David J.
Ashworth
and
Jonathan A.
Foster
*
Department of Chemistry, The University of Sheffield, Dainton Building, Sheffield, S3 7HF, UK. E-mail: jona.foster@sheffield.ac.uk
First published on 17th August 2018
Metal–organic framework nanosheets (MONs) are emerging as a novel class of two-dimensional materials with a distinct set of design principles, synthetic approaches, characterisation techniques and applications. MONs are free standing, nominally two-dimensional materials formed by the co-ordination of organic ligands to metal ions or clusters. In comparison to other metal–organic and two-dimensional materials, the principles behind their design and synthesis are only just beginning to be understood. Here we seek to bring together recent highlights from this rapidly growing field and attempt to draw out common principles and strategies which we hope will aid the development of this exciting new class of materials. We consider the range of chemistries and different synthetic strategies used to fabricate MONs, the methods employed to characterise them and the applications that have so far been investigated.
Metal–organic materials combine the diversity of organic ligands with the unique properties of metal ions to produce robust materials with well-defined and readily tuneable structures. This approach has been used to create a variety of different metal–organic architectures ranging from discrete complexes, cages, grids, helicates and knots to extended polymers, gels, liquids and liquid crystals.8–12 In particular, there are over 70000 thousand metal–organic frameworks (MOFs) reported in the Cambridge structural database (CSD), many of which have a layered structure.13 A number of well-established coordination motifs exist allowing for a high degree of predictability over the topology of the structures that will form. The modular nature of these materials often allows them to be systematically tuned and modified through reticular substitution of different ligands and metal ions and through post-synthetic modifications. The versatility of metal–organic materials means they have been exploited for applications as diverse as gas-storage,14 water purification,15 catalysis,16 drug-delivery,17 sensing,18 imaging19 and electronics.20
Two-dimensional metal–organic framework nanosheets (MONs) have emerged as the most recent form-factor for metal–organic materials. MONs have been variously described in the literature as metal–organic framework nanosheets,21 two-dimensional MOFs,22 metal–organic layers (MOLs),23 metal–organic graphene analogues (MOGs),24 metal–organic surfaces,25 single-layered MOF based materials (MOFenes),26 metal–organic flakes,27 two-dimensional coordination polymers,28 coordination nanosheets (CONASH),29 organometallic sheets,30,31 and hybrid organic–inorganic nanosheets.32 Whilst there are meaningful distinctions between some of the terms used in these descriptions, in an effort to draw out the commonality in the underlying chemistry, approaches to synthesis, techniques for characterisation and applications envisaged we group them here under a common name.
The term “nanosheet” has been used extensively in the MOF literature and whilst a large number of layered MOFs exist or have been grown on surfaces, in most cases the individual layers will not be stable or cannot be isolated using a given method. However, as with other two-dimensional materials, the ideals of a uniform crystalline material with single unit thickness extended infinitely in the other two dimensions is not often achieved in practice. Here we employ a broad definition which encompasses materials which clearly display ‘nanosheet’-like structure and properties and that, with iterative development, could form free standing single-layers. More specifically, MONs consist of: [1] organic ligands coordinated to metal ions or clusters with continuous connectivity in two-dimensions but only non-covalent interactions in the third dimension; [2] highly anisotropic materials with one dimension approaching monolayer thickness and the others being at least an order of magnitude larger and approximately equal in size; [3] materials which can be isolated in a form with the dimensions outlined above as free standing sheets, not attached to a surface or other scaffold or as layers in a bulk material.
In this critical review we shall describe recent progress in this rapidly developing area and seek to highlight the breadth of approaches taken and draw out informative examples of good practice and recent innovations. We begin in Section 2 by discussing the diverse range of chemistries used to synthesise MONs and attempt to draw-out common design principles. In Section 3 we present different approaches for synthesising MONs, either directly or from their parent layered frameworks. We will then discuss the range of characterisation techniques that have developed for analysing the molecular, nanoscopic and macroscopic structure and properties of MONs in Section 4. In Section 5 we consider the distinct opportunities offered by MONs for use in a wide range of applications before summarising and providing our own perspective on the future of this field in Section 6.
Fig. 1 Schemes showing (a) paddlewheel and (b) M6L6 secondary building units. (c–h) example crystal structures showing diversity of carboxylic acid based linkers and secondary building units used in the synthesis of MONs. Specifically, (c) Zn2(BDC-x2)(DMF)2, where x = O(CH2)3OMe; (d) M(TCPP) where M = Zn, Cu, Cd, Co; (e) [Hf6(μ3-O)4(μ3-OH)4(carboxylate)12]; (f) hcp UiO-67; (g) Mn(DMS)(H2O); (h) lanthanum 1,3,5-benzenetriphosphonate (LBP-II). Adapted with permission from ref. 56, 43, 52, 56, 60, 32 and 65 for images (b–h) respectively. |
Zr and Hf carboxylate clusters have proved popular SBU's for creating robust 3D MOFs but have only recently be used to create 2D MONs. Cao et al. synthesised a series of MONs by combining 3-connected carboxylate ligands, initially benzene-1,3,5-tribenzoate (BTB) moieties, with the Hf4+ cluster [Hf6(μ3-O)4(μ3-OH)4(carboxylate)12] to create an infinite 3,6-connected 2D network with kagome dual (kgd) topology (Fig. 1e).56 The 12-connectivity of the Hf6 cluster violates the geometric requirement of a 2D layer so they used formate to cap six of the connection sites on the cluster, leaving the remaining six in the same plane to connect to the BTB ligands (Fig. 1b). Zhao and coworkers produced analogous layered structures based on BTB with both Hf and Zr M6O4(OH)4 clusters synthesised using a modulated hydrothermal approach,57 and Wang et al. recently demonstrated a continuous flow reaction in order to synthesise the Zr analogue.58 The same Zr6 cluster but with different sites capped was used to create MONs with tetraphenylethylene-based tetracarboxylate (TCBPE),23 as well as TCPP ligands.59 A Hf12 cluster was used by Cliffe et al. who used 4,4-biphenyldicarboxylate (bpdc2−) to form a 3D framework containing a “double cluster” (Hf12O8(OH)14) which they were able to exfoliate through selective scission of the interlayer ligands (Fig. 1f).60 A related double-decker Hf12 clusters has also been used as an SBU with extended tritopic carboxylates.61
Inorganic (I) corner sharing octahedra have also been used alongside coordination bonds (O) to create two-dimensional layers. In the nomenclature defined by Cheetham, Rao and Fuller, superscript numbers are used to define the types of connectivity in different dimensions.34 Cheetham and coworkers combined 2,2-dimethylsuccinate (DMS) and its isomers with different metal ions to produce a series of layered frameworks which they exfoliated to form nanosheets.32,62,63Fig. 1g shows the archetypal I1O1 network for the Mn-DMS network in which distorted MnO6 octahedra form corner-sharing chains along the b-axis which are bridged via DMS ligands to form 2D layers.32,64 The methyl groups of the ligands protrude between the layers providing weakly interacting hydrophobic caps. Other closely related systems had either inorganic (I2O0) or organic connectivity in two dimensions (I0O2) highlighting the challenges associated with predicting structure when using less preorganised ligands. Phosphonic acids can also be used to create inorganic layers. Araki et al. exploit the high coordination numbers of lanthanide ions by coordinating 1,3,5-benzene-triphosphonate to lanthanum ions to form layered MOFs with either (I1O1) or (I2O0) connectivity (Fig. 1h).65
Fig. 2 Example structures of nitrogen (a–d), sulfur (e) and mixed linkers (f–h) used in the synthesis of MONs. Specific repeat structural units are: (a) Zn(bim)(OAc); (b) Zn2(bim)4; (c) Cu(bpy)2(OTf)2, (d) S1(M2+), where M = Zn, Fe, Co, Pd and S1-see reference; (e) Ni3(bis(dithiolene))2; (f) [Cu2Br(IN)2] where IN = isonicotinate; (g) [Zn(Gly-Thr)2]·CH3OH; (h) [Fe(Py2th)2]. Adapted with permission from ref. 67, 68, 74, 76, 80–83 for images (a–h) respectively. |
The neutral N-donor systems, 4,4-bipyridine (bpy), was used to create a layered framework with the formula Cu(bpy)2(OTf)2 in which the trifluoromethanesulfonate (OTf) counterions capped weakly interacting layers (Fig. 2c).74 Atomic force microscopy (AFM) and transmission electron microscopy (TEM) indicate that single and few layer nanosheets are formed which show crumpling and rolling to form nanoscrolls highlighting the flexibility of these systems. A variety of tri- and hexa-dentate terpyridine (tpy) building blocks have also been used to form monolayers through self-assembly at interfaces through coordination to M(II) ions (Zn, Co, Ru, Pb, Ni and Fe) (Fig. 2d).30,52,75–77 These multidentate building blocks provide a high degree of connectivity and robust coordination interactions through their multidentate binding. The often single layered nanosheets which were formed through interfacial assembly can be up to several cm in lateral dimensions and mechanically strong enough to be spanned over 20 × 20 μm sized holes, however the degree of crystallinity can be low.76 A structurally related series of MONs have also been synthesised using tri- or tetra-dipyrinato ligands coordinating to tetrahedral zinc ions.78,79
Rosseinsky and coworkers investigated a peptide based layered MOF [Zn(Gly-Thr)2]·CH3OH which formed single layered nanosheets following exfoliation with ultrasound (Fig. 2g).82 Other examples of MONs incorporating multiple coordination motifs within a single framework include a lamellar iron(II)-pyrimidine-2-thiolate coordination polymer [Fe(Py2th)2]n (Fig. 2h),83 large single layer thick flakes of [Cu(μ-pym2S2)(μ-Cl)]n (pymS2 = dipyrimidindisulfide)27 and lanthanide based MONs formed by the coordination of 2,2-thiodiacetic acid.89 Examples of de-symmetrised MONs with different bonding motifs running in different directions include work by Gao et al. created a zinc based MON with a layered structure consisting of perpendicular chains of carboxylate coordinated ibuprofen and 1,2-bis(4-pyrdiyl)ethane.90 Another interesting de-symmetrised case is a two-dimensional coordination polymer consisting of Cu2I2 chains linked by 2-aminopyrazine.91
Fig. 4 Example AFM (b, d-l) and TEM (a, c) images illustrating MONs synthesized using various bottom-up (a–f) and top-down (g–l) methodologies. Heights of nanosheets across the indicated vectors are approximately: (b) – 3 nm; (d) – 6 and 8 nm (red and blue, respectively), (e) − both 5 nm, (f) – 0.8 nm, (g) – 1.1 nm, (h) – 1.9 nm, (i) – 2 nm, (j) – 4 nm and (l) – 2 nm. Image (g) is 3 μm square, the indicated vector in (i) is 5 μm and the scale bar in (j) is 10 μm. Images adapted with permission from ref. 47, 93, 49, 36, 37, 30, 68, 43, 89, 40, 53 and 94, for images (a–l) respectively. |
Surfactants have been used to modify crystal habit by binding to the surface of the growing nanosheets, inhibiting growth and preventing stacking of the layers. The surfactant species can also decrease the surface energy and so total energy of the system, which favours the formation of the 2D morphology.92 Zhang and coworkers used polyvinylpyrrolidone (PVP) in the synthesis of Zn(TCPP).49 Addition of PVP to the reactant mixture resulted in MONs of 1.2 ± 0.4 μm × 7.6 ± 2.6 nm, corresponding to 8 ± 3 layers thick (Fig. 4c). FTIR investigations of PVP interacting with Zn2+ ions showed a strong interaction of the PVP CO group with Zn2+ ions, suggesting that PVP could attach onto the surface of the nanosheet after nucleation, leading to highly anisotropic growth to form MONs. The generality of this method was demonstrated through the additional synthesis of Cu/Co/Cd(TCPP), in which nanosheets of <10 nm thickness were obtained for all but Co(TCPP). These MONs have been further used for various applications.50–52,55 PVP has also been used within the synthesis of Cu(HBTC) (where BTC = 1,3,5-benzene tricarboxylate) in a reaction which occurred at room temperature and pressure to produce nanosheets between 30–55 nm thick.95 The cationic surfactant CTAB has been suggested to adsorb to specific crystal planes. The hydrophobic tail adsorbing to the crystal surface could aid in MON stabilisation and dispersion in particular solvents. This approach has been used to directly produce Zn(bim)(OAc) MONs down to 7 nm thickness.67,96
Small molecule crystal growth modifiers that bind preferentially to a particular facet of a growing crystal can modify the resulting crystal habit. A classic example of this is the addition of pyridine to the synthesis of the pillared MOF [Cu2(NDC)2(DABCO)] (where NDC = 1,4-naphthalene dicarboxylate and DABCO = 1,4-diazabicyclo[2.2.2]octane) which resulted in the formation of large nanosheets up to 500 nm2 as a result of competition with the pillaring ligands.97 PVP has been used to similar effect to produce highly anisotropic nanosheets of the pillared MOF Co(TCPP)(BiPY).50 It should be noted that these nanosheets are connected in three-dimensions through coordination bonds and therefore do not fulfill our definition of a MON. However, in principle this approach could be used to produce single layers or pillared bilayers which would then have two-dimensional connectivity.
Small molecule addictives can also become incorporated into growing MOFs resulting in the formation of layered structures. Zhao and coworkers exploited acetic acid as a modulator to prevent the formation of interpenetrated networks. This lead to the formation of MONs of 10–20 nm thickness which exhibit stability superior to the analogous 3D MOF (Fig. 4b).93 Lin and coworkers found that the 12-connectivity of Zr6 and Hf6 SBUs could be modified by incorporating six formate ions into the SBU to produce nanosheets with thickness of <4 nm and lateral dimensions >10 μm, with nanosheets observed down to monolayer thickness.23,29,50,61
Wang and coworkers demonstrated a “pseudoassembly disassembly” strategy for the formation of Zr6-(NiTCPP) MONs in high yield (85%) and high dimensional uniformity of around 200 × 1.5 nm.59 Incorporation of controlled concentrations of small monoacid (formic, acetic, lauric and oleic acid) ligands as a modulator into the reaction mixture lead to layered MOFs, within which the monoacids occupied the interlayer coordination sites of the Zr cluster (confirmed by quantitative NMR and SAXRD) which lead to destabilisation and “disassembly” to MONs. Stacking of produced MONs was observed under TEM with lengthening of the aliphatic chain. Rodenas et al. were able to produce a series of nanosheets of 5–25 nm thickness and up to 4 μm square using a “layered synthesis” method (Fig. 4d).36 The ligands and metal ions were dissolved in different ratios of DMF and acetonitrile to produce solutions of different densities which were layered on top of each other, with a buffer layer in between. Slow diffusion of the ligand and metal ions into the buffer layer produced preferential growth in two-dimensions to produce nanosheets, which then sank as a result of gravity into a metal ion deficient layer preventing further growth (Fig. 4e). Inspired by this work, Fu and coworkers developed a spray technique which used ultrasonic atomisation to spray a solution of metal salt onto a reservoir of the ligand solution. This approach reduces the disturbance caused by contact between the layers, providing a steady interface for anisotropic crystal growth. The nanosheets produced through this method were <500 nm and >5 nm thick (Fig. 4e).
An alternative method for directing crystal growth into two-dimensions is the use of phase interfaces such as air–liquid (Fig. 4f, for example)30,45,48,75,76,78,80,98 or liquid–liquid.22,77–79,85,99,100 These methods also generally proceed under ambient conditions. Liquid–gas interfacial growth has been demonstrated using Langmuir–Blodgett troughs, in which a solution of ligand in a volatile solvent is applied on top of the aqueous phase containing metal ions.46,48,75,80,98,101,102 Surface compression can result in large extended nanosheets of potentially infinite size, with domains demonstrated up to sub-mm scale, although questions remain about the crystallinity of these large sheets. Additionally, MON films can also be built up by layer-by-layer deposition of these large MONs. More detailed methodology and examples of nanosheets produced in these ways can be found in a recent review by Nishihara and coworkers.29,103,104
Additionally, there have been multiple demonstrations since 2003 of the growth of MOF layers at solid–liquid interfaces. These materials have been recently reviewed elsewhere,105,106 and the difficulties associated with removing these materials from the surfaces mean we will not cover these approaches in detail here. Another interesting approach that has been explored is the growth of MOFs on other two-dimensional materials such as graphene oxide, although in most cases the MOFs are not themselves two-dimensional.107 Rare examples of the formation of MOF thin films at the vacuum–solid interface by chemical-vapour deposition (CVD) have also been reported,108 but again are outside the focus of this review.
Abhervé et al. mimicked the famous “Scotch tape” method, originally used to isolate graphene nanosheets, to produce MONs with heights down to 2 nm from a layered cationic framework.109 Exfoliation can also be achieved mechanically, either through grinding by hand or with the use of a ball mill. For example, UiO-67 was exfoliated from the bulk MOF to form sheets of ∼10 nm thickness (Fig. 4g).60 This approach produced a relatively broad distribution of particle sizes, in terms of both lateral dimensionality and thickness. Grinding can also cleave chemical bonds, which was utilised by Cliffe et al. to create sheet-like particulates from non-layered MOFs to form nanosheets with a relatively broad distribution of layer thicknesses.60 Wet-ball-milling has been additionally demonstrated in a solvent mixture of MeOH/nPrOH.68 The authors suggest that methanol penetrates into the galleries of the layered MOF, which is facilitated by the ball-milling process, and the nPrOH acts to stabilize the exfoliated nanosheets through adsorbing onto the surface through the alkane tails, fulfilling a similar role as surfactants previously described.
Liquid exfoliation through sonication has perhaps been the most widely adopted method of MOF exfoliation over the past decade. The energy input provided by the ultrasonicator (typically 20–80 kHz, with powers of 80–750 W) can overcome the inter-layer interactions, facilitating solvent penetration, and serve as a stimulus for layer separation. As yet, there has not been a universal set of conditions demonstrated to produce the highest quality and quantity of nanosheets. Various authors have used sonication times from 20 minutes to 24 hours, and although exfoliation through sonication has been shown to achieve better results at lower temperature,110 the temperature of sonication is rarely controlled. Systematically varying centrifugation rates used to collect MONs from suspension can be used to select for different sizes of nanosheet.110 The sonication process breaks bonds within the layers as well as between them resulting in smaller crystallite fragments, and subsequently broader particle size distribution and smaller MON size than bottom-up methodology. This is due to the low elastic modulus (3–7 GPa)27,32 of these crystalline materials, compared to other 2D systems such as monolayer graphene and graphene oxide (1000 ± 100 GPa and 207.6 ± 23.4 GPa respectively).70,72 However, mono- and few-layer nanosheets have been found to be produced through this methodology (Fig. 4h), with lateral dimensions that are comparable to mono/few-layer graphene nanosheets produced from liquid phase graphite exfoliations through sonication, which typically produces nanosheets of below 1 μm size.111,112
Liquid exfoliation has additionally been achieved by simply stirring,113 or shaking a MOF in a solvent (in the presence of surfactant in order to prevent restacking).67 Junggeburth et al. note the effect of shaking in differing solvent systems. Their use of a hydrophobic MOF showed decreasing exfoliation in THF > tol > CHCl3, and poor exfoliation observed when using the polar solvents DMF and H2O. This was suggested to result from an inability of these solvents to efficiently penetrate between the hydrophobic interlayer space. In contrast, Moorthy and coworkers showed that hydrogen bonds between layers of MOF could be overcome by hydrogen-bond-accepting solvents, resulting in spontaneous exfoliation.114 This shows that the selection of an appropriate solvent system for exfoliation may be of paramount importance. A solvent system that works well for one MOF is not generalizable to others as each MOF has widely varying properties depending on its makeup of metal and ligands. Lower energy-input liquid exfoliation techniques may generally be preferred, as these are less likely to fragment the produced nanosheets.
The intercalation of molecular/ionic species between MOF layers in order to increase interlayer distance and induce exfoliation has been demonstrated for the production of MONs. Lithium-ions were intercalated into various layered frameworks by Wang et al. which were shown to undergo complete exfoliation following sonication in water (Fig. 4i). The forced hydration of the lithium ions is thought to push the layers of MOF apart to such an extent that the interlayer interactions are negated.64,89 A freeze–thaw method has been demonstrated by Zhou and coworkers, in which a hexane dispersion of MOF was repeatedly frozen in liquid nitrogen and then thawed at elevated temperature with a temperature differential of 256 °C.40 The authors suggest that a shear force was exerted on the MOF crystals as a result of the volumetric change to the hexane upon gas–liquid phase transition. Bilayer thick nanosheets with a broad distribution of lateral dimensions (10.7 ± 4.8 μm) were produced in 95% yield (Fig. 4j).
The exfoliative techniques discussed so far all rely on the pre-ordered layered 2D structure of MOF, in order to separate layers. However, there is also the potential for chemical modification of the system in order to promote exfoliation. Zhou and coworkers intercalated a pillaring dipyridyl ligand which contained a disulphide bond between layers of a pre-designed layered MOF.53 This increased the interplanar distance from 9.8 to 22.6 Å. Scissoring of the ligand through chemical reduction of the disulphide bond resulted in spontaneous exfoliation upon stirring the reaction media, which resulted in single layer nanosheets with lateral dimensions up to several micrometres (Fig. 4k). An element of control upon the produced nanosheet size was additionally demonstrated through varying the reaction conditions for the disulphide scissor. Huang et al. demonstrated an electrochemical exfoliation of a MOF through oxidation of pillaring 2,3-dihydroxybenzene dicarboxylic acid ligands to cyclopenta-2,4-dienone. This allowed for facile removal of the pillars due to weakened coordination ability from both structural strain and electronic differences between the ligands and reported nanosheets with lateral dimensions 100–200 nm and as little as 2 nm in height.41
In addition, there has been exciting recent work demonstrating solvent induced structural transformations resulting in the formation of nanosheets. Banerjee and coworkers demonstrated a transformative hydrolytic process from metal–organic polyhedra to layered MOF, which resulted in a spontaneous exfoliation to nanosheets of 6–8 layers thick upon addition of larger relative amounts of water.39 Similarly, Gallego et al. found that exposure of bulk layered crystals to excess water induced layer separation down to monolayer thickness, without any additional energetic input (Fig. 4l).94 This is suggested to be due to incorporation of additional solvent molecules within the cavities present in the starting framework.
Fig. 5 (a) XRPD patterns comparing nanosheets with parent MOF showing systematic loss of out of plane reflections; (b) STEM-HAADF image of nanosheet showing lattice spacing and corresponding structural model; (c) XPS data providing evidence on elemental composition of a MON; (d–g) EDXS mapping distribution of elements (C, O, S and Co) within a MON. Images reprinted with permission from ref. 36 (a), ref. 115 (b) and ref. 116 (c–g). |
A diverse range of other techniques have also been used to provide additional information about the structure and composition of the MONs. Solid state nuclear magnetic resonance (NMR) spectroscopy, pair distribution function (PDF) data, thermal gravimetric analysis (TGA), infrared spectroscopy and elemental analysis have been widely used to provide evidence of the composition of MONs, as well as NMR analysis of digested samples.23,60,117 Surface analysis techniques such as X-ray photo spectroscopy (XPS), X-ray fluorescence (XRF) and Ultraviolet Photoelectron Spectroscopy (UPS) also been used to give information about the elemental composition and oxidation states of the nanosheets (Fig. 5c–f).24,79,89,94,116 Density functional theory modelling has also been used alongside experimental data to calculate likely MON structures.60
Fig. 6 (a) AFM images of nanosheets and (below) plot of corresponding size profiles; (b) TEM images of crinkled nanosheets; (c) SEM image of nanosheets grown by layering method and associated (d) FEB-SEM of nanosheets dispersed in a polymer membrane; (e) Brewster angle optical microscopy of nanosheets formed at the liquid–gas interface using Langmuir–Blodgett method; (f) Raman microscopy images of MONs; (g) DLS data showing lateral size distribution of nanosheets in suspension. Images reprinted with permission from ref. 74, 56, 36, 30, 27 and 82 respectively. |
Scanning electron microscopy (SEM) and TEM can provide high resolution images of the nanosheets, giving information about their dimensions and rigidity. The non-conductive and labile nature of most MONs mean they readily suffer electron damage and charging which can make imaging challenging, although many systems have been successfully imaged with high resolution (Fig. 6b and c). A wide variety of advanced electron microscopy techniques have been used to provide additional information about the underlying structure of the MONs. For example, Lin and coworkers used fast Fourier transform and rotation electron diffraction to determine the reciprocal lattice of sub-micron sized nanosheets as well as high resolution TEM and scanning TEM high angle annular dark-field (STEM-HAADF) images to corroborate their structural model (Fig. 5b).23 Selected area electron diffraction (SAED) has also been used to confirm unit-cell measurements.29,32 Energy-dispersive X-ray spectroscopy (EDX) and electron energy-loss spectroscopy (EELS) have been used to map the elemental distribution of the nanosheets.59,67,116 These powerful techniques provide an important route to understanding the nature and position of defects, functional groups and active sites which are often essential to their performance in a range of applications.
SEM can also achieve good resolution and can be useful for characterising the layers of parent material and getting an overview of the particle size distribution. For example, Rodenas et al. used focused ion beam SEM (FIB-SEM) to image the distribution of MONs within their composite membranes (Fig. 6d).36 SEM microscopes can also be coupled to elemental characterisation techniques such as EDX. Brewster angle optical microscopy can be used to image nanosheets at interfaces such as those shown in Fig. 6d,30 as can Raman microscopy (Fig. 6e).27
Often only selected images of nanosheets are shown which may not be representative of the bulk sample. Some groups have attempted to quantify the size distribution by imaging a large number of nanosheets and tallying their thickness against their largest lateral dimension, as shown in Fig. 6a taken from the research of Maeda and coworkers.74 Although time consuming, this provides a more reliable account of the range of particles observed and must be considered good practice. Dynamic light scattering (DLS) has been used to measure the lateral size distribution of nanosheets. Lin and coworkers observed hydrodynamic diameters of 600–800 nm which corresponds with wrinkled nanosheets of ∼0.5 × 1 μm observed by TEM,61 whilst Rosseinsky and coworkers produced a narrow distribution of lateral sizes between 120–180 nm consistent with those observed by AFM (Fig. 6f).82
Fig. 7 (a) Photo showing typical Tyndall scattering resulting from a suspension of MONs. (b) Fluorescence emission profiles (λex = 330 nm) of Cd MONs in different solvents. (c) Gas adsorption isotherm comparing N2 uptake for Cu(BDC) bulk MOF (red) and MONs (blue). (d) AFM topographic image of Cu-based nanosheets suspended over micron-sized wells (400 nm depth) within a Si/SiO2 substrate. Images reprinted with permission from ref. 32, 114, 120 and 27, for images (a–d) respectively. |
As with MOFs, many of the applications of MONs take advantage of their porous structure and high surface area in the solid state. Gas adsorption measurements have relatively routinely been used to characterise the accessible volumes of MONs (Fig. 7c).68,121,122 The Brunauer–Emmett–Teller BET surface area of the nanosheets is typically lower than that of the parent bulk porous material due to inefficient packing of the small crystallites,120 however other properties such as permeability may be significantly enhanced, which is discussed further in Section 5.1.
Understanding the mechanical properties of MONs is also essential for optimising their use in applications such as in membranes for gas separation and in forming composites. The group of Cheetham used a spherical-tip diamond indentor to compare the mechanical properties of different faces of a bulk layered MOF.32 They were able to determine the critical resolved shear stress needed for the micromechanical delamination of individual layers to be relatively small at ≤0.4 GPa. AFM can also be used to undertake nanoindentation experiments of nanosheets positioned over wells of different diameters. Gomez-Herrero, Zamora and coworkers calculated the Young's modulus and breaking strength of their frameworks to be 5 GPa and 0.12 N m−1 (Fig. 7d).27 This is 200 and 150 times lower than the values reported for pristine graphene, but the MONs were still strong enough for free standing sheets to be suspended over micron sized holes.
Fig. 8 (a) Schematic illustration of selectively permeable MON composite membrane (left), and permeance as a function of the energy consumption for the 2D M-TCP(Fe)-based membranes, compared with additional advanced membranes. (b) N2 adsorption–desorption isotherms (77 K) on pristine Zn2(bim)4 and Zn2(bim)4 nanosheets, with inset photographs of material used for analyses. (c) Schematic of catalytic activity of Fe-TPY MONs. (d) Absorbance of juglone (λ = 419 nm) as a function of reaction time with different catalysts (right) and catalytic reaction scheme (left). (e) UV-Vis titration of pyridine into an aqueous suspension of Cu-MONs, with an inset of absorbance vs. concentration, used to calculate the binding constant. (f) Operation of the dual-electrochromic MON device. (g) Confocal fluorescence image of a single cell, showing two-colour sensing of DNA and small molecules with La-MONs. (h) TEM image of CuS nanoparticle-MON composite (left), and schematic illustration of the used photoelectrochemical cell (right). (i) Charge–discharge profile (black) and specific capacitance (red) at a current density of 2 A g−1 of the Co-MOF electrode. (j) Variable-temperature van der Pauw conductivity measurement on a ∼500 nm thick MON film on quartz. Images reprinted with permission. Images reprinted with permission from ref. 123, 68, 56, 53, 43, 100, 89, 51, 125 and 24 for images (a–j) respectively. |
Recently, MONs have been used for water purification through high-performance nanofiltration (NF).123 Membranes showed permeance about two orders of magnitude higher than a commercial NF membrane, while exhibiting high rejection rates of over 90% for organic dye molecules with sizes larger than 0.8 × 1.1 nm (Fig. 8a). The large body of research on the use of MOFs in gas storage and separation, coupled with the inherent advantages of MON morphology in enhancing the performance of membranes, means this area is likely to see considerable future investment.
MONs have also been used as photocatalysts and in electrochemical reactions. Ding et al. demonstrated Zn(Pd-TCPP) MONs perform better in singlet oxygen generation that the unexfoliated MOF, leading to increased rate of photooxidation of 1,5-dihydroxynaphthalene to juglone (Fig. 8d).53 The same photocatalytic reaction has been demonstrated using a Zr6-cluster-linked (NiTCPP) MON.59 Similarly, Zn-(ZnTCPP) MONs were used as a semiconductor photosensitizer along with ZIF-67 as a cocatalyst for the photochemical reduction of CO2 and exhibited enhanced photocatalytic efficiency compared to the bulk MOF.55 Multiple authors have incorporated MONs into electrodes for use within the electrochemical catalytic splitting of water, for H2 generation.22,25,41,57,80 Recent efforts outperform standard IrO2-based catalysts and comparing favourably with state-of-the-art transition-metal-based catalysts.57
An alternative approach has been to use MONs to quench the fluorescence of adsorbed, dye-labelled DNA and mRNA,49,64 of which detection limits have been found as low as 20 × 10−12 M,49 and 1 pM (after hybridisation chain reaction amplification).64 Similarly, background flourescence quenching enabled a signal-to-noise ratio increase of 7.5× that when using 2D graphene oxide, and enabled a detection limit down to 0.9 pM (0.3 pg mL−1) of chloramphenical, a model antibiotic,126 and luminescent quenching of nanosheet photoluminescence has been used to detect Fe3+ to a detection limit of 0.45 μM, amongst additional metal ions,127 and 0.054 μM (compared with 0.11 μM for bulk MOF).128
He et al. have developed MONs within a biosensor for the protein MUC1, with a detection limit of 0.12 ng mL−1.129 The cancer marker protein was detected from human serum, which points towards MON application within medicinal biosensing and diagnoses. Wang et al. have additionally demonstrated a lanthanide-based MON, useful as a two-colour sensing platform for intracellular DNA and small molecules (Fig. 8g).89 For further information on the preparation of MONs for chemical and biosensing and examples within this area, see Yang et al.'s recent review.130
Recent work has been directed towards the incorporation of MONs into supercapacitor electrodes.50,125,133 The groups of Jia and Wei have utilised MONs as electrode materials. Jia and coworkers found an 80.2% retention rate after 500 charge–discharge cycles,133 and more recently the group of Wei set records for both capacitance (2564 F g−1) and retention (95.8% after 3000 cycles) for MO materials (Fig. 8i).125
Liu et al. have utilised MONs as a clean-background matrix for MALDI-TOF mass spectrometry analysis of small biomolecules.69 Biomarkers are normally below the scope of this technique as interference from conventional matrices normally limits the size of molecules that can be seen to ∼700 Da. The superior background provided by the nanosheet composite allowed detection of glutamic acid (147 Da) amongst other small molecules and biomarkers. The same group also demonstrate MON inhibition of enzyme activity, allowing activity modulation.113
Intensive research over the last decade into the synthesis of two-dimensional materials and the exfoliation of layered materials into nanosheets similarly provides an important starting point for research into MONs. The use of ultrasound, solvation, intercalants, surfactants and crystal-growth modifiers all have parallels in the formation of nanosheets from other materials. There has been considerable innovation over the last year in new ‘softer forms’ of exfoliation and new ways to direct crystal growth, but it is not yet clear how broadly applicable these approaches will be. As with other nanosheets, the preferred method of synthesis is likely to depend on the properties of nanosheets required. In general, bottom-up methods have tended to produce larger nanosheets with narrower size distributions whilst top-down exfoliations have tended to give smaller, thinner sheets. However, the diversity of MON chemistry means it is difficult to generalise and compare different studies, and in most cases the synthesis or exfoliation will not have been optimised. More detailed and systematic studies are therefore required to understand the effect of different parameters on the dimensions of nanosheets produced to allow more targeted synthesis.
A diverse range of solid, solution, colloidal and surface analysis techniques must be combined to provide insights into different levels of their structure. The complex molecular structure of MONs, their relatively fragile and non-conducting composition and the spread of sizes and thicknesses of nanosheets produced makes them particularly challenging to characterise. Greater understanding of the mechanical, optoelectronic and porosity of nanosheets and how this compares with the parent, layered materials will be important for identifying new applications. There is also little general acceptance of what constitutes a “nanosheet” in terms of the number of layers, size distribution and crystallinity of the materials formed. Setting the bar too high at this early stage has the potential to stifle innovation. Setting it too low will dilute the field with compounds without the potential to form free-standing, crystalline, single-layered materials.
The success of MONs as a distinct class of nanomaterials is likely to rest on their utility. The billions of dollars invested by industry and funding councils in other two-dimensional and metal–organic materials demonstrates both the potential demand for these type of materials and the challenges in bringing them to market. The chemical diversity, modular structure and tunability of MONs offers obvious advantages over simple inorganic nanosheets and the inherent reversibility of coordination bonds and unique properties of metal ions offers distinct opportunities compared to covalent–organic framework (COF) nanosheets. The high external surface area and tuneable structure of MONs make them obvious candidates for a wide range of sensing, separation and catalytic applications and there are already promising examples of MONs outperforming bulk MOFs when used as membranes for gas-separation and as catalysts. The tuneable electronic, optical and magnetic properties of MONs also potentially allow them to be used as layers in diverse range of devices including displays, solar-cells and batteries. The wide range of inexpensive and abundant ligands and metal ions that can be used to construct MONs and the ability to synthesise them from solution and process them as suspensions offers further environmental and economic advantages.
In conclusion, MONs represent a rich new class of materials requiring distinct approaches in their design, synthesis and characterisation and offering a novel combination of properties that can be harnessed for a wide range of applications. This is an emerging field whose boundaries, techniques, rules and potential are only just beginning to be explored. Here we have tried to highlight both the breadth of different approaches that have so far been taken and draw out common threads between the different studies. We hope that this review will further stimulate this exciting area of research and look forward to contributing further to its development.
This journal is © The Royal Society of Chemistry 2018 |