Pb dating by SF-ICP-MS. Addition of water vapour to the gas stream after the LA cell improved the MC-ICP-MS sensitivity for Nd by 40% and thereby improved the precision of the Sm–Nd isotopic data. The simultaneous acquisition of these geochemical parameters yielded detailed age information based on complicated mineral growth zoning.

5.3.4 Secondary ion mass spectrometry. As in previous years, several contributions focused on high-precision isotope ratio measurements on various minerals. These included: improved precision for δ37Cl measurements on apatite279 using a FC fitted with a 1012 Ω amplifier to collect 37Cl; δ94Zr measurements on zircon280 with an external precision (2SD) of 0.04–0.7‰; improved precision for U–Pb dating of zircons281 in U-series disequilibrium; Li isotope ratios in garnet282 using specially-developed glass RMs prepared from either natural garnets or oxide and silicate powders; and Pb–Pb and U–Pb dating of Zr-rich minerals283 at sub-μm spatial resolution.

A set of 27 synthetic glasses covering a broad compositional range with respect to six major oxides (Al, Ca, Fe, Mg, Si and Ti) was developed284 to study instrumental mass fractionation (IMF) in O isotope measurements. Data from a single continuous SIMS session confirmed that the chemical composition strongly influenced O isotope matrix effects in silicate glasses and that the cation–oxygen bond strength had a strong influence on the IMF value. An empirical model based on the correlation of six major element oxides with the IMF was proposed as the most reliable of the models examined when correcting for such matrix effects in silicate glasses. Another study reported285 that IMF caused δ18O values in aragonite to increase linearly with increasing Ca content by about 3.4‰. The use of multiple aragonite RMs with compositions that bracket that of the unknown sample was recommended for accurate correction of the O isotopic measurements. A natural aragonite crystal (VS001/1-A) was evaluated as a potential new SIMS RM. Taracsak et al.286 characterised matrix effects found in the S isotope analysis of silicate glasses by SIMS. They made more than 600 S isotope measurements on nine different glasses which contained 500–3400 μg g−1 S with a wide compositional range, including mafic glasses, rhyolite and phonolite. The finding of significant composition-dependent IMF effects in measured S isotope ratios was in stark contrast to previous studies that had assumed or shown these effects to be negligible for S isotope ratio measurements by SIMS. Calibration with multiple well-characterised RMs with a wide compositional range was recommended.

5.3.5 Other techniques. A cutting-edge review by Otter et al.287 (89 references) provided a thorough overview of nanoscale chemical imaging by Photo-induced Force Microscopy (PiFM). This non-destructive technique combines the advantages of atomic force microscopy with IR spectroscopy providing simultaneous acquisition of 3D topographic data and molecular chemical information at high spatial (ca. 5 nm) and spectral (ca. 1 cm−1) resolution. The aim of the review was to introduce this new analytical development to a broader geochemical audience by covering the fundamentals of the technique and presenting its first application to geochemical samples (zoned zircons, high-pressure experimental phases and mother-of-pearl). It was demonstrated that PiFM imaging enabled nanoscale phase identification and complemented nanoscale imaging and elemental characterisation using other geochemical methods such as NanoSIMS, SEM/TEM and APT.

The effectiveness of atom probe tomography (APT) was tested288 for nanoscale characterisation of hydrous phyllosilicate minerals, which are likely to be major constituents of material bought back to Earth by extra-terrestrial missions. Application of this technique to a terrestrial analogue (lizardite) showed that the technique had better resolution than more established imaging techniques so it was possible for it to detect previously unobservable nanominerals and nanostructures within phyllosilicates. It was concluded that APT could be a key tool in the analysis of planetary samples. For example, new SiO-rich nanophases were revealed that provided new insights into the nature of the fluid and reaction pathways. The study also demonstrated that APT could be applied more broadly to other hydrous mineralogies. Cappelli et al.289 investigated the problems of atom loss and inaccurate estimates of stoichiometric composition when applying laser-assisted APT to garnet and spinel. By studying oxygen quantification and issues related to uneven ion desorption and variation in charge state ratios, a better understanding was obtained of how measured and true mineral stoichiometries diverged due to the influence of mineral properties and crystal structure on the atom probe field evaporation process.

A new method for the determination of δ13C and δ18O in carbonates featured290 a fibre-coupled laser-diode device emitting 30 W at 880 nm. The carbonate was decomposed to CO2 which was collected under a controlled atmosphere for offline analysis. A comparison of isotopic data for carbonate zones analysed both by classical methods (micro-drilling followed by acid digestion) and the new laser calcination method gave correlation coefficients of 0.99 for δ13C and 0.96 for δ18O for a range of different mineralogies and isotopic compositions. As well as decreasing the overall analytical time considerably by reducing the number of preparation steps, the new procedure offered the possibility of performing spatially resolved analysis at the mm scale. Fibre-coupled diode lasers are very compact compared to other laser systems so an exciting prospect was that they could be paired with field-deployable CRDS/IRIS optical-mass spectrometers for on-site measurements.

The technique of XRFS has been applied to the analysis of geological materials for many decades, particularly for the determination of major and minor elements. Modern XRFS instruments are capable of measuring the halogen elements, so a review291 (154 references) on the application of XRFS to the determination of Br, Cl, F and I in geological materials was timely. Core scanning systems with a variety of sensors have the potential for automating many aspects of core logging and thereby provide detailed and continuous core data and imaging at an early stage in the processing of data from geological cores. This process was assisted292 by the availability of new software, called Corascope, which merged the outputs from optical line-scan imaging and X-ray radiography with downhole elemental composition to reconstruct the complete sedimentary record from cores scanned in short sections.

The μXRFS technique is rapidly becoming a familiar tool for characterising geological matrices. Sample sizes ranging from thin sections to hand specimens can be analysed and information collected over the whole sample surface to provide chemical, textural and mineralogical information. An application to the quantitative mapping of minerals in a drill core from a gold deposit demonstrated293 that μXRFS maps could provide information on mineralogy, mineral abundances and mineralogical textures not visible with the naked eye. Fast mineralogical and elemental mapping of ore samples from a PGE deposit by LIBS were validated294 by μXRFS. Presentations at recent conferences (e.g. Geoanalysis 2022) have confirmed that there is a desire to capture both mineralogical and chemical compositions of geological materials through the integrated use of a variety of modern geoanalytical tools such as core scanners, μXRFS and LIBS. Maybe the day when mineralogists and analytical geochemists work together in the same laboratory and speak the same technical language is not far away?

6 Abbreviations

1Done dimensional
2Dtwo dimensional
3Dthree dimensional
AASatomic absorption spectrometry
AAEabsorption Ångström exponent
ABarsenobetaine
AECanion exchange chromatography
AESatomic emission spectrometry
AFSatomic fluorescence spectrometry
AMSaccelerator mass spectrometry
ANNartificial neural network
APDCammonium pyrrolidine dithiocarbamate
APGDatmospheric pressure glow discharge
APMatmospheric particulate matter
APSaerodynamic particle sizer
APTatom probe tomography
ASUAtomic Spectrometry Update
ASVanodic stripping voltammetry
BCRCommunity Bureau of Reference (of the Commission of the European Communities)
BGSBritish Geological Survey
C18octadecyl bonded silica
CCcollision cell
CEcapillary electrophoresis
CECcation exchange chromatography
CENEuropean Committee for Standardisation
CFcontinuous flow
CIconfidence interval
COLMcontinuous online leaching method
CPCcondensation particle counter
CPEcloud point extraction
CRDScavity ring-down spectroscopy
CRMcertified reference material
CScontinuum source
CVcold vapour
CVGchemical vapour generation
Cyscysteine
DBDdielectric barrier discharge
DCMdichloromethane
DESdeep eutectic solvent
DGAdiglycolamide
DGTdiffusive gradient in thin films
DLLMEdispersive liquid liquid microextraction
DMAdimethylarsonic acid
DoEdesign of experiments
DOMdissolved organic matter
DPdouble pulse
DPMdiesel particulate matter
ECelemental carbon
EDSenergy dispersive (X-ray) spectrometry
EDXRFSenergy dispersive X-ray fluorescence spectrometry
ELPIelectrical low-pressure impactor
EPMAelectron probe microanalysis
ERMEuropean reference material
ETAASelectrothermal atomic absorption spectrometry
EtHgethylmercury
ETVelectrothermal vaporisation
FAASflame atomic absorption spectrometry
FCFaraday cup
FFFfield flow fractionation
FIflow injection
FTFourier transform
FTIRFourier transform infrared
GCgas chromatography
GDglow discharge
Gd-DOTAgadoterate
GEMgaseous elemental mercury
GOgraphene oxide
GSJGeological Society of Japan
HCLhollow cathode lamp
HERFDhigh energy resolution fluorescence detected
HFSEhigh field strength element
HGhydride generation
HPLChigh performance liquid chromatography
HRhigh resolution
IAEAInternational Atomic Energy Authority
IAPSOInternational Association for the Physical Sciences of the Oceans
ICion chromatography
ICPinductively coupled plasma
ICRion cyclotron resonance
IDisotope dilution
IDAisotope dilution analysis
IGGEInstitute of Geophysical and Geochemical Prospecting, People’s Republic of China
IHSSInternational Humic Substances Society
ILionic liquid
IMFinstrumental mass fractionation
INCTInstitute of Nuclear Chemistry and Technology (Poland)
IPionisation potential
IPGPInstitut de Physique du Globe de Paris
IRinfra-red
IRISinterface region imaging spectrograph
IRMMInstitute for Reference Materials and Measurements
ISinternal standard
JMCJohnson Matthey Company
JRCJoint Research Centre (European Commission, Belgium)
LAlaser ablation
LASSlaser ablation split stream
LCliquid chromatography
LDSAlung deposited surface area
LGCLaboratory of the Government Chemist (UK)
LIBSlaser-induced breakdown spectroscopy
LLEliquid liquid extraction
LLMEliquid liquid microextraction
LODlimit of detection
LOQlimit of quantification
LPEliquid phase extraction
LPMEliquid phase microextraction
MACmass absorption cross section
MADmicrowave-assisted digestion
MAEmicrowave-assisted extraction
MCmulticollector
MDAmineral dust aerosol
MeHgmethyl mercury
MIPmicrowave induced plasma
MOFmetal–organic framework
MPIMax Planck Institute
MRImagnetic resonance imaging
MSmass spectrometry
MS/MStandem mass spectrometry
μXRFSmicro X-ray fluorescence spectrometry
NACISNational Analysis Centre of Iron and Steel, China
NADESnatural deep eutectic solvent
NBSNational Bureau of Standards
NCRMNational Research Centre for Certified Reference Materials, China
NIOSHNational Institute of Occupational Safety and Health
NISTNational Institute of Standards and Technology
NPnanoparticle
NRCCNational Research Council of Canada
NRCGNational Research Centre of Geoanalysis, Beijing
NTIMSnegative thermal ionisation mass spectrometry
NWRINational Water Research Institute
OCorganic carbon
OMorganic matter
OPCoptical particle counter
PCAprincipal component analysis
PCRprincipal component regression
PFAperfluoroalkyl
PGEplatinum group element
PhHgphenyl mercury
PiFMphoto-induced force microscopy
PMparticulate matter
PM1particulate matter (with an aerodynamic diameter of up to 1.0 μm)
PM2.5particulate matter (with an aerodynamic diameter of up to 2.5 μm)
PM4particulate matter (with an aerodynamic diameter of up to 4.0 μm)
PM10particulate matter (with an aerodynamic diameter of up to 10 μm)
PPpolypropylene
ppmpart per million
PTEpotentially toxic element
PTFEpolytetrafluoroethylene
PVGphotochemical vapour generation
pXRFportable X-ray fluorescence
QCquality control
QMSquadrupole mass spectrometry
RCSrespirable crystalline silica
RDDrotating disc dilutor
REErare earth element
rfradio frequency
RMreference material
RPreversed phase
rpmrevolutions per minute
RSDrelative standard deviation
SAXstrong anion exchange
SDstandard deviation
SEstandard error
SEMscanning electron microscopy
SFsector field
SIBSspark-induced breakdown spectroscopy
SIMSsecondary ion mass spectrometry
SMPSscanning mobility particle sizer
S/Nsignal-to-noise ratio
spsingle particle
SPEsolid phase extraction
SPMEsolid-phase microextraction
SRsynchrotron radiation
SRMstandard reference material
SSAsingle scattering albedo
SSBsample standard bracketing
TCtotal carbon
TELtetraethyl lead
TEMtransmission electron microscopy
THFtetrahydrofuran
TIMSthermal ionisation mass spectrometry
TMAHtetramethylammonium hydroxide
TMLtetramethyl lead
TOAthermal optical analysis
TOCtotal organic carbon
TODGA N,N,N′,N′-tetraoctyl diglycolamide
TOFtime-of-flight
TSPtotal suspended particle
TXRFtotal reflection X-ray fluorescence
TXRFStotal reflection X-ray fluorescence spectrometry
UAultrasound-assisted
UAEultrasound-assisted extraction
US EPAUnited States Environmental Protection Agency
USGSUnited States Geological Survey
UTEVAuranium and tetravalent actinides
UVultraviolet
UV-VISultraviolet-visible
VAvortex-assisted
VCDTVienna-Cañon Diablo Troilite
VGvapour generation
VOCvolatile organic carbon
VPDBVienna Peedee Belemnite
VSMOWVienna Standard Mean Ocean Water
WDXRFSwavelength-dispersive X-ray fluorescence spectrometry
WHOWorld Health Organisation
XANESX-ray absorption near edge structure
XRDX-ray diffraction
XRFX-ray fluorescence
XRFSX-ray fluorescence spectrometry

Conflicts of interest

There are no conflicts to declare.

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