DOI:
10.1039/D2SC04314A
(Review Article)
Chem. Sci., 2022,
13, 13978-14007
Recent progress on MOF-based optical sensors for VOC sensing
Received
3rd August 2022
, Accepted 4th October 2022
First published on 5th October 2022
Abstract
The raising apprehension of volatile organic compound (VOC) exposures urges the exploration of advanced monitoring platforms. Metal–organic frameworks (MOFs) provide many attractive features including tailorable porosity, high surface areas, good chemical/thermal stability, and various host–guest interactions, making them appealing candidates for VOC capture and sensing. To comprehensively exploit the potential of MOFs as sensing materials, great efforts have been dedicated to the shaping and patterning of MOFs for next-level device integration. Among different types of sensors (chemiresistive sensors, gravimetric sensors, optical sensors, etc.), MOFs coupled with optical sensors feature distinctive strength. This review summarized the latest advancements in MOF-based optical sensors with a particular focus on VOC sensing. The subject is discussed by different mechanisms: colorimetry, luminescence, and sensors based on optical index modulations. Critical analysis for each system highlighting practical aspects was also deliberated.
1. Introduction
Air pollution has become a growing concern worldwide. Specifically owing to the recent pandemic, the time people spend indoors has escalated, which comes with a higher risk of indoor pollutant exposure. Volatile organic compounds (VOCs) are an entire set of vapour-phase atmospheric organics (excluding CO and CO2) associated with relatively high volatility, due to their high vapour pressures and low boiling points at ambient temperature and pressure. Common species of VOCs include (apolar) alkanes, alkenes, aromatic hydrocarbons, and heteroatom-containing (polar) organic compounds. VOC exposure can cause acute and long-term health issues depending on exposure durations and doses. A direct example is the sick building syndrome, where people in a building experience acute symptoms such as eye, nose, or throat irritations, headaches, fatigue, etc. that disappear after exiting the building. Besides, odours generated by VOCs are capable of inducing psychological negative effects. Long-term chronic exposure to certain VOCs can also cause adverse health impacts including cancers and liver, kidney or central nervous system damage.1 Compounds of major concern include benzene, toluene, xylenes, styrene, acetaldehyde, formaldehyde and naphthalene, which are classified by the European Commission as the priority pollutants to be regulated. Specifically, benzene, formaldehyde, acetaldehyde, and naphthalene are considered carcinogenic.2 Given the possible health risk caused by VOC exposures, it is imperative to monitor the ambient concentrations of VOCs.
Identification of individual components of VOCs in air samples can be achieved in laboratories via analytical methods using gas chromatography (GC) coupled with flame ionization detection (FID), electron capture detection or mass spectrometry (MS).3 However, these laboratory-based instruments are typically bulky in size, time and power-consuming, complex to operate and expensive. Many other types of sensors have therefore become commercially available or established in research for VOC detection to address the aforementioned limitations. Specifically, commercially available techniques include photo-ionization detectors (PIDs), electrochemical cells, metal-oxide-based chemiresistive sensors (MOs), etc. These sensors are generally miniature in size, sensitive to a range of VOCs and have a short response time. However, the main concern for these sensors is cross-sensitivity to multiple gases/vapours simultaneously leading to a lack of selectivity and the fact that their response can be largely perturbed by the interfering species. More advanced sensing platforms are therefore emerging. One solution for circumventing lack of sensitivity is to adopt multiplexing approaches, for example, sensor arrays, also known as e-noses. They combine multiple sensors with smart pattern recognition software for improved sensitivity and selectivity. In some cases, employing sensor arrays can realize individual discrimination of each component in vapour mixtures.4 Coupling MO sensors with porous solids (e.g. zeolites) can also enhance the sensing performance by employing the intrinsic chemical affinity of the porous solids for better selectivity and/or pre-concentrating the selected VOCs for improved sensitivity.5
Metal–organic frameworks (MOFs) are an extensive class of crystalline micro- or meso-porous hybrid materials that have been widely developed and investigated over the past 20 years.6 MOFs are built with metal cation based nodes and organic linkers linked via coordination bonds. A great variety of chemical combinations between metal secondary building units (SBUs) and organic linkers give rise to diverse topologies and extended physical and chemical properties. These remarkable properties often include tailorable porosity, high surface area, chemical/thermal stability, etc.7,8 MOFs are therefore of great interest for multiple applications, such as gas separation,9–12 gas storage,13,14 catalysis15–17 and bio-applications,18–20 among others.
MOFs are also appealing candidates for sensing applications owing to the following reasons: (1) their intrinsic porosity can favour diffusion, absorption, and/or interactions with analyte molecules; (2) they can provide various active sites, for instance open metal coordination sites as well as possible intermolecular coupling between analytes and ligands (hydrogen bonds, π–π interaction, etc.). These sites can consequently favour sensitive and selective binding with the target gas molecules; (3) their tunable pore size can enable the molecular sieving phenomenon, which can also improve selectivity; (4) the host–guest interactions can lead to detectable changes in chemo-physical properties (resistance, mass, magnetism, colour, etc.), in favour of further signal transduction and quantification; (5) the reversible physisorption process assures the reusability of MOFs; in the case of chemisorption, irreversible responses may appear, yet induce higher sensitivity and selectivity.21–25 Abundant research has been conducted applying MOFs to the design of various types of gas/vapour sensors, including chemiresistive sensors, capacitive sensors, gravimetric sensors, and optical sensors.23,26–33 Among these categories, colorimetric and optical sensors are highly attractive due to their apparent advantages such as immunity to electromagnetic interferences, capabilities of remote sensing, facile operations, and direct naked-eye detection.
The sensing process generally involves selective adsorption of targeted molecules. MOFs feature attractive aspects for gas adsorption and capture, especially for VOCs. Functionalization of organic ligands is a powerful approach to not only systematically tailor the pore size and aperture of the MOF structure,34 but also modify the chemical properties of MOFs including hydrophilicity and hydrophobicity, leading to desired sorption properties. It is also possible to combine multiple species of organic linkers in one framework, namely multivariate (MTV)-MOFs. Such a structure is proven to provide a more complex pore environment and exhibit better sorption and separation performance.35 Besides, defects in MOFs are a unique element to tune the adsorption properties. Missing nodes and missing linkers are the two defects that are mainly observed. The formation of defects in MOFs can change the pore size, rigidity, flexibility and density of the framework. Specifically, missing linker defects lead to more open metal sites, which can favour sorption processes.36 However, increasing the number of defects in MOF crystals can possibly compromise their chemical stability.
This review summarizes the recent progress of MOF-based optical sensors, with specific highlights for VOC sensing. We will first outline the state of the art in the patterning techniques of MOFs that facilitate the integration of MOFs into different platforms. The next parts focus on the latest advancements of MOF-based optical sensors, which are categorized by sensing mechanisms: colorimetric sensing, luminescent sensing and sensing based on optical index modulation. In particular, the section on optical-index-based sensors describes the development of MOFs incorporated with Fabry–Perot interferometers, Bragg stacks, diffraction grafting, colloidal film engineering, optical fibres, micro-ring resonators, surface resonance and surface-enhanced Raman scattering. Finally, we conclude by highlighting the opportunities and challenges of MOF-based optical sensors with critical insight for their further practical applications.
2. Patterning techniques of MOF thin films
In order to exploit the great potential of MOFs for sensing applications, it is vital to integrate MOFs onto substrates for further real device construction. To date, diverse techniques have been addressed to fabricate MOF films with various substrates, including in situ direct growth from hydro/solvothermal synthesis,37,38 electrochemical deposition,39 colloidal deposition via spin/dip coating,40,41 atomic layer deposition42–44 and layer-by-layer epitaxy.45–47 Each method has its attributes for producing films with different thicknesses, preferred orientation, morphology and mechanical properties. Numerous reviews have been written on this topic, covering various aspects ranging from general fundamentals to advanced practical implementations of MOF films.48–58 In the following, we describe the most investigated methods for MOF film preparation.
2.1
In situ growth
In situ direct growth is one of the most straightforward methods where the substrate is placed in the reacting solution and film growth happens simultaneously during the synthesis. The choice of substrate is critical for this approach despite its ostensible simplicity. Indeed, the surface structure and chemical composition of the substrate influence the nucleation, anchoring and adhesion processes of the MOF particles. For example, some metal oxide surfaces with basicity can form strong covalent bonds with the complexing groups from acidic linkers (carboxylates, phosphonates…), accordingly anchoring the MOF. On the other hand, naturally acidic surfaces such as silica (SiO2) do not favour the growth of most carboxylate MOFs.59 Metal pieces37,60,61 and polymers62 have also been employed as substrates for successful MOF film installation. The thickness of these films is typically related to the reaction time and falls within the range of a few micrometers.48 However, control of polymorphism can be complicated and conditions may vary for different MOFs for in situ grown films.63,64
Self-assembled monolayers (SAMs) are active molecules attached to the surface of substrates.65 Tail functional groups (e.g. carboxylic acid) on a SAM can be used to coordinate metal centres or SBUs from the mother solution, therefore promoting the nucleation and growth of MOFs.66 Deploying SAMs can also lead to patterning MOF films via micro-patterning techniques,67 which will be discussed in the next section. Various MOF films have been developed on SAM functionalized substrates (Au, SiO2, Si, FTO, etc.).38,59,68–71 Noticeably, exchanging functionality of the SAM layer can consequently in some cases impact the nature of the MOF that is formed61 and/or tune the orientation of formed crystals.51,59,72 One major disadvantage of this approach is the compatibility between the high reaction temperature for hydro/solvothermal MOF synthesis and temperature-sensitive substrates. However, some MOF films can be grown at room temperature under certain conditions.71–73 In addition, the complex preparation process and limited control over morphology and defects of the films can still be problematic.48
2.2 Liquid phase epitaxy
Unlike one-pot direct growth of MOF films, liquid phase epitaxy (LPE) alternatively grows MOF films layer by layer through immersing substrates into separated solutions of the metal cation precursor and the ligand in a stepwise manner.57 Epitaxially grown MOF films are also defined as surface-mounted MOFs (SURMOFs), which consist of highly oriented ultrathin MOF multilayers instead of crystalline grains. SURMOF growth is generally conducted from room temperature to 60 °C in ethanol, which are milder conditions than the usual ones used for in situ growth.45 These films tend to be very smooth with a roughness at the molecular level. The thickness and crystallite domain size can be precisely controlled by considering an ideal layer-by-layer growth mechanism.48 Despite unlimited choices of organic linkers for SURMOF construction, the metal nodes are to date mainly limited to divalent metals, as mild synthetic conditions are required for SURMOF growth.74
SAM substrates are broadly employed in this approach to initiate the nucleation of highly oriented SURMOFs. Similar to in situ growth, different functional groups on SAMs also affect the growth orientation of SURMOFs. Likewise, tuning the density of functional groups alters the preferential orientations.74 Arranging SAM functional groups with certain patterns prior to SURMOF growth can strategically template well-defined, patterned films. Li et al. reported ZIF-8 film patterning by arrangement of 1-octadecanethiol(ODT)/16-mercaptohexadecanoic acid (MHA) groups with micro-contact printing on gold substrates.75 The selective growth of ZIF-8 on the ODT SAM surface leads to a dot patterning of the film. By switching the solvent from water to methanol, ZIF-8 only nucleated on the MHA surface and produced a negative pattern. Several research groups have also demonstrated combining LPE methods with microprint contact techniques,75 lithography76 and spray coating77 to pattern the films.74
It is also possible to couple the Langmuir–Blodgett (LB) technique with layer-by-layer deposition for fabricating MOFs with a paddle-wheel unit, where 2D nanosheets are first synthesized via air–liquid interfacial synthesis, followed by introducing pillar linkers for interlayer connection (Fig. 1a).78 Extensions of this layer-by-layer strategy also include forming films of multivariate MOFs (MTV-MOFs) and MOFs on MOF structures.79 Another similar approach named substrate-seeded heteroepitaxy uses metal substrates as direct metal sources matching unit-cells for perfect growth. Falcaro et al. fabricated a oriented polycrystalline Cu2(BDC)2 thin film on Cu(OH)2 nanotubes using this strategy.80 However, it should be noted that only limited MOFs with certain topologies (e.g. paddle-wheel structures) can be constructed by the aforementioned approach. The lengthy synthesis and time-consuming step-by-step process should also be considered. In addition, some MOF synthesis requires harsh conditions including acids, heat or specific solvents, which cannot be used for standard LPE or LB procedures.48,50,74 A simpler LB route starting from pre-synthesized MOF nanoparticles for film deposition will be discussed in the following section dealing with colloidal deposition.
|
| Fig. 1 (a) Schematic illustration of the fabrication of NAFS-1 with bottom-up modular assembly by combining a layer-by-layer growth technique with the Langmuir–Blodgett method. Reproduced from ref. 78. (b) Vapour-phase deposition of ZIF-8 thin films via ALD ZnO films. The procedure consists of a metal oxide vapour deposition (step 1) and a consecutive vapour–solid reaction (step 2). Metal, oxygen and ligand sources are labelled as M, O and L, respectively. Metal oxide deposition can be achieved by atomic layer deposition (M, diethylzinc; O, oxygen/water) or by reactive sputtering (M, zinc; O, oxygen plasma). Atom colours: zinc (grey) oxygen (red), nitrogen (light blue) and carbon (dark blue); hydrogen atoms are omitted for clarity. Illustration reproduced from ref. 78.81 | |
2.3 Atomic/molecular layer deposition
Vapour-based processes avoid the use of solvents, which can intrinsically overcome the limitations of liquid-based strategies such as toxicity, difficulty in scale-up, surface-tension involving issues, etc.82 One of the well-established techniques is atomic layer deposition (ALD). It has been widely investigated and applied to producing inorganic nanomembranes (e.g. oxides, nitrides, elementary metals).83 Combining ALD with molecular layer deposition (MLD), which is often used with organic molecules can lead to the fabrication of crystalline MOF thin films.42,43,84 A typical ALD/MLD process consists of layer-by-layer deposition of a metal precursor and an organic linker vapour, with purges of inert gases in between depositing the upcoming layer. The construction of the MOF films occurs through a vapour–solid reaction, where the choice of the metal precursor, the linker exposure time, temperature and humidity require precise control.82,84 Film thickness can be carefully controlled down to the nanoscale. However, the directly deposited film is amorphous in most cases, but it can be crystallized by post-treatments, for instance, annealing under humid conditions,43 or subsequent exposure to acid.44,85 This post-crystallization process consequently changes the morphology and roughness of the film, which counteracts the targeted precise thickness control.
To avoid post-deposition treatments, Ameloot et al. fabricated a uniform and compact ZIF-8 film through a vapour-phase transformation from ALD ZnO films to ZIF-8, as shown in Fig. 1b.81 A recent review by Su et al.82 is suggested for further insight regarding this strategy. The solvent-free strategy makes ALD/MLD appealing to the microelectronics industry,86 as it can lead to a meticulous tuning of thickness and possesses good potential for scale-up. However, this approach is employable almost only for ZIF materials that are easy to produce but possess limited chemical stability. In addition, the large differences in the unit cell parameters between the initial oxide substrates and the MOF might induce the formation of polymorphs and affect the quality of the films. Besides, the necessity of post-synthetic treatments, requirement of high processing temperature and high cost may impede the practical implementation of this method.87
2.4 Colloidal deposition
Another easier option for MOF film fabrication is to use colloidal deposition of pre-formed MOF nanoparticles on a substrate. This strategy requires colloidal-stable suspensions of MOF nanocrystals prior to deposition, where MOFs are dispersed in volatile dispersants. Commonly employed techniques include spin coating, dip coating, spray coating and Langmuir Blodgett deposition.86 The choice of MOF candidates that can be adopted via this approach are with less limitations, even including high-valence metal based MOFs such as MIL-101(Cr), MIL-96(Al) and UiO-66.88–92 The quality of the resulting films highly depends on the homogeneity of the MOF suspension, where the choice of the dispersant and surfactant can be crucial.89,90 In this strategy, the MOF suspensions are deposited onto flat substrates, after which solvent evaporates leading to uniform and polycrystalline films. In a recent study, Rauf et al. reported a homogenous coating of MIL-96(Al) monolayer thin films onto conductive and insulating polymer threads, evidencing the applicability of this approach to a wide choice of substrates.91 The deposited films possess the hierarchical microporosity from the MOF and additional meso- to macro-porosity from assembled MOF particles.40 Moreover, the film thickness is often controllable by tuning the particle size of deployed MOFs, the concentration and viscosity of the MOF suspension, as well as deposition parameters (e.g. withdraw speed in the case of dip coating).21
This approach is easy to operate and cost-efficient. It can be adapted to a broad range of MOFs, as well as combined with other film fabricating processes (e.g. CVD).92 The roughness and orientation of MOF crystals yet remain uncontrolled and depend on the polydispersity and size of the starting nanoparticles. The density of the film also depends on the kinetics of deposition that controls the packing density of the nanoparticles on the substrate. In addition, the adhesion strength between substrates and MOF colloidal films can be weak, leading to insubstantial mechanical strength.40 A feasible strategy to reinforce the mechanical strength of MOF colloidal films is by incorporating additives, such as inorganic binders or polymers,93,94 or via functionalizing the substrates.87
3. MOF-based optical sensors for VOC sensing
Optical sensors are driven by light–matter interaction in the forms of light absorption, emission, reflection, refraction, scattering or transmission. They are usually composed of a light source, a sensing material that can interact with the analytes and a light detector. The spectrum of commonly employed light sources covers from the UV region to the visible region. Depending on specific techniques, detectable parameters include refractive indices, scattering, absorbance and luminescence, which are typically guest molecule dependent.95 The sensitivity and limit of detection (LoD), therefore, can be interpreted and quantified by the change in the detected parameters induced by analyte exposure. To be specific, the response of colorimetric sensors is defined as changes in color, while luminescent sensing materials are evaluated according to their luminescence intensity or position change upon stimulation. For optical-index-dependent sensors, their sensitivity is defined by the changes in the monitored indices, e.g. peak shift in reflectance/transmission spectra. This section will focus on the different platforms that enable MOF-based optical sensing, especially highlighting their application for VOC detection. Table 1 summarizes the recent MOF-based sensors and their performance based on different sensing mechanisms for VOC sensing.
Table 1 MOF-based sensing for VOCs categorized by different mechanisms
Sensing mechanism |
MOF |
Sensing parameters |
VOCs |
Response time |
LoD |
Ref. |
Colorimetric |
Co3[Co(CN)6]2 |
Co2+ |
Ethanol |
1 min |
50 to 500 ppm |
96
|
{[Ni(pzt)2(H2O)2](H2O)(DMF)}n |
Ni2+ |
Primary amine and methanol |
20 min to 50 min |
— |
97
|
[Cu(HL)(DMSO)·(MeOH)]n |
Cu2+ and the phosphonate group |
DMSO; methanol |
39 h |
— |
98
|
CuI-1-benzimidazolyl-3,5-bis(4-pyridyl)benzene |
Ligand-involved charge transfer process |
Aliphatic VOCs |
20 min to 2.5 h |
1 ppm (alcohols); 10 ppm (CH2Cl2, CHCl3) |
99
|
UiO-67-dmbpy |
Ligand-involved charge transfer process |
Alkylamines |
Immediate response |
— |
100
|
UiO-67-bpy-A |
Covalent condensation with amino groups |
Formaldehyde |
3 h |
3 ppm |
101
|
[Zn7(bpybc)3(o-BDC)6]·2NO3·6H2O |
Radical generation of the viologen ligand |
Dimethylamine (DMA) |
Immediate response |
30% DMA aqueous solution |
102
|
Ethylamine (EA); propylamine (PA) |
Immediate response |
— |
Butylamine; benzylamine |
∼10 s |
— |
[Cd2(ipbp)2(NO3)2]·2DMF |
Synergistic effects of host–guest interactions |
Dimethylamine |
2 min |
400 ppm |
103
|
TMU-34 |
Ligand oxidation |
Chloroform |
10 s |
3 ppm |
104
|
{[Zn(3-DPMNI)0.5(NDC)]·3DMF} |
Host–guest electron transfer |
n-Butylamine |
2 s |
300 ppm |
105
|
[FeII(BPI)(HBPI)(ClO4)2] ⊆ MFU-4l(Zn) |
Spin-crossover complex |
Alcohols |
— |
— |
106
|
Luminescence |
NKU-128 |
Chromophore grafting |
Toluene; THF; DMF; DMSO |
24h |
— |
107
|
[Cu4I4(Py3P)2]n (Py3P = tris(2-pyridyl)phosphine) |
Guest-lock-induced luminescence |
CH2Cl2 |
<1 s |
Saturated vapours |
108
|
Chlorobenzene |
455 s |
NR∼ccZIF-8 film (NR = nil red) |
Fluorescent dye |
Acetone |
5 min |
60 ppm |
109
|
Toluene |
5 min |
95 ppm |
Fabry–Perot interferometers |
ZIF-8 |
Reflectance |
Acetone |
<2 s |
1000 ppm |
110
|
HKUST-1⊃TiO2 |
Reflectance |
Acetone |
12.2 s |
11.27 ppm |
111
|
Polyhedral ZIF-8 |
Reflectance |
n-Heptane |
∼250 s |
500 ppm |
112
|
Bragg stacks |
TiO2/ZIF-8 |
Reflectance |
Ethanol |
4.5 s |
10% dosage in 0.1 g h−1 flow |
113
|
TiO2/HKUST-1 |
7.7 s |
TiO2/CAU-1-NH2 |
10.1 s |
TiO2/CAU-1 |
Reflectance |
Methanol |
18 s |
— |
114
|
Heptane |
∼5 s |
— |
Diffraction grafting |
Colloidal ZIF-8; ZIF-8/TiO2 |
Refractive index; colour luminance |
Styrene |
— |
57 ppm |
115
|
MIL-100(Cr) |
First order diffraction intensity |
Toluene |
— |
200 ppm |
116
|
Optical fibres |
ZIF-8/SiO2 waveguide |
Transmission spectra |
Ethanol |
— |
1.6 ppm |
117
|
ZIF-8/graphene oxide |
Transmission spectra |
Ethanol |
118 ms |
5.26 ppm |
118
|
Long-period grafted (LPG) optical fibre |
ZIF-8 |
Transmission spectra |
Ethanol |
— |
9.8 ppm |
119
|
Micro-ring resonators |
ZIF-8 |
Transmission spectra |
Methanol |
∼30 min |
58 ppb |
29
|
Propylene |
29 ppb |
Benzene |
35 ppb |
Toluene |
76 ppb |
Styrene |
99 ppb |
Surface plasmon resonance |
ZIF-8 |
Refractive index |
Methanol |
30 s |
2.5 ppm |
120
|
ZIF-93 |
n-BuOH |
73 ppm |
Surface plasmon polariton (SPP) resonance |
ZIF-8 |
Surface plasmon polariton shift |
Methanol |
— |
0.5 ppm in dry N2; 8 ppm in 40% humidity |
121
|
Toluene |
90–100 ppb |
Surface-enhanced Raman scattering |
Ag nanotubes@ZIF-8 |
SERS spectra |
Toluene |
80 s |
200 ppm |
122
|
Au@Ag@ZIF-8 |
SERS spectra |
Dimethyl methylphosphonate (DMMP) |
30 s |
0.2 ppbV |
123
|
Ag@ZIF-8 |
SERS spectra |
4-Methanylbenzenethiol (4-MBT) |
10 s |
50 ppb |
124
|
MIL-100(Fe) |
SERS spectra |
Toluene |
— |
0.48 ppb |
27
|
3.1 MOF-based colorimetric sensing
Colorimetry is one of the oldest analytical techniques for its straightforward visualization of results95 that is broadly applied in current life, e.g. pH scales. The phenomenon of chromism originates from interactions between a responsive centre and a triggering analyte. The range involving intermolecular interactions can go from the weakest van der Waals interactions to bond formation and ligand coordination. The main mechanisms of MOF-based chromism sensing include coordination geometry of transition metal triggered colour change, ligand-based charge transfer and functional MOF-composite based sensing (Fig. 2).
|
| Fig. 2 Illustration of chromism-based sensing mechanisms of MOFs, adapted from ref. 24. | |
3.1.1 Transition metals.
MOFs composed of transition metal ions (Fe, Co, Cu, etc.) can change colour upon the sorption of guest molecules. In particular, guest molecules interacting with unsaturated metal sites modify the coordination geometry of the metal ions, thus changing their electronic properties, which eventually afford a detectable change in the optical absorption spectrum of the MOF.24,125 For example, Chen et al. reported a reversible structure transformation of a cobalt-based MOF accompanied by colour change upon H2O or NH3 sorption in the liquid phase. The presence of H2O/NH3 molecules changes the coordination number of Co2+ ions from 4 to 6 and consequently the geometry from tetrahedral to octahedral, leading to a colour change from blue to red.125
This principle can also be applied for VOC sensing. Dzesse et al. have reported preliminary results of solvatochromic behaviour with a transition metal-based MOF by soaking it in different solvents. The MOF, built with Co2+ and 3-(4-pyridyl)benzoate, presents solvatochromism upon sorption of various VOCs including polar protic ethanol and methanol, polar aprotic acetone, DMF, DMA, DMSO and nonpolar aprotic dioxane (colours are shown in Fig. 3a).126 In this case, the solvatochromic response is accompanied by a phase transition. In addition, a Mn-MOF showing solvatochromic behaviour toward ketone molecules was investigated by Li et al., where the introduced ketone molecules distort the parent framework and brought changes in d–d transition into the visible region.127
|
| Fig. 3 (a) Coordination environment of Co(II), packing of {[Co(3,4pba)2-(H2O)]·1/2DMF·H2O}n; and pictures of powdered samples after exposure to different solvents. Figures adapted from ref. 126. (b) Structure of Co3[Co(CN)6]2 and TEM image of the nanoparticles; the colour of Co3[Co(CN)6]2 films changes from pink to purple gradually with an increasing ethanol concentration gradient. Adapted with permission from ref. 96. | |
Vapour-phase VOC induced changes in metal centres have also been achieved. Wang and Chen fabricated a film of Co3[Co(CN)6]2 nanoparticles exhibiting a colorimetric and selective detection of ethanol vapour.96 The prepared Co3[Co(CN)6]2 film undergoes a gradual colour transition from pink to purple when subjected to different concentrations of ethanol vapour (Fig. 3b). Such a colour change was not observed with other solvents (H2O, methanol, formaldehyde, etc.), evidencing the selectivity of the sensor. The detection range of the sensor is from 0.05 mg mL−1 to 0.5 mg mL−1 of ethanol, with a response time of around 1 min and recovery within a few seconds. The vapochromic behaviour can be explained by the conversion of Co2+ ion coordination geometry from octahedral to tetrahedral after ethanol molecules entered the pores and coordinated to Co2+ ions. Consequently, the resulting tetrahedral geometry induces a reduction in the d-orbital splitting energy resulting in a redshift in the adsorption spectrum and the colour change of Co3[Co(CN)6]2. In another example, Tunsrichon and co-workers introduced a Ni-viologen based 2D MOF {[Ni(pzt)2(H2O)2](H2O)(DMF)}n (Hpzt = 5-(3-pyridyl)-1,3,4-oxadiazole-2-thiol) with naked-eye chromism in the presence of primary amines and methanol vapours.97 Upon exposure to NH3, methylamine, ethylamine and ethylenediamine, the intrinsic blue colour changed by replacing coordinated H2O molecules with a strong-field amine through forming Ni–N bonds. Bulkier amine vapours did not induce a chromic response due to higher steric hindrance. However, the vapochromism towards amines is irreversible due to the formation of a more stable coordination compound and to the poor chemical stability of these low valence based MOFs. This material also exhibited a selective detection of methanol vapour over other alcohols with a reversible colour change from blue to pale green. The incorporation of MeOH molecules into the MOF distorts the octahedral geometry of NiII and consequently induces chromism. Vapochromism was also revealed in a single-crystal-to-single-crystal (SC-SC) transformation of a Cu-based MOF.98 For example, the 3D-MOF [Cu(HL)(DMSO)·(MeOH)]n (L = triphosphaazatriangulene) exhibits a structural transformation into a 1D-columnar assembly H3L·0.5[Cu2(OH)4·6H2O]·4H2O under humid conditions accompanied by a yellow to blue-green colour change of the crystals. A reverse 1D-to-3D transformation structure also occurred upon the sorption of DMSO/MeOH vapours.
Crystals containing Pt(II) complexes can also be coloured due to metal-metal-to-ligand charge-transfer (MMLCT) from the Pt–Pt orbital to the π* orbital of the organic ligand. Slight modifications of the complex structure upon external stimuli can induce a significant change in the transition energy of MMLCT, resulting in a colour change. For example, Kato et al. demonstrated novel Pt(II) diamine based crystals with vapochromic behaviour towards H2O and alcohol vapours by switching the structures between an amorphous compound and a porous crystalline network.128,129
3.1.2 Redox-active ligands.
As in the aforementioned (expensive) Pt-based complexes, MOF linkers can also participate as responsive centres towards targeted analytes. Here, the interaction between the guest molecules and the ligands triggers charge transfer processes, accordingly changing the perceived colour of MOFs. For example, a porous CuI-MOF reported by Yu et al. shows naked-eye chromic detection of polar aliphatic VOCs.99 The response time of the MOF upon exposure to saturated VOC vapours at ambient temperature ranges from 20 min to 2.5 h. The colorimetric detection limit for alcohols and ketones is about 5 ppm. Single crystal X-ray diffraction analysis evidenced that the guest species are located inside the pores in hydrogen-bonding interactions with the ligand instead of being coordinated to the Cu ions. The UV-visible diffuse reflectance spectra of the VOC-enclosed MOF displayed a gradually broadened absorption band in the visible region. The colour change can be attributed to an intermolecular electron-transfer transition between the ligand and the encapsulated guests. A follow-up study showed that this CuI-MOF can be a highly selective visual sensor for recognizing C2H2, which was also associated with an intermolecular electron-transfer between the linker and the encapsulated guests.130
MOFs composed of redox-active ligands such as viologens,100–103,131–133 tetrazine derivatives104 and naphthalene diimide105 have shown great potential in colorimetric sensing through charge transfer processes. Viologens are 4,4′-bipyridinium derivatives with a particularly electron-deficient nature. Upon interaction with electron-rich molecules, e.g. NH3 and amines, viologen ligands received electrons from the donors and produced radicals, leading to colour changes.24,134,135 For example, Gao et al. synthesized a naphthalene-diimide-based Zn MOF exhibiting photochromic behavior in the presence of various amine vapors (Fig. 4a and b).105 The nature of its photochromism is from photo-induced electron transfer between the electron-rich guest molecules and electron-deficient MOF. It showed varied colors and response times towards different amine vapors. Specifically for n-butylamine (n-BUA), the MOF changed its color from yellow to red in 2 s. The similar color induced by n-BUA and hydrazine (AH) can be further discriminated by their UV-vis absorption spectra. Yang et al. modified the 2,2′-bipyridyl-5,5′-dicarboxylate ligand (bpydc) of the large pore Zr-MOF UiO-67-bpy into N,N′-dimethyl-2,2′-bipyridinium (dmbpy) through post synthetic N-methylation (Fig. 4c).100 Such modification provides charge-transfer interacting sites for selectively capturing and sensing alkylamines. In this example, the CT interaction between the electron-deficient 2,2′-bipyridinium site and the electron-rich analytes is the driving force for selective molecular recognition and adsorption, as it induces a reversible vapochromism and luminescence quenching. A follow-up study on the same Zr-bpy MOF with N-amination modification showed similar chromism behaviour in the presence of amines.101 Owing to imine condensation, the N-aminated MOF also shows a unique colorimetric response to formaldehyde. Another chromic Zn-MOF constructed from a tris-pyridinium ligand was reported by the same group in 2020.131 The material showed direct colour change towards primary amines (methylamine, ethylamine, etc.) and can also be responsive to methanol and ethanol. The mechanism is proposed to be radical formation through spontaneous/photo-induced guest-to-host electron transfer. In addition, the small and interconnected voids due to the 2- fold interpenetration of the MOF give rise to a size and shape selectivity of the chromic process.
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| Fig. 4 (a) Color change and response time of [Zn(3-DPMNI)0.5(NDC)] (denoted as 1 in the figure and following text), (H2NDC = 2,6-naphthalenedicarboxylic acid and 3-DPMNI = N,N′-bis(3-pyridylmethyl)-1,4,5,8-naphthalene diimide) in the presence of different amine vapors. (b) UV-vis absorption spectra of 1 in the presence of different organic amines. Figures adapted from ref. 105. (c) Structure of N-methylated UiO-67-bpy and its reversible colour change when deposited UiO-67-dmbpy was exposed to amine vapours. n-BUA(in a)/BA(in c) = butylamine, DEA = diethylamine, AH = hydrazine, DIP(in a)/DiPA(in c) = diisopropylamine, TEA = triethylamine, TEOA = triethanolamine, AN = aniline, and EA = ethylamine. Figures adapted from ref. 100. | |
Interpenetrated structures of metal-viologen frameworks can stabilize the reduced radicals of viologen ligands and also create multi-bridges for electron transfers, which eventually brings stable and fast responses to multiple stimuli.102,136 For example, a 7-fold interpenetrated Anderson-like cluster-based Zn(II) MOF [Zn7(bpybc)3(o-BDC)6]·2NO3·6H2O, reported by Li et al., exhibited visible responses to different types of stimuli including soft X-ray, UV-light, heat, electricity and in the presence of some organic amines.102 When exposed to vapours of dimethylamine (DMA), ethylamine (EA), and propylamine (PA), an immediate colour change from the original yellow was observed (pale blue for DEA and purple for EA and PA). Bulkier amines such as butylamine and benzylamine had a prolonged response time of ca. 10 s and in these cases, the colour became brown and green, respectively. Solid-state UV-vis and EPR spectra confirmed the generation of viologen radicals after exposure to amines. Such vapochromism was also observed in MOF-PMMA polymer films and is reversible by introducing HCl vapour onto the amine-exposed samples.
Tetrazine derivatives are another type of ligand that can undergo reversible colorimetric responses through redox reactions. Razavi and co-workers developed a dihydrotetrazine-functionalized pillared MOF [Zn(OBA)(H2DPT)0.5]·DMF (TMU-34) for selective and colorimetric detection of chloroform (CHCl3), where H2DPT is 3,6-di(pyridin-4-yl)-1,4-dihydro-1,2,4,5-tetrazine is the pillar spacer and H2OBA is 4,4′-oxybis(benzoic acid).104 In the presence of CHCl3, a colour change from yellow to pink was observed by the naked eye within 10 s, at the lowest concentration of 2.5 × 10−5 M in both liquid and vapour phases and was regenerated by washing the compound in DMF. In the compound, CHCl3 oxidizes dihydrotetrazine (H2DPT) into tetrazine (DPT), therefore inducing changes in the geometry and functionality of the pillar spacer, leading to a colour change.
3.1.3 MOF composites.
Given the fact that most MOFs are colourless or do not change significantly in colour upon sorption of guests, a rational strategy is to load functional (optically active) guests within the host MOF to achieve visual detection of analytes. Common functional guests include organic dyes (rhodamine, spiropyrans, etc.)137–139 and metal nanoclusters.140–142 These compounds are either grafted on the metal oxoclusters of MOFs, or loaded into their pores through direct adsorption or covalent grafting134,143 For example, Koning and co-workers anchored two carboxylate groups of DTNB (5,5′-di-thio-bis-2-nitrobenzoic acid), a bidentate reactive dye, on the unsaturated inorganic node of the mesoporous Zr tetracarboxylate NU-1000 for degradation and visual detection of the nerve agent VX.143 The octahedral Zr6 oxoclusters catalyze the hydrolysis of VX and DTNB reacts with the thiol group from degraded products providing a bright yellow colour (Fig. 5a). This dual-functional composite also brings higher detection efficiency compared to the separated DTNB/NU-1000 system. A follow-up study reported the grafting of DTNB onto the large pore Zr trimesate MOF-808 immobilized on cotton forming a MOF/fabric composite enabling practical application of VX degradation and detection.144 The cloth is capable of visualizing amounts of VX down to 0.16 μg cm−2, which was more sensitive compared to DTNB@NU-1000 (0.8 μg cm−2). It also displayed an improvement in catalytic performance with rapid conversion within 5 min (Fig. 5a and b). However, most MOF composites involve photochromic or luminescent compounds, which require extra light sources to be applied in naked-eye detection. Limited research reported guest chromophore induced colorimetric sensing, and the majority focused on liquid phase detection of heavy metal ions and organic pollutants.141,145,146
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| Fig. 5 (a) Illustration of DTNB@NU-1000 for degradation and visual detection of the nerve agent VX.143 (b) Two anchoring modes of DTNB in MOF-808 and the proposed mechanism of the colour change of DTNB@MOF-808 upon VX degradation. DTNB@MOF-808 degradation kinetics of VX compared to DTNB@NU-1000 degradation kinetics. Photographs of the MOF-textile composite upon contact with VX.144 (c) Sequential installation strategy for anchoring a SCO complex in a MOF and UV-vis spectra at room temperature of the MOF-SCO composites dispersed in acetone (orange) and EtOH (red) for MIL-100, and dispersed in acetone (orange) and MeOH (red) for MFU-4l.106 | |
Another strategy to achieve colorimetric sensing towards VOCs is through encapsulation of spin-crossover (SCO) complexes into colourless large pore MOFs. As mentioned previously in Section 2, spin-crossover complexes are responsive to external stimuli that are accompanied by a colour change. For example, an Fe(II) complex, [Fe(HB(pz)3)2] was confined in diamagnetic and optically-transparent NH2-MIL-100(Al) and showed a colour change induced by solvent adsorption.147 Despite that a range of polar to non-polar solvents can induce spin switching accompanied by off-white to red colour change, it is a proof-of-concept that SCO-MOF composites have great potential for sensing applications. Some of us have successfully introduced an Fe(III) SCO compound, Fe(sal2trien)NO3, into MIL-100(Al) through an in situ synthesis.148 A spin state switching from the inserted FeIII(sal2trien) cation was observed upon water sorption. Another SCO-MOF system designed by our group was built with [FeII(BPI)(HBPI)(ClO4)2]− anions anchored in MIL-100(Al) and MFU-4l(Zn), which displayed a selective solvatochromism towards alcohols.106 In this work, the FeII SCO complex was anchored on the SBUs of the MOFs via the sequential installation strategy. The coordination environment surrounding Fe(II) can be modulated upon alcohol sorption, which leads to a reversible colour change from orange to red (Fig. 5c). This strategy is currently at the very early stage of research but presents great potential for VOC sensing.
3.2 MOF-based luminescent sensing
Luminescent metal–organic frameworks (LMOFs) have been actively explored and investigated for their potential in biological and chemical sensing applications. We will focus in this part on their application towards VOC sensing.
3.2.1 Origins of luminescence in LMOFs.
The luminescence in LMOFs commonly originates from the following sources: (1) photo-responsive metal SBUs (e.g. lanthanide metal ions and d10 transition metal ions), especially trivalent lanthanide ions display sharp emission spectra with wide emission wavelengths from ultraviolet (UV) to near-infrared (NIR) ranges; (2) ligand-centred emission, where the featured ligand typically has extended π-conjugation. Briefly speaking, upon photoexcitation, fluorescence occurs from the emission of a photon from the lowest singlet state (S1) to the ground state (S0), showing a typical lifetime in the nanosecond range. With a suitable triplet state (T1), an intersystem crossing can take place to populate the T1 state. Subsequently, phosphorescence with a longer lifetime (microsecond to second range) can occur from the photon emission to the ground state (see Fig. 6b). (3) Charge-transfer (CT) based luminescence, which corresponds to the transition from the charge-transfer excited state to the ground state, includes metal-to-metal charge transfer (MMCT), ligand-to-ligand charge transfer (LLCT), metal-to-ligand charge transfer (MLCT) and ligand-to-metal charge transfer (LMCT). (4) Guest-induced emission, by encapsulating luminescent guests such as lanthanide ions, quantum dots, organic dyes, etc. in the pores of MOFs. Several books and reviews have described the origin of luminescence in a detailed way, providing a more comprehensive understanding and interpretation of luminescence in MOFs. For example, Cui et al. described thoroughly the design and construction strategies for luminescent MOFs categorized by the three elementary units: SBUs, linkers, and guests.149 Recently, Wang et al. carefully depicted the energy transfer mechanisms in LMOFs with a main focus on the most recent research development of LMOFs.150 Gutierrez et al. focused on the confinement of luminescent guests in MOFs, where they gave a comprehensive overview of synthetic methodologies, a systematic discussion of characterization methods, followed by a brief tutorial on the host–guest phenomena and potential applications for such hybrid materials.141
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| Fig. 6 (a) Schematic diagram of various origins of luminescence in LMOFs. (b) Illustration of photon emission in ligand-centred luminescence. Adopted from ref. 151. | |
3.2.2 MOF-based luminescent sensing for VOCs.
LMOFs combine the general advantages of MOFs (porosity, tailorability, etc.) with their inherent luminescent properties, making them interesting for sensing applications. The luminescent sensing is essentially based on the host–guest interactions between the analytes molecules and the LMOFs, which gives rise to variations in the luminescent intensity (e.g. turn-on and turn-off effects) or peak positions. Classic sensing mechanisms are photo-induced electron transfer (PET), intermolecular charge transfer (ICT) and Förster energy transfer (FRET).24,152 A detailed description of every sensing mechanism in LMOFs can be found in the reviews by Yan,153 while Cui et al. specifically focused on sensing strategies with potential in practical applications, which include the use of functional sites for selective sensing, turn-on luminescent sensing and self-referencing sensing based on dual-emitting MOFs.149 It is noteworthy that LMOFs also bear limitations such as relatively low sensitivity compared to organic based systems when the sensitivity comes from ligand-to-metal-transfer.
LMOF-based gas/vapour sensing has been extensively investigated and comprehensively reviewed recently.141,149,151,152,154–159 Similar to chromism-based sensing, finely tuning the physical and chemical properties of LMOFs, such as introducing functional groups, tuning the hydrophobicity/hydrophilicity, the Lewis acidity/basicity, or adjusting the steric hindrance effect, can improve selectivity.24,160 Li et al. provided their comprehensive insights on the rational designs of LMOFs as functional chemosensors, along with notable considerations of practical parameters for seeking real-time applicability. They also extensively reviewed the progress of LMOFs as explosive sensors, humidity sensors, gas sensors, ion sensors and VOC sensors.151 Another review published later by the same group highlighted the detection of different types of VOCs, chemical warfare agents and hazardous gases.158 Sensing of environmental pollutants including pesticides, antibiotics, heavy-metal-ions, explosives and VOCs using LMOFs has also been highlighted.152,159 Reviews by Lin et al.156 and Khatua et al.157 also highlighted the advantages of using flexible LMOFs in gas/vapour sensing applications. Recently, Yao et al. grafted a non-planar organic chromophore, 3-TPPA (tri(4-(pyridine-3-yl)phenyl)amine (3-TPPA)), into a 2D flexible MOF, MOF-105, via one-pot synthesis and realized a wide range of emission colour tuning107 (Fig. 7a). The bulk crystal of the free-standing 3-TPPA chromophore exhibited only emission intensity changes at different temperatures. However, the resulting hybrid material emission can be modulated by both temperature and pressure stimuli as well as VOC sorption via positive (solvato-)fluoro–chromism interactions.
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| Fig. 7 (a) Illustration of the organic chromophore 3-TPPA grafted in the dynamic coordination space of a flexible MOF. (b) Wide-range emission colour tuning of a 3-TPPA grafted MOF-105 material.107 (c) Illustration of the guest-induced luminescence enhancement mechanism in the presence of VOCs. (d) Emission spectra of [Cu4I4(Py3P)2]n after incubation for 30 min in various solvent vapours.108 | |
With the rapid growth of LMOF-based sensing, new mechanisms and platforms are also emerging. In 2020, Liu et al. designed and synthesized a rigid Cu(I)-based MOF [Cu4I4(Py3P)2]n (Py3P = tris(2-pyridyl)phosphine) that displayed a guest-induced luminescence enhancement mechanism.108 Upon exposure to chlorinated VOC vapours (CH2Cl2, CHCl3 and C2H4Cl2), a turn-on detection mode was observed with an obvious enhancement of luminescence intensity, compared to other VOC vapour exposures such as benzene, CH3OH, acetone and DMF. The weak host–guest interactions between chloroalkane molecules and the host framework decrease the molecular vibrations inside the MOF, resulting in luminescence enhancement (Fig. 7b). In the same year, the first report on enhanced fluorescence of self-assembled colloidal crystal films was achieved by Olorunyomi et al. They incorporated the fluorescent dye Nil red (NR) into ZIF-8 colloidal crystals, followed by self-assembly of dye-functionalized MOF particles into colloidal crystal films via dip-coating.109 The periodically ordered assembly of NR∼ZIF-8 colloidal crystals (denoted as NR∼ccZIF-8 films) enhanced the fluorescence by 186 fold compared to disordered samples. Furthermore, the NR∼ccZIF-8 films respond to different organic vapours (acetone, methanol, toluene and xylenes) at various concentrations via fluorescent quenching. The highest response was obtained with toluene vapours, whereas the lowest occurred from xylene isomer exposure. The selectivity is evoked from molecular size and shape exclusion, which indicates the importance of porosity in colloidal crystal assemblies for fluorescent sensing.
Despite advancements in LMOFs for sensing applications, further improvements are still required for the practical implementations of LMOFs in sensors: (1) in the aspect of sensing VOCs, the majority of the reported results were examined in the liquid phase, yet the response might differ when the material encounters vapour-phase analytes. (2) The dominant construction strategy of LMOFs relies on either lanthanide metal ions or bulky π-conjugated ligands, which generally are costly and produced on small scales. The typical synthesis of LMOFs highly depends on solvothermal reactions. Thus, scale-up synthesis and stability of LMOFs on a longer time scale still await further examination. (3) The luminescent responses are, mostly, changes in emission intensity and positions, which are currently measurable through laboratory instruments. The signal transduction can therefore not be trivial, and the material needs to be first coupled with electronics with proper shaping processes. (4) Shaping of LMOFs is also an important step toward practical applications, and it calls for further attention, as it is another concern for fabricating a luminescent sensing device. In conclusion, luminescent MOFs for gas/vapour sensing application are still a young and active field with many promising results and several opportunities remain to move LMOFs from lab-scale to real-world applications.
3.3 Sensors based on optical index modulation
3.3.1 Fabry–Perot interferometers.
Interferometry is a technique based on the interaction between waves.161 Fabry–Perot interferometers, also known as etalons, typically utilize the reflections and transmissions between two closely seated parallel reflective surfaces. When the incident light travels in the cavity, multiple reflections occur and the path-length difference between subsequent transmissions results in an interference pattern, as shown in Fig. 8.162 The intensity of the output interference pattern is highly dependent on the distance between the mirrors l. When the distance l equals half of the wavelength of the incident light λ or one of its multiples, a standing wave with the longitudinal mode is created and a maximum transmittance is observed at the detector. The following equation can express this correlation:
where m is the number of half wavelengths inside the cavity and n is the refractive index of the active medium.
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| Fig. 8 Illustration of the working principle of a Fabry–Perot interferometer and a typical Fabry–Perot interference pattern. | |
MOF films can function as the responsive medium of the Fabry–Perot (F–P) cavity. The first proof of concept was described by Lu and Hupp in 2010 for selective sensing of chemical vapours.163 For example, a transparent thin film of ZIF-8 was deposited on an appropriate substrate (glass or silicon) and films with different thicknesses exhibited various colours, which can be attributed to the thickness-dependent optical interference in the visible region. Given that the cavity of ZIF-8 is evacuated and under vacuum (nvac = 1), absorption of guest molecules modifies the bulk refractive index of the MOF, and red-shifts the interference peaks accordingly. In 2016, Chen et al. presented a high-performance etalon composed of hollow ZIF-8 nanoshell arrays and a thin layer of Pt coating, named a hollow MOF nanoshell-based etalon (HMNSE).110 The hollow ZIF-8 arrays function as the dielectric medium in between the reflective Si wafer substrate and the metal layer. The fabrication of the device requires several steps including repetitive in situ growth of ZIF-8 on a monolayer of polystyrene (PS) nanospheres, removal of the PS cores to form the hollow structure of the MOF, followed by sputtering of Pt (Fig. 9a). The interference peak wavelength and accordingly the colour of HMNSE were tuned by varying the size of the ZIF-8 shell. Such construction allows large optical response and distinct colour outputs for selective detection of alcohols, ketones, nitriles, cyclohexane/benzene and xylene isomers in the vapour phase, as well as good repeatability and recyclability. Fig. 9 presents the sensor optical shift upon exposure to saturated acetonitrile vapour (b) and different alcohols (c). This device also exhibits a wide detection range from 1000 to 20000 ppm for acetone vapours with a good correlation between the wavelength shift and the vapour concentration. Zhang et al. have also reported a Fabry–Perot optical sensor based on self-assembled UiO-66 nanocrystals for VOC vapour sensing. They demonstrated that controlling the size and the missing-linker amount in UiO-66 crystals can tune the optical properties of the film, as well as enhance the sensitivity and recovery performance of the sensor.164 Recently, Li et al. encapsulated TiO2 nanoparticles in an HKUST-1 thin film in order to improve the sensitivity and response time of the sensor.111 The HKUST-1⊃TiO2 composite film was fabricated through the layer-by-layer deposition of spray-coated MOF precursor solutions and pre-synthesized TiO2 NP solution alternatively (Fig. 9d). The authors demonstrated that the incorporation of TiO2 NPs increases the optical quality of the film, with narrower reflection bands and more intense reflectance compared to a bare MOF film of similar thickness. Furthermore, TiO2 NPs brought a higher affinity to isopropanol, ethanol and methanol for the HKUST-1-based F–P cavity, which was revealed by a larger redshift of the reflection bands upon vapour exposure. A shorter response time (27.6 s for HKUST-1 vs. 12.6 s for HKUST-1⊃TiO2 to acetone) was also observed with the HKUST-1⊃TiO2 composite due to enhanced H-bonding between TiO2 NPs and the tested oxygen-containing molecules.
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| Fig. 9 (a) Illustration of the experimental procedure used to fabricate a HMNSE. (b) HMNSE with 2 nm Pt coating before and after exposure to saturated acetonitrile vapour at 293 K. The insets show the corresponding optical microphotographs. (c) Optical response of the HMNSE to different alcohols, including methanol, ethanol, 1-propanol, 1-butanol, 1-pentanol, and tert-pentanol.110 (d) Schematic of the liquid phase epitaxy (LPE) method for sequential TiO2-loading in MOF films.111 | |
Colloidal crystals are typically submicron-sized spheres of silica or polymers in an ordered arrangement. The periodic variation of the refractive index in the crystals enables them to reflect light at a specific wavelength, also known as a stopband. Adsorption of guest molecules can shift the stopband due to the changes in their effective refractive indices and/or lattice spacing.165 Based on this strategy, Hupp et al. have shown that coating a thin layer of ZIF-8 on colloidal crystals (CCs) can give rise to a device capable of VOC sensing.165 Li et al. also managed to deposit an ultrathin layer (∼80 nm) of ZIF-8 on monolayer colloidal crystals (MCCs) via the LBL method.166 This sensor can discriminate between different alcohols via the colorimetric response together with shifts in the reflectance peak. Later on, Chen et al. fabricated another optical sensor based on the self-assembly of polyhedral ZIF-8 into MCCs.112 Three polyhedral ZIF-8 particles with different exposed facets were assembled, namely truncated cubic (TC) ZIF-8, truncated rhombic dodecahedral (TRD) ZIF-8, and rhombic dodecahedral (RD) ZIF-8 (Fig. 10a–d). A thin layer of Pt was sputtered on the MOF layer to enhance the output signal, leading to narrower full width at half maxima (FWHM), higher reflectance peaks to valley ratios (p–v ratios) and more vivid colours (Fig. 10e–f). Compared to polycrystalline ZIF-8, RD ZIF-8 MCCs lead to a more controlled crystal orientation and elimination of grain boundaries, resulting in a refined selectivity towards linear olefins (e.g. 1-hexane) over other BTEX species (benzene, toluene, ethylbenzene and xylene). Furthermore, the authors demonstrated that different exposed facets of ZIF-8 can regulate the sensitivity of the sensor via differentiated diffusion (Fig. 10h). Specifically, exposing the (110) facet of ZIF-8 allows a more completed exposure of the six-membered window and consequently realizes the detection of C1–C8 linear alcohols, as well as the colorimetric discrimination of C5–C8 alkanes (Fig. 10g).
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| Fig. 10 (a)–(c) SEM images of ZIF-8 MCCs of different crystal morphologies: TC ZIF-8 (a), TRD ZIF-8 (b) and RD ZIF-8 (c). The insets show schematic representations of the corresponding crystal morphologies. (d) PXRD patterns of ZIF-8 MCCs of different crystal morphologies showing preferential orientations. The insets show schematic representations of the corresponding arrangement of ZIF-8 nanoparticles. From top to bottom: TC ZIF-8, TRD ZIF-8 and RD ZIF-8. (e) and (f) Reflectance spectra of TC ZIF-8 MCCs (e) and TRD ZIF-8 MCCs (f). The insets show the corresponding optical micrographs. (g) Schematics showing the adsorption of C5–C8 linear alcohols on ZIF-8 through (110) and (100) planes. (h) Δλmax of ZIF-8 MCCs of different crystal morphologies in response to C1–C8 linear alcohols: RD ZIF-8 (pink), TRD ZIF-8 (cyan) and TC ZIF-8 (yellow).112 | |
3.3.2 Bragg stacks.
Bragg stacks (BSs), also known as Bragg mirrors or one-dimensional photonic crystals (1D PCs), typically consist of multiple dielectric layers with alternating high- and low refractive indices (RI). The periodic structure enhances the reflections of certain wavelengths because of the diffraction and interferences at every interface.113,167–169 The optical response can often be intrinsically tuned by modifying the incident angles170 and the stack thickness.113,114 Similar to F–P interferometers, the position of the diffraction maxima λmax is at normal incidence and is given by:113,114
where the indices H and L represent the high- and low-RI layer, respectively. In MOF-based BSs, MOFs typically function as the low-RI layers and TiO2 (ref. 113, 114 and 170) or polymers168 are often employed as the high-RI layers. Adsorption of guest molecules varies the refractive index of the MOF layers (nL) and accordingly shifts the reflectance peaks. Selectivity can be achieved via size sieving, pore accessibility and/or host–guest interactions between MOFs and the analytes.
The first MOF-based Bragg stack based on ZIF-8 and TiO2 for ethanol sensing was introduced by Lotsch et al., where ZIF-8 functions as the low-RI layer and TiO2 possesses a high RI.169 Patterning of ZIF/Pt BSs171 and 3D-ordered MOF photonic films172 for sensing application has also been achieved. BSs were also prepared with NH2-MIL-88 for selective sensing of EtOH vapour, benefitting from the selective breathing behaviour of MIL-88.170 Lotsch et al. also assembled an optical sensor array from three TiO2/MOFs BSs (TiO2/ZIF-8, TiO2/HKUST-1, and TiO2/CAU-1-NH2).113 Combining responses from multiple MOF elements with appropriate signal analysis methods (colour image analysis and principal component analysis-PCA) generated analyte-specific fingerprints, which facilitated the single component discrimination of mixed vapours. In another study by the same group, post-synthetic modification (PSM) on either the SBU or the linker of CAU-1(Al) directly on an assembled BS of TiO2/CAU-1 was achieved to precisely tune the sensitivity and selectivity of the active MOF layers.114 De-methoxylation of the SBU increased the pore accessibility and improved the possibility to form hydrogen bonds, while amidification of the linker with hexanoic acid brought hydrophobicity. Both modulations allowed a better distinction among water, alcohols (methanol, ethanol and iso-propanol) and n-heptane vapours. The first Bragg stack composed of NH2-MIL-88B nanoparticles and a functional polymer poly(styrene-acrylic acid) was reported in 2020.168 The polymer and the flexible MOF can both undergo swelling upon BTEX sorption and the associated volume change induces modifications in the thickness and RI of both components. Consequently, the sensitivity of the sensor is boosted with contributions from both parts. The brown-purple film also exhibited a colour variation correlated to the concentration of exposed BTEX vapours. Selective sensing of chlorobenzene has also been achieved using two other strategies: combining MOFs and graphene oxide as the sensing layer173 and MOF metal doping.174
3.3.3 Diffraction grafting and colloidal film engineering.
Engineering colloidal films of MOFs can create photonic structures for sensing applications. For example, Faustini et al. have described a soft-lithographic technique for the fabrication of sub-micrometer 2D photonic structures based on colloidal ZIF-8 or ZIF-8/TiO2 nanocomposites.115 The sensor presented a selective detection of styrene under the interference of humidity, with a LoD of 57 ppm. The signal was transduced by the change in colour luminance, which originated from the MOF refractive index variation upon adsorption of the targeted analytes and can be detected by using integrated cameras in smartphones. The same group also demonstrated an evaporation-directed crack patterning of MIL-101(Cr) colloidal films.116 The crack pattern was promoted during dip-coating deposition, where controlling the evaporation front and the withdrawal speed guided the crack propagation and periodicity differently. The crack arrays acted as diffraction grafting and allowed the detection of toluene down to 200 ppm. Bai et al. introduced a responsive amorphous photonic structure (APS) constructed by the colloidal assembly of spherical/polyhedral ZIF-8 particles on a liquid-permeable substrate.175 The infiltration-assisted Mayer rod coating can customize the colour of the film by controlling the wetting process (see Fig. 11). This photonic structure exhibited a vapour-responsive colour variation, where distinctions among ethanol, methanol, acetone, toluene and DMF can be realized.
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| Fig. 11 Illustration of Mayer rod coating of a MOF amorphous photonic structure (APS). (a) Selective wetting of the hydrophilic area of the substrate during coating with spherical/polyhedral MOF inks; (b) formation of APS patterns of spherical or polyhedral MOF particles after the removal of water; (c) vapour-responsive colour changes of the MOF APS patterns.175 | |
3.3.4 Optical fibres.
Optical fibres are often made of silica or plastic for the core, covered by a cladding layer with a lower refractive index. This structure allows light to propagate along the fibre by total internal reflections (TIRs), where the fibre acts as a waveguide. In such a manner, light can be transmitted over long distances with low loss and immunity to electromagnetic interferences. Optical fibres are commonly employed in telecommunication, but they have also been explored as chemical sensors. Fibre optic interferometry is one of the chemical sensing approaches that makes use of optical fibres and is known for its high sensitivity, but lacks chemical specificity.162 One solution is to combine MOF nanocrystals with optical fibres for improved selectivity. Several MOF-coated optical fibres have been reported to be able to selectively detect CO2 and H2.176–179 Some studies have also explored their potential for VOC sensing. For example, Zhu and coworkers coupled a single crystal of HKUST-1 to the end-face of an optical fibre using epoxy glue for quantitative detection of nitrobenzene (Fig. 12a).180 The sensing mechanism is based on the variation of the refractive index induced by the adsorption of nitrobenzene within the MOF crystal. The quantification was achieved by analysing the shifts of the interference spectra derived from the fibre optic interferometry (Fig. 12b). Cao et al. also developed a methane-sensitive cladding layer by integrating ZIF-8 into a UV-curable polymer.181 The detection limit of 1% methane in nitrogen was achieved by employing the ZIF-8/polymer coating in either single-mode or multi-mode fibres. In another study, Chen et al. realized the on-chip integration of ZIF-8 on the surface of a SiO2 waveguide.117 The fabricated sensor exhibited high sensitivity towards ethanol with a large detection range of 0–1000 ppm and a low detection limit of 1.6 ppm. Recently, Huang et al. fabricated an optical microfibre interferometric VOC sensor based on evanescent field interaction with ZIF-8/graphene oxide nanocoating.118 The surface of the optical fibre was pre-modified with graphene oxide (GO), where multilayers of ZIF-8 were grown subsequently via in situ synthesis (Fig. 12c). The GO layer enhanced the adhesion and homogeneity of ZIF-8 layers due to the large π-conjugated network of GO. The sensor presented an ultrafast response of 118 ms towards ethanol with a LoD of 5.26 ppm, which was attributed to the porous structure of the ZIF-8/GO composite.
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| Fig. 12 (a) Schematic diagram of the HKUST-1 coated optical fibre sensor and an optical microscope image of the sensor. (b) Illustration of a section of the original (blue) and shifted (red) interferograms.180 (c) Schematics of the modification step at the interface of the optical microfibre with a ZIF-8/GO functional layer.118 | |
Long-period grafting (LPG) optical fibres are another well-known type of sensor that relies on the modulation of refractive indices. Typically, a periodic perturbation of the refractive index is present on an LPG fibre, which results in a series of attenuation bands in the transmission spectrum. Each band corresponds to different couplings between the core mode and a particular cladding mode. As such, the exposure of guest vapours induced changes in the refractive index of the cladding that shifted the attenuation band.162,182–184 Hromadka et al. have reported a LPG-based sensor working at a phase-matching turning point presenting a high sensitivity for ethanol and acetone.184,185 In another study, Chiang et al. developed a fibre interferometer with a pair of cascaded LPGs, where ZIF-8 was coated on the surface of the cladding.119 The LPGs enable a co-propagating mode, where the light in the core and the cladding interfere with each other and results in a sharp interference fringe as shown in Fig. 13. Ethanol and methanol showed the largest interfering fringe shifts and greatest RI changes from 1.216 to 1.499 and 1.476, respectively. DFT calculations attributed the distinctive responses toward ethanol and methanol to their different desorption energies from ZIF-8. In a follow-up study, Chiang et al. utilized the same configuration for real-time monitoring of bulkier molecules (e.g. toluene and pyridine) and proved that the adsorption dynamics is greatly linked to molecular geometries and kinetic diameters of the guest molecules.183 Adsorption of toluene on ZIF-8 shifted the outcome interference spectrum by 4.3 nm after 40 min of exposure. However, due to the slow adsorption dynamics and difficulty in desorption, the device is rather suitable for toluene capture than for the sensing application.
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| Fig. 13 (a) Optical power distribution of the fundamental mode (LP01, core mode) and (b) higher-order mode (LP08, cladding mode); (c) near-field image of the LP08 mode pattern obtained with an infrared camera; (d) schematic diagram of the proposed fibre interferometer with cascaded LPFGs. ASE: amplified spontaneous emission light source; OSA: optical spectrum analyzer.119 | |
3.3.5 Micro-ring resonators.
Similar to optical-fibre-based sensors, photonic micro-ring resonators detect the analytes based on evanescent field interaction and consequent changes in the refractive index. However, the waveguides, in that case, are bendable and connected in a closed loop with a light source and a detector. Light in micro-ring resonators is propagated in the fashion of a circulating waveguide mode, which is derived from the total internal reflection of an arced boundary between a high and a low refractive index medium. As a result, the interaction between the sensitive layer and the analytes gives rise to a shift in the resonant wavelength.21,29 Tao et al. exemplified a micro-ring resonator with ZIF-8 coating for detection of multiple VOCs at the ppb level including styrene, toluene, benzene, propylene and methanol.29 The coating of ZIF-8 was achieved by in situ growth followed by chemical etching. In the presence of ZIF-8, the sensitivity of the resonator was enhanced by a factor of up to 1000 for propylene compared to that of a bare resonator. This can be attributed to the preconcentration of the analytes in ZIF-8. In addition, the hydrophobicity of ZIF-8 also made the device much less sensitive to humidity. The LoD ranged from 29 to 99 ppb with a response time of 30 min, which can be suitable for applications requiring high-accuracy.
3.3.6 Surface plasmon resonance.
Surface plasmon resonance (SPR) occurs when incident light stimulates the resonant oscillation of plasmons at the interface between two media with opposite permittivity. When plasmonic metal nanoparticles are involved, the nanoscale dimension confines the oscillation on the particle surface, which is known as localized surface plasmon resonance. Plasmonic nanoparticles, typically Ag, Au and Cu, can interact with light in the visible and near-infrared regions. The presence of analytes at their surface can modify the local RI and results in a shift in the resonance wavelength. MOFs incorporating SPR platforms can amplify the sensor response, therefore extending its applications from biomolecule detection to VOC sensing.186,187
Vanderzande et al. presented a ppm-level detection of alcohol vapours using MOF-functionalized SPR sensors.120 A layer of ZIF-8 or ZIF-93 was deposited as a recognition layer on a gold surface of fibre-optic-based SPR sensors (see Fig. 14a). Upon exposure to several alcohol vapours (MeOH, n-BuOH, etc.), the bare SPR sensor did not exhibit any detectable SPR activity due to the low intrinsic RI of the alcohols. With the assistance of MOF coating, vapours with ppm concentrations were detected. A LoD of 2.5 ppm for methanol was realized by the ZIF-8 coated sensor. ZIF-93 coating presented the highest sensitivity and selectivity towards MeOH at low partial pressure due to its hydrophilicity, whereas ZIF-8 showed high sensitivity to MeOH at high partial pressure because of the molecular clustering effect. Such differences in recognition behaviour can be used for qualitative distinction of the vapour composition. Recently, Ameloot et al. explored surface plasmon polariton (SPP) resonance by incorporating a ZIF-8 thin film via the CVD approach onto an AlOx/Ag layered surface on a glass substrate for methanol detection.121 The sample configuration is illustrated in Fig. 14b. The signal of VOC uptake was transduced into SPP shifts by applying spectroscopic total internal reflection ellipsometry (TIRE). Upon exposure to MeOH vapour, the sensor responded up to 160 nm in the SPP shifts with a LoD lower than 1 ppm (Fig. 14c). A resolution of 10−5 in refractive index units was achieved by optical modelling of measured TIRE/SPP spectra, which outperformed conventional ellipsometric porosimetry.
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| Fig. 14 (a) Schematic representation of an MOF-FO-SPR probe (not at real scale). The probe consists of an optical fibre with a diameter of 400 μm with the inner TECS cladding and the outer protective cladding removed from the end. A gold layer is covered with a MOF which functions as a recognition layer. The atoms in the floating methanol molecules are oxygen (red), carbon (black), and hydrogen (white).120 (b) TIRE/SPP principle and TIRE measurement geometry with the sample layer stacks. (c) The measured SPP peak redshift in methanol compared to dry N2.121 | |
3.3.7 Surface-enhanced Raman scattering.
Surface-enhanced Raman scattering is an ultrasensitive vibrational spectroscopic analytical technique. It is based on the working principle of traditional Raman spectroscopy that identifies and quantifies the analytes with their characteristic vibrational fingerprints. Enhancement of Raman signals is achievable by adopting SERS-active substrates such as plasmonic particles, for instance Au and Ag, which can generate an enhanced electromagnetic field on the surface upon excitations and accordingly amplify the signals. The poor affinity between the plasmonic surface and analytes is often addressed as a problem with SERS platforms. Incorporating MOFs with SERS essentially facilitates the selectivity and sensitivity by preconcentrating the analytes and introducing intermolecular interactions between the framework and guest molecules.188–190
Koh et al. reported a plasmonic nose by encapsulating Ag nanotubes in ZIF-8 (Ag@ZIF-8) for molecular-level recognition of VOCs.122 The combination of Ag and ZIF-8 leads to pre-concentration of analyte molecules and enhancement of the electromagnetic (EM) field at the nanoscale. The ultra-trace SERS detection of VOCs was facilitated by optimizing the thickness of the ZIF-film for maximizing the volume of preconcentrated vapour and tailoring the plasmonic coupling between neighbouring Ag nanotubes to intensify the EM hotspots. The Ag@ZIF-8 plasmonic nose exhibited a SERS response towards multiple vapours including toluene and chloroform. Specifically, it presented unique vibrational features for toluene down to 200 ppm and a linear quantification of toluene in the range from 200 to 2000 ppm. Osterrieth et al. fabricated a core–shell structure of Au nanorods (Au NRs) and Zr-MOFs NU-901 for SERS detection of thiolated analytes.191 NU-901 is composed of eight-connected Zr6 oxoclusters and tetratopic 1,3,5,8-(p-benzoate)pyrene linkers (H4TBAPy). The 1D diamond-shaped channel of NU-901 has the dimension of ca. 12 × 26 Å which allows fast diffusion of relatively large analytes. Au NRs as seeds facilitated the MOF growth at room temperature with a core–shell structure and a yield higher than 99% under optimal conditions. The composite maintained the SERS capability of the Au NRs, allowing the selective adsorption and detection of thiolated polystyrene with SERS spectra. In other examples, Li et al. constructed core–shell HKUST-1@Ag NPs via in situ electrodeposition for SERS detection of polycyclic aromatic hydrocarbons192 and Chen et al. achieved SERS detection for toluene, ethylbenzene, and chlorobenzene by constructing a similar core–shell structure of Au@ZIF-8.193 Another platform of Au@Ag nanorods encapsulated in ZIF-8 was fabricated by Lafuente et al. for chemical warfare agent detection in ambient air.123 Yang et al. also demonstrated a site-selective deposition of ZIF-8 on Au nanobipyramids for SERS detection of toluene and aniline vapours.194 ZIF-8 was selectively grown either at the ends, at the waist, or by forming a core–shell structure on the bipyramids. The formation of the selectively deposited ZIF-8 was confirmed by SEM and TEM images shown in Fig. 15a and b. All three nanostructures presented distinctive Raman peaks of toluene and aniline under the vapour exposure, indicating the occurrence of analyte interactions with the MOF. The end-deposited Au NBP@ZIF-8 presented the strongest Raman signals, which can be explained by the large local electric field at the sharp ends of the Au NBPs.
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| Fig. 15 (a) Schematics of the routes for selective deposition of ZIF-8 on the Au NBPs. (b) TEM images of the Au NBPs, NBP/end-ZIF, NBP/waist-ZIF, and NBP@ZIF nanostructures, respectively.194 (c) Illustration of the setup for stand-off SERS sensing. (d) Stand-off multiplex spectra obtained under outdoor conditions with natural light, for two different mixtures of naphthalene and toluene, with reference to individual naphthalene and toluene SERS spectra. | |
Phan-Quang et al. also realized real-time stand-off SERS spectroscopy with the integration of Ag@ZIF-8 for remote and multiplex detection of airborne molecules.124 The platform was fabricated via drop-casting multiple layers of the solution of a pre-synthesized Ag@ZIF-8 core–shell composite. The formed 3D structure of Ag@ZIF-8 has a thickness of ca. 1.3 μm after 10–15 layers with an interparticle distance of Ag cores of ca. 10 nm, which allows strong plasmonic coupling for intense SERS hotspots. Upon exposure to vapours of the probe molecule 4-methylbenzenethiol (4-MBT), it presented a rapid response of 10 s at 500 ppm and the signals were 6-fold more intense compared to those of the control platforms (the MOF-coated Ag platform and bare Ag nanocubes). Notably, the multilayered structure also brought an appropriate hotspot focal depth to be able to cooperate with the stand-off Raman system. The response of the sensor can therefore be recorded with a detector placed 2–10 m apart with 8-fold less laser power employed (≤55 mW, see Fig. 15c). The Ag@ZIF-8 combined stand-off Raman detection can respond to a minimum of 50 ppb aerosolized 4-MBT and a linear calibration curve can be constructed within the range of 500 ppm to 50 ppb. Outdoor sensing of aerosolized mixtures of (poly)cyclic aromatic hydrocarbons (PAHs), naphthalene and toluene was also realized. The reported platform can elucidate the characteristic vibrational fingerprints of each species within 10 s under the interference of a daylight background (Fig. 15d).
Min et al. also explored a SERS-active sensory array based on MIL-100(Fe) for ultrasensitive and multiplex detection of VOCs.27 The LoD for toluene was 2.5 ppm on a solely MIL-100(Fe) substrate, and depositing gold nanoparticles over MIL-100 greatly amplified the signal with an enhancement factor of up to 1010, which consequently reduced the LoD for toluene to 0.48 ppb. The high-SERS activity of MIL-100(Fe) can be accounted for by a charge transfer enhancement mechanism between the framework and the analytes, which was confirmed by the specific adsorption energy and DFT calculations. Specifically, the aromatic ligand and metal active sites are preferably combined by different molecules (e.g. toluene adsorption via π–π interaction and acetone via Fe–O coordination), providing sensor array properties for multiplex VOC detection. Finally, a MOF-integrated plasmonic surface-enhanced infrared adsorption platform was explored by Mu et al., where ZIF-8 was coated on an Au antenna to realize on-chip sensing of greenhouse gases (CH4 and CO2).195
4. Conclusions and perspectives
This review summarizes recent progress on MOF-based colorimetric sensors with particular highlights on VOC sensing. The versatility of MOFs features their unique chemical and physical properties, drawing extensive research interest in them, especially as chemical sensing materials. The advancement of integrated circuits and miniaturization of electronic devices, combined with the development of MOF film fabrication, has recently allowed the preliminary laboratory demonstrations of practical VOC sensing application of MOFs.
Compared to research on MOF-based electronic sensors, research on MOF-based colorimetric sensors is still in the early stage. Chromism sensing exhibits a straightforward output with an often naked-eye observable colour change. The colorimetric responses highly rely on the design of MOF structures including modifying the coordination geometry of the metal sites in MOFs, using chromophoric ligands and encapsulating functional chromophores. Although many studies have demonstrated sensitive and selective sensing of VOCs using chromic MOFs, the delivered selectivity targets groups of VOCs and often lacks refined selectivity towards individual compounds as well as misses the examination of the materials under environmental conditions. The combination of multiple MOFs to create a sensor array can take advantage of the differentiated affinity of each MOF component and thus, an improved selectivity might be achieved. Besides, the shaping of colorimetric MOFs requires further attention, as it can also strongly influence the sensing performances. The reproducibility of nanoMOF-integrated sensing devices also needs critical recognition as it highly relies on the purity of MOFs, their activation status, and water-stability for consistent long-term performance. Luminescent sensing shares similar characteristics, where the intensity of luminescence is modified by the target analytes. The various choices of building blocks and diverse guest-recognition mechanisms have made luminescent MOFs rapidly evolve for sensing applications. The prominent challenge of luminescent MOFs is, similar to that of colorimetric MOFs, a lack of processability for practical implementations. Specifically, the construction of MOFs as thin films or membranes is starting, yet comprehensive evaluations of their performances including sensitivity, selectivity, response time, stability and recyclability still await further efforts. In addition, evaluating the luminescence change often requires specific instruments, which may pose additional obstacles to their practical applications. Overall, there is still a long journey ahead for chromism- and luminescent-based MOFs to achieve ultra-sensitive VOC sensing, especially for real-world sensing installation. Their limitation of sensitivity comes intrinsically from their sensing mechanisms, and thus colour-based sensors can hardly compete with other techniques such as SERS. Nonetheless, colour-based MOFs for VOC sensing possess their own advantages as they are easy to operate and interpret, not to mention the customizable selectivity provided by desired MOFs. Yet, one needs to note that the unique selective behaviour of MOFs is not a confirmation of outstanding sensing ability. It is also worth investigating and examining promising materials under different circumstances. To summarize, despite the advantage of naked-eye observation, limited studies examined chromic and luminescent MOFs in the presence of VOC vapors and sensing performance was often not systematically investigated. The reported LoD of some chromic or luminescent MOFs falls within the ppm levels and can be varied greatly depending on the chosen MOFs. It is worth mentioning that their sensitivity is sometimes limited by the sensing mechanisms, especially for the ones relying on ligand-to-metal transfer, which are often less sensitive than the organic-based system. Furthermore, considering that the shaping processes are not often developed with these compounds, considerable efforts are still required in order to use these types of MOFs in real devices.
Other optical sensors are based on the change of the optical index induced by the absorbance of analytes on the MOF sensing layer. For such purposes, multiple techniques have integrated MOFs in the form of thin films or photonic crystals into sensing devices. They present great potential in VOC vapour sensing with sensitivity from the ppb to the ppm level. In particular, Fabry–Perot interferometers can efficiently transduce adsorption-induced refractive index change, with sensing performances including sensitivity, selectivity and response time that are highly associated with the sorption features of integrated MOF layers. MOF sorption ability not only depends on their microstructure and intrinsic physico-chemical properties but is also related to the attributes of MOF-film engineering. Reducing the thickness of MOF films can accelerate the mass-transport process of analytes, but at the same time, can damage the optical properties of the sensor by diminishing the magnitude of the RI, leading to undermined performance. Furthermore, the orientation of MOF particles can also impact the optical properties of the film, as highly oriented films can enhance both the selectivity112 and signal intensity for potential colorimetric sensing. Another possible strategy to optimize the signal transduction is the hybridization of MOFs with oxide nanoparticles. One way is to integrate MOF photonic crystals into Bragg stacks with contrasting oxide NPs, which requires size and morphology control during MOF synthesis. The other approach is by encapsulating oxide NPs into MOF films; however, obtaining a uniform and homogenous distribution of NPs is still challenging.
Optical fibres based on RI changes can also encode sensing events into spectra. They are known for their immunity to electromagnetic interference and are generally light weight with small probe heads and high flexibility, which allows highly sensitive and multiplex detection in remote or harsh environments. The MOF coatings in optical fibres act as concentrators to boost the sensitivity (LoD under 10 ppm) and also potentially as sieving layers for enhanced selectivity. However, it is, like the aforementioned others, a technique under preliminary investigation, as only ZIF-8 was coated on the fibres and ethanol was the only tested vapor. Thus, the selectivity of this method must still be explored. The mechanical properties of the MOF coating are key factors for the practical integration of MOFs into optical fibres. In situ growth of MOF films is widely adopted for optical fibre coating. Despite the convenience of this method, it is challenging to precisely control the morphology and defects of the film, as well as not being easily scalable. Besides, mismatching MOFs with weakly adhered optical fibres can cause damage to the MOF coating (e.g. cracks and shedding), thus hindering the performance of the sensor. MOF-polymer-based mixed-matrix membranes might be an alternative solution to tackle such drawbacks, yet a systematic investigation is still required.
SERS is recognized as a highly sensitive and selective technique for quantitative detection of chemicals at trace levels. MOFs have been identified as Raman active substrates and, with appropriate choices of candidates, their enhancement factor can be competitive with classic SERS substrates including noble metal NPs. These MOF-based SERS systems have been actively applied in vapour-phase sensing with promising processes recently. Configuration of core–shell structures between MOFs and plasmonic noble metal NPs is also a popular strategy to improve sensing performances via enhanced substrate-analyte affinity or molecular trapping.
As multiple sensing techniques are involved in this review, it is also important to compare them for their performance and potential in practical applications. The detection and monitoring of VOCs in the real world require sufficient sensitivity of sensors considering the toxicity and exposure limits of VOCs, especially carcinogenic ones including benzene, formaldehyde, toluene, etc. For example, the exposure limit of formaldehyde regulated by the EU is 300 ppb for 8 h of average exposure and 600 ppb for short term exposure (data from the GESTIS database). The LoD of MOF-incorporated colorimetric and luminescent sensing is grouped around the ppm level, as it is mostly preliminary research. Micro-ring resonators, SPP resonance, and SERS can handle ppb-level detection. However, micro-ring resonators with MOF coating and SPP resonance are currently at the proof-of-concept level. Their performance under practical conditions including interfering gases/vapors and humidity needs further examination. At the current stage, SERS can be considered as the platform closest to the actual application for its refined LoD (lowest report value of 0.48 ppb) and fast response time (several seconds). The cost of MOFs is a generally concerning topic when speaking about their real application due to harsh synthetic conditions limiting the production scale and their price. Optimizing MOF synthesis and large-scale production are the two contributing factors that can benefit MOFs' practical use.
The key challenge for MOF-based SERS, as well as for other MOF-integrated proof-of-concept techniques, is to expand the spectrum of MOF candidates. The majority of research on sensing applications employed limited benchmark MOFs such as ZIF-8 or HKUST-1, due to their well-developed facile synthesis and diverse shaping approaches. However, they have drawbacks including poor chemical stability (HKUST-1), insufficient water stability and the narrow pore sizes of ZIF-8(4 Å) that limit their potential for practical usage, especially in large-molecule sensing. Besides, difficulty in functionalization further hinders them by restricting tailorability for desired analytes. Conventional one-pot MOF synthesis generally acquires harsh conditions (e.g. high pressure and temperature), especially for water-stable high-valence MOFs, which makes it complicated to further incorporate with nanoparticles. Thus, developments in the mild-condition synthesis of MOFs are expected to promote a further diverse application, where the potential of MOFs can be fully explored.
Author contributions
Y. S. wrote the manuscript. A. T. and C. S. revised and supervised the manuscript.
Conflicts of interest
There are no conflicts of interest to declare.
Acknowledgements
YS thanks the UptoParis European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement No. 754387.
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