• 综述 •
张安睿, 艾玥洁. 共价有机框架(COFs)材料的结构控制及其在环境化学中的应用[J]. 化学进展, 2020, 32(10): 1564-1581.
Anrui Zhang, Yuejie Ai. Structure Control of Covalent Organic Frameworks(COFs) and Their Applications in Environmental Chemistry[J]. Progress in Chemistry, 2020, 32(10): 1564-1581.
近年来,共价有机框架(COFs)材料因其稳定的结构、高比表面积、大孔隙率、可修饰结构和易于功能化而受到了科学家们的广泛关注。通过控制COFs材料的孔径、形状和链接方式以及后合成修饰,功能性COFs材料在气体储存分离、传感器和药物传输等领域发挥了越来越重要的作用。尤其在环境化学领域,COFs材料的研究和应用已成为一热门课题。本文综述了COFs材料的结构控制、分类以及在环境污染物检测和去除中的应用,包括对重金属离子、放射性核素、有机污染物和气体污染物的吸附和催化等。通过改变构筑单体的大小和形状、引入特殊官能团和活性位点等方法,可以增强污染物与COFs材料的相互作用(氢键相互作用、π-π相互作用和范德华力等),使COFs材料在环境领域应用中有优异的表现。本文最后展望了COFs材料在环境领域的应用前景和今后的研究方向,希望能为该领域的研究提供参考。
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COFs | Removal | Building units | Pore size/nm | Conditions | Adsorption capacity | ref | |
---|---|---|---|---|---|---|---|
pH | T/K | ||||||
TAPB-BMTTPA-COF | Hg(Ⅱ) | TAPB, DMTTPA | 3.2 | 7.0 | 298 | 734 mg/g | 60 |
COF-LZU8 | Hg(Ⅱ) | - | 1.23 | - | - | - | 61 |
CTF-1 | Cd(Ⅱ) | 1,4-dicyanobenzene | 1.2 | - | 298 | 29.26 mg/g | 54 |
γ-Fe2O3@CTF-1 | As(Ⅲ) | Fe2O3, CTF-1 | - | 7.0 | 298 | 198.0 mg/g | 62 |
As(Ⅵ) | 102.3 mg/g | ||||||
Hg(Ⅱ) | 165.8 mg/g | ||||||
COF-S-SH | Hg | COF-V, thiol/thioether | 2.8 | - | 298 | 863 mg/g | 63 |
Hg(Ⅱ) | 1350 mg/g | ||||||
COF-TE | Pb(Ⅱ) | TMC, EDA | - | - | 298 | 185.7 mg/g | 64 |
COF-TP | Pb(Ⅱ) | TMC, PDA | - | - | 298 | 140.0 mg/g | 64 |
TPB-BT-COF | Cr(Ⅵ) | BT, TPB | 3.26 | - | - | - | 65 |
TAPT-BT-COF | Cr(Ⅵ) | BT, TAPT | 3.26 | - | - | - | 65 |
QG-scaffolded COFs | Cu(Ⅱ) | PA, MA, Phen, QG | - | - | - | - | 5 |
3D-OH-COF | Sr(Ⅱ) | TFPM, DHBD | 1.31 | - | - | - | 66 |
Fe(Ⅲ) | - | ||||||
Nd(Ⅲ) | - | ||||||
TTTAT | I2 | TTAT | 1.22 | - | 350 | 3.41 g/g | 67 |
TTDAT | I2 | TTDT | 1.22 | - | 350 | 2.91 g/g | 67 |
TPT-DHBDX COF | I | TPT-CHO, DHBD | 3.43 | - | 348 | 5.43 g/g(X=0) | 68 |
SCU-COF-1 | TcO4-/ReO4- | aminated viologen,Tp | 1.44 | - | 373 | 702.4 mg/g | 69 |
DhaTGCl | TcO4-/ReO4- | Dha, TGCl | 1.5 | 3~12 | 298 | 437 mg/g | 70 |
PQA-Py-I, PQA- pNH2Py-I, PQA-pN(Me)2Py-I | TcO4-/ReO4- | - | - | - | - | 997 mg/g | 70 |
CPF-D, CPF-T | U | HCCP, hydroquinone/ phloroglucinol | - | 1 | 298 | 140 mg/g (CPF-T) | 58 |
MPCOF | U | HCCP, PDA | 1.8 | 4.5 | - | 169 mg/g | 57 |
1~2.5 | - | 95 mg/g | |||||
COF-HBI | U | TMC, PDA, HBI | - | 4.5 | - | 211 mg/g | 72 |
4.5 | - | 81 mg/g | |||||
COF-TpDb-AO | U | Db, Tp, hydroxylamine | 1.58 | - | - | 127 mg/g | 73 |
PAF-1-CH2AO | U | PAF-1, HCl, NaCN, NH2·OH | 0.7 | 6 | 298 | 300 mg/g | 74 |
[NH4]+[COF-SO4-] | U | COF-SO3H, NH3·H2O | 1.1 | 5 | 298 | 851 mg/g | 75 |
5 | 298 | 17.8 mg/g | |||||
o-GS-COF | U | TDCOF, QG | - | - | - | 220.1 mg/g | 76 |
MIPAFs | U | - | - | 6.5 | - | 37.28 mg/g | 77 |
COFs | Removal | Building units | Pore size/nm | Conditions | Adsorption capacity | Catalytic amount | ref | ||
---|---|---|---|---|---|---|---|---|---|
pH | T/K | ||||||||
TS-COF-1 | MB | TAPT, PMDA/Tp | 3.3 | - | 298 | 1691 mg/g | - | 84 | |
TS-COF-2 | 1.5 | - | 298 | 377 mg/g | - | ||||
Fe-TiO2@COF | MB | TpTa-COF, TiO2, Fe3+ | 2.3 | - | - | - | 100 mg/L,4 mL | 85 | |
Ag@TPHH-COF | 4-nitrop-henol, NACs | TPT-CHO, hydrazine hydrate, Ag+ | 2.4 | - | 298 | - | - | 86 | |
g-C3N4@COF | Acid Orange Ⅱ | g-C3N4, TpPa-1 | - | 5.88 | 298 | - | - | 87 | |
COF1 | TPhP | Tp, Pa-1/BD/DT | 1.81 | 7.5 | 300 | 86.1 mg/g | - | 88 | |
COF2 | 2.57 | 7.5 | 300 | 387.2 mg/g | - | ||||
COF3 | 3.34 | 7.5 | 300 | 371.2 mg/g | - |
COFs | Removal | Building units | Pore size/nm | Conditions | Adsorption capacity | ref | |
---|---|---|---|---|---|---|---|
pH | T/K | ||||||
COF-10 | NH3 | Hexahydroxytriphenylene, biphenyldiboronic acid | 3.4 | - | 298 | 15 mol/kg | 88 |
[HOOC]X-COF | NH3 | TP, PA, 2,5-diaminobenzoic acid | 2.4 | - | 298 | 9.34 mmol/g(X=17) | 89 |
COF-105 | SO2 | TBPS, 2,3,6,7,10,11-hexahydroxy triphenylene | - | - | - | - | 90 |
PI-COF-mX | SO2 | DMMA, TAPA, PMDA | 2.9 | - | - | 6.30 mmol SO2 g-1 (X=10) | 91 |
CTF-HUST-HC1 | NO | Terephthalaldehyde, Terephthalamidine dihydrochloride | 1.2 | - | - | - | 92 |
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