• 综述 •
彭涛, 柴倩倩, 李传强, 郑旭煦, 李铃娟. MOFs衍生金属氧化物在催化VOCs完全氧化中的应用[J]. 化学进展, 2024, 36(1): 81-94.
Tao Peng, Qianqian Chai, Chuanqiang Li, Xuxu Zheng, Lingjuan Li. Application of MOFs-Derived Metal Oxides in Catalytic Total Oxidation of VOCs[J]. Progress in Chemistry, 2024, 36(1): 81-94.
大量挥发性有机化合物VOCs的排放对人类和环境造成了严重的影响。通过金属氧化物催化VOCs完全氧化为无毒害的二氧化碳和水是当前最有效的处理方式。为提高金属氧化物的催化性能,已开发了多种合成策略,如形貌工程、缺陷工程和掺杂工程等。然而,这些合成工艺不仅繁琐,而且催化性能有待提升。相比之下,金属有机框架(MOFs)衍生的金属氧化物由于其形貌可调、大比表面积、高缺陷浓度和良好的掺杂分散性等优点,被广泛应用于催化VOCs的完全氧化。由于目前缺乏针对MOFs衍生金属氧化物在VOCs完全氧化应用上的总结,本文从衍生金属氧化物的调控策略出发,对MOFs的合成条件、掺杂方式和热解条件进行了综述。总结了这些调控方法、衍生金属氧化物的物理化学性质与VOCs完全氧化性能的关系,并探讨了其未来的发展和挑战。
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Catalyst | MOF | pyrolysis conditions | pollutant | Concentration(ppm) | WHSV(mL·gcat−1·h−1) | T90(℃) | ref |
---|---|---|---|---|---|---|---|
CeO2/Co3O4 | CoCe-BDC | Air, 350 ℃ | Acetone | 600 | 18 600 | 180 | |
CeCoOx-MNS | ZIF-67 | Air, 450 ℃ | Toluene | 3000 | 30 000 | 249 | |
CeO2-1 | Ce-BTC | Air, 450 ℃ | o-xylene | 500 | 48 000 | 198 | |
Co3O4-R | Co-MOF-74 | Air, 350 ℃ | o-xylene | 100 | 120 000 | 270 | |
Mn-100-AR-O | MIL-101(Mn) | O2 after Ar, 700 ℃ | Toluene | 1000 | 30 000 | 265 | |
ZSA-1-Co3O4 | ZSA-1 | Air, 350 ℃ | Toluene | / | 20 000 | 240 | |
CeO2 | Ce-MOF-808 | Air, 250 ℃ | Toluene | 1000 | 30 000 | 278 | |
Mn3O4-MOFs-74-300 | Mn-MOF-74 | Air, 300 ℃ | Toluene | 1000 | 20 000 | 218 | |
CeCoOx-200 | Ce[Co(CN)6]2·nH2O | Air, 500 ℃ | Toluene | 3000 | 30 000 | 168 | |
Co3O4-400 | ZIF-67 | Air, 350 ℃ | Toluene | 12000 | 21 000 | 259 | |
CeO2-C | Ce-BTC | Air, 450 ℃ | o-xylene | 500 | 48 000 | 193 | |
Co2Mn3 | MnCo-BTC | Air, 350 ℃ | Propane | 10000 | 120 000 | 255 | |
M-Co2Cu1Ox | CoCu-MOF-74 | Air, 400 ℃ | Toluene | 1000 | 30 000 | 220 | |
MOF-Mn1Co1 | Mn3[Co(CN)6]2·nH2O | Air, 450 ℃ | Toluene | 500 | 96 000 | 226 | |
MnOx-CeO2-MOF | Ce/Mn-MOF-74 | Air, 600 ℃ | Toluene | 1000 | 60 000 | 220 | |
CuMn2Ox | CuMn -BTC | N2,350 ℃&500 ℃ | Acetone | 1019 | 18 000 | 144 | |
MnOx-CeO2-s | Mn/Ce-BTC | Air, 600 ℃ | ethylacetate | 500 | 60 000 | 205 | |
CuO/Co3O4 | Cu/ZIF-67 | Air, 500 ℃ | Toluene | 1000 | 20 000 | 229 | |
M-Co1Mn1Ox | Mn/ZSA-1 | Air, 500 ℃ | Toluene | - | 20 000 | 192 | |
15Mn/Cr2O3-M | Cr-MIL-101 | Air, 500 ℃ | Toluene | 1000 | 60 000 | 268 | |
10%CeO2-MnOx | Mn-BTC | Air, 300 ℃ | Toluene | 1000 | 48 000 | 275 | |
M-Co1Cu1Ox | Mn/ZSA-1 | Air, 350 ℃ | Toluene | 1000 | 20 000 | 208 | |
MnOx/Co3O4-4 h | Mn/ZIF-67 | Air, 350 ℃ | chlorobenzene | 1000 | 60 000 | 334 | |
MnOx/Co3O4-10 | Mn/ZIF-67 | O2 after N2, 500 ℃ | Toluene | 1000 | 120 000 | 242 | |
CoMn6 | Mn/ZIF-67 | Air, 350 ℃ | Toluene | 1000 | 60 000 | 219 | |
MOF-CMO/400 | Mn3[Co(CN)6]2·nH2O | Air, 400 ℃ | Toluene | 1000 | 20 000 | 209 | |
M-Co3O4-350 | ZSA-1 | Air, 350 ℃ | Toluene | 1000 | 20 000 | 239 | |
Co3O4-350 | Co-BTC | Air, 350 ℃ | Propane | 10000 | 60 000 | 275 | |
CeO2-MOF/ 350 | Ce-BTC | Air, 350 ℃ | Toluene | 1000 | 12 000 | 260 | |
1Mn1Ce-300 | MnCe-BTC | O2 after Ar, 300 ℃ | Toluene | 1000 | 30 000 | 244 | |
HW-MnxCo3-xO4 | ZIF-67 | Air, 350 ℃ | Toluene | 3000 | 30 000 | 188 | |
MnOx-NA | Mn-BDC | O2 after N2, 350 ℃ | Acetone | 600 | 56 000 | 167 | |
MnOx@ZrO2-NA | MOF-808 | O2 after N2, 300 ℃ | Toluene | 1000 | 60 000 | 260 | |
MnOx-700 | Mn-MOF-74 | Air, 700 ℃ | chlorobenzene | 50 | 12 000 | 225 | |
3Mn2Ce | Mn/Ce-BTC | O2 after Ar, 300 ℃ | Toluene | 1000 | 30 000 | 236 |
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