• Review •
Xiaozhu Zhao, Wen Li, Xuerui Zhao, Naipu He, Chao Li, Xuehui Zhang. Controlled Growth of MOFs in Emulsion[J]. Progress in Chemistry, 2023, 35(1): 157-167.
Emulsion | MOFs | Base stock | Morphological | Pore size | Application | ref |
---|---|---|---|---|---|---|
Traditional emulsion/Surface growth on micelle template | HKUST-1 | Cu(NO3)2/ H3BTC/H2O/EtOH/CTAB/TMB | Hierarchically micro-/ mesoporous MOFs | Meso-micro pores, tunable pore size: 3.8~31.0 nm | Heterogeneous catalysis | |
HKUST-1 | Cu(NO3)2/H3BTC/ H2O/EtOH/HPW/ CTAB | Hierarchically micro-/ mesoporous MOFs, bimodal micro-/mesoporous hexagonal variant | Meso-micro pores, wide mesopores of 5 nm separated by microporous walls | Selective catalysis | ||
HKUST-1 | Cu(NO3)2/H3BTC/ DMF/CTAB/CA | Hierarchically micro-/ mesoporous MOFs | Meso-micro pores, wide mesopores of 19.6 nm, wide micropores of 0.86 nm | Bulky molecule capture, heterogeneous catalysis | ||
Cu-(5-OH- BDC)-C16 | Cu(NO3)2/5- OH-BDC/H2O/CTAC | 2D hexagonal symmetry, highly ordered hexagonal meso-structure | Meso-micro pores | Heterogeneous catalysis, controlled drug release | ||
Reverse microemulsion/ Interior growth in micelle template | Gd(BDC)1.5(H2O)2 | GdCl3/BDC/CTAB/ isooctane/1- hexanol/H2O | Nanorods of fairly uniform shape and size 100~125 nm in length by 40 nm in diameter | Micropores | Target-specific multimodal imaging contrast agents | |
[Gd(1,2, 4-BTC) (H2O)3]·H2O | GdCl3/BDC/CTAB/isooctane/1- hexanol/H2O | Irregularly shaped crystalline nanoplates ~100 nm in diameter, an average thickness of 35 nm | Micropores | Target- specificmultimodal imaging contrast agents | ||
Mn(BDC)(H2O)2 | MnCl2/[NMeH3]2 (BDC)/CTAB/1- hexanol/ n-heptane/H2O | Nanorods of fairly uniform shape and size 750 nm to several μm in length, 50~100 nm in diameters | Micropores | Targeted delivery of other imaging and therapeutic agents | ||
Mn3(BTC)2 (H2O)6 | Microwave heating MnCl2/Na3BTC/ CTAB/1-hexanol /isooctane/H2O | An unusual spiral rod morphology of fairly uniform shape and size, 1~2 μm in length, 50~100 nm in diameter | Micropores | Target-specific MR imaging | ||
ZIF-8 ZIF-67 | Zn(NO3)2/2-MI/ CTAB/n-hexanol/n-heptane/H2O | Nanoparticles, the mean particle size of ZIF-8 was 2.3 nm, the ZIF-67 has the mean particle size of 2.7 nm | Micropores | Gas storage | ||
ZIF-8 | Zn(NO3)2/2-MI/ CTAB/1-hexanol/heptane/H2O | Spherical particle, the mean particle was 100 nm | Micropores | Gas storage, heterogeneous catalysis | ||
ZIF-8 | Zn(NO3)2/2-MI/ CTAB/n-hexanol/n-heptane/H2O | Lamellar MOFs@polymer networks, regular spherical nanoparticles, 100 nm in dimeter | Micropores | CO2 adsorption | ||
ZIF-8 ZIF-67 | Zn(NO3)2/2-MI/ H2O/BmimPF6/TX-100 Cu(NO3)2/H3BTC/ | Nanoparticles, size < 2.3 nm, narrow distribution < 0.5 nm | Micropores | Biomedical imaging | ||
HKUST-1 | H2O/ethanol/BmimPF6/TX-100 | Spherical nanoparticles, the mean particle size was 1.6 nm (σ = 0.4) | Micropores | |||
La-MOFs | La(NO3)3/BTC/H2O/BmimPF6/TX-100 | Micellar particles: spherical, lamellar, and cylindrical | Micropores | Sensing, controlled drug release | ||
Surfactant-free emulsion /Surface growth on polymer template | ZIF-8 | Zn(NO3)2/2-MI/ H2O/1-octanol /PVP | Hollow MOFs Nanospheres with average diameters around 130 nm, the shell thickness increased from 20 nm to 50 nm | Pore aperture of ZIF-8 = 3.4 Å | Heterogeneous catalysis | |
MIL-88A | FeCl3/Tributylamine /1-Octanol/H2O/ PVA/Fumaric acid micro-fluidic System | Uniform spherical shape with tunable size, 450 μm in diameter and 2 μm in shell thickness, | Micropores, micropores size: less than 1 nm | Enzyme and nanoparticle encapsulation | ||
ZIF-8 | Zn(NO3)2/2-MI/ APS/H2O/TEA /DMAPMA | ZIF-8@PDMAPMA nanoparticle, spherical nanospheres, polyhedron cube morphology, 100~ 400 nm | Micropores | Drug loading | ||
Cu3(BTC)2 | Cu(NO3)2/ H3BTC/H2O/ EtOH/CH3COOH/ Pluronic F127 | Discrete octahedral, nanocrystals, 100~200 nm | Mesopore diameter=4.0 nm | Gas storage, catalysis, sensing, and drug delivery. | ||
Cu2(HBTB)2 | Cu(NO3)2/ H3BTB/H2O/ EtOH/CH3COOH/ Pluronic F127 | Flower-like nanosheets, thickness of the lamellar stacking = 40~60 nm | Mesopore diameter = 3.9 nm | |||
UiO-66-NH2 | ZrO(NO3)2·2H2O/ BDC-NH2/toluene/H2O/P123/ F127/NaClO4/H2O/AA | Bowl-like mesoporous nanoparticles, dendritic nanospheres, walnut-shaped nanoparticles, nanosheet with surface folds, nano disk | Pore aperture = 0.8 nm, 1.1 nm | Heterogeneous regeneration of the coenzymes | ||
ZIF-8 | Zn(NO3)2/2-MI/ catalase/H2O | Cruciate flower | The average pore diameter was 12.24 nm | Enzyme immobilization | ||
Pickering emulsion/Surface growth on solid template | ZIF-8 | HIPE Zn(NO3)2/2-MI/ H2O/CNCs/dodecane | Microspheres, micropores/ mesopores, the wall thickness of microsphere was 2.0~ 2.5 μm | Micropores | Dye adsorption | |
Cu3(BTC)2 | Cu(NO3)2/H3BTC/ n-octanol/H2O/GO | Regular octahedron, columnar 100~200 nm, columnar rod with a length of 1~2 μm | Macropores | CO2 adsorption | ||
ZIF-8 | HIPE Zn(NO3)2/2-MI/ H2O/oleic acid/ZIF-8 | Foam-like structure containing well-separated macro-porous cavities, ZIF-8 nanoparticle shape or size = 120 nm | Macroporous size: 17 μm, micropores size: less than 1 nm | Gas separation, pollutant removal | ||
ZIF-8 | HIPE Zn(NO3)2/ 2-MI/H2O/ cyclohexane/ZIF-8 (200 nm) | Hierarchical microporous MOF monoliths, nanoZIF-8: rhombic dodecahedron size = 200 nm, 3D ZIF-8 monoliths void walls were coated with close-packed ZIF-8 nanoparticles. | Micropores in the ZIF-8 framework: 0.64 and 0.90 nm, 3D ZIF-8 monoliths void size of around 50 μm | Oil-water separation, selective catalysis |
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