• 综述 •
李立清, 吴盼旺, 马杰. 双网络凝胶吸附剂的构建及其去除水中污染物的应用[J]. 化学进展, 2021, 33(6): 1010-1025.
Liqing Li, Panwang Wu, Jie Ma. Construction of Double Network Gel Adsorbent and Application for Pollutants Removal from Aqueous Solution[J]. Progress in Chemistry, 2021, 33(6): 1010-1025.
近年来,随着工业的迅速发展,水污染危机是世界面临的主要威胁之一,开发新型环境功能材料和技术,实现水体污染物的高效去除是目前研究热点。双网络水凝胶(Double Network hydrogels)是具有三维网络结构的高分子聚合物,其机械性能优越,具备较高的强度,可以承受高水平的拉伸和压缩变形。低溶胀率使水凝胶可以容纳大量水并保持稳定的形态和网络结构。此外,由于其独特的交联方式,它还具有快速的自修复性能和显著的抗疲劳性能。具备众多优点的双网络水凝胶是一种有着巨大潜力的吸附材料,在水处理领域引起广泛关注。本文综述了双网络凝胶吸附剂的物化特性及其分类,以及近年来双网络凝胶吸附剂去除水体中重金属、抗生素和染料等污染物的应用进展。通过该综述,为双网络凝胶吸附剂的深入开发以及在水质净化中的工程应用提供新思路、新方法和新技术。
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Year | Double Network hydrogels | Adsorbed pollutant | Maximum adsorption capacity(mg/g) | Regenerability | Kinetic model | Adsorption isotherm | Adsorption thermodynamics | adsorption mechanism | ref | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
2012 | PAA/SiO2 | Cu(Ⅱ) Cr2 | 690.00 19.10 | - | - | Freundlich | - | Electrostatic interactions | ||||||||||
2015 | PVA/PAA | Cd(Ⅱ) Pb(Ⅱ) | 194.99 115.88 | After 5 adsorption-desorption cycles, the removal rate remained nearly 100% | P2 | Langmuir | Spontaneous and endothermic | Ion exchange | ||||||||||
2015 | PSA/GO | Cd(Ⅱ) Mn(Ⅱ) | 238.30 165.50 | After 4 cycles, the removal efficiency was maintained at about 85% | P2 | Langmuir | Spontaneous and endothermic | Electrostatic interactions and ion exchange | ||||||||||
2016 | Alginate/RGO | Cu(Ⅱ) Cr2 | 169.50 72.46 | After 10 cycles, the adsorption capacities of Cu2+and Cr2 were maintained at 92.12 mg/g and 48.23 mg/g, respectively | - | Langmuir | Spontaneous and endothermic | Electrostatic interactions | ||||||||||
2016 | N - Starch/PAA | Cd(Ⅱ) | 256.40 | After 5 cycles, the removal efficiency decreased slightly to 97.7% | P2 | Langmuir | Spontaneous and endothermic | Chemisorption | ||||||||||
2017 | CTSb/PAM | Cd(Ⅱ) Cu(Ⅱ) Pb(Ⅱ) | 86.00 99.44 138.41 | After 5 cycles, the removal efficiency decreases by less than 3% | P2 | Langmuir | Spontaneous and endothermic | Ion exchange | ||||||||||
2018 | Cellulose/PAM | Cd(Ⅱ) Cu(Ⅱ) Pb(Ⅱ) | 198.48 138.90 382.80 | After 10 cycles, the observed adsorption difference was negligible | P2 | Langmuir | Spontaneous and endothermic | Electrostatic interactions and ion exchange | ||||||||||
2018 | Jute/PAA | Pb(Ⅱ) Cd(Ⅱ) | 542.9 401.7 | After 5 cycles, the removal efficiency remained 81% and 94% respectively | P2 | Langmuir | Spontaneous and endothermic | Chemisorption | ||||||||||
2018 | PAA/HSc | Pb(Ⅱ) Cu(Ⅱ) Cd(Ⅱ) | 360.5 151.00 412.76 | After 5 cycles, the adsorption capacity of the three decreased by only 7%, 3% and 1% respectively | Elovich | Langmuir-Freundlich | Spontaneous and endothermic | Coordination interaction and electrostatic interactions | ||||||||||
2018 | PVA/PAMPS | Pb(Ⅱ) Cd(Ⅱ) | 340.00 155.10 | After 5 cycles, the removal efficiency remained 94% and 93%, respectively | P2 | Langmuir | Spontaneous and endothermic | Ion exchange and complexation | ||||||||||
2018 | GO/PAA aerogeld | Cu(Ⅱ) | 390.34 | After 7 cycles, the removal efficiency was still over 95% | P2 | Langmuir | - | - | ||||||||||
2018 | GO/SA | Mn(Ⅱ) | 56.49 | After 7 cycles, the adsorption capacity remained unchanged at 18.11 mg/g | P2 | Freundlich | Spontaneous and endothermic | - | ||||||||||
2019 | RH-CTSe/ PAM | Pb(Ⅱ) Cu(Ⅱ) Cd(Ⅱ) | 374.32 196.68 268.98 | After 5 cycles, the adsorption rate decreased by only 2.3%, 1.8% and 3.1%, respectively | P2 | Freundlich | Spontaneous and endothermic | Chelation or coordination interaction | ||||||||||
2019 | CMC/PEI | Cr(Ⅵ) | 312.46 | After four cycles, the removal rate decreased by 8.70% | P2 | Freundlich | Spontaneous and endothermic | Electrostatic attraction, redox, coordination and sediment | ||||||||||
2020 | GO-CA/PAA | Cd(Ⅱ) | 119.98 | After 5 cycles, the adsorption capacity of the adsorbent is almost not reduced | P2 | Langmuir | Spontaneous and endothermic | Ion exchange | ||||||||||
2020 | TR f /PAA | Cr(Ⅲ) Pb(Ⅱ) Fe(Ⅲ) | 206.19 253.16 94.88 | After 7 cycles, the adsorption efficiency of Cr(Ⅲ), Fe(Ⅲ) and Pb(Ⅱ) decreased by 9.9%, 5.0% and 16.7% respectively | P2 | Freundlich | - | Chelation, coordination, ion exchange and electrostatic interactions | ||||||||||
Year | Double Network hydrogels | Adsorbed pollutant | Maximum adsorption capacity(mg/g) | Regenerability | Kinetic model | Adsorption isotherm | Adsorption thermodynamics | adsorption mechanism | ref | |||||||||
2020 | N -GR/Alginate | Cu(Ⅱ) | 153.91 | - | P2 | Langmuir | - | Chemisorption | ||||||||||
2020 | CTS/SA | Pb(Ⅱ) Cu(Ⅱ) Cd(Ⅱ) | 400.90 71.10 99.46 | - | P1,P2 | Freundlich | Spontaneous and endothermic | Electrostatic interactions, coordination interaction | ||||||||||
2020 | SA/PAA/nZnh | Pb(Ⅱ) | 200.00 | - | P2 | Freundlich | Spontaneous and exothermic | Chemisorption |
Year | Double Network hydrogels | Adsorbed pollutant | Maximum adsorption capacity(mg/g) | Regenerability | Kinetic model | Adsorption isotherm | Adsorption thermodynamics | adsorption mechanism | ref |
---|---|---|---|---|---|---|---|---|---|
2013 | GO-SA/PAM | Cationic dyes and anionic dyes | - | - | - | - | - | - | |
2014 | SA/SAPa | RB4 | 245 | After 5 sorption-desorption cycles, the adsorption capacity remained almost unchanged | P1 | Langmuir | Spontaneous and endothermic | - | |
2016 | Alginate/GO | MB | 2300 | After 10 cycles, the removal rate was reduced to 60.2% | P2 | Langmuir | - | Electrostatic interactions, hydrogen bond, hydrophobic interactions | |
2018 | Alginate/PVAb | MB | 313.09 | - | P2 | Langmuir | Spontaneous and endothermic | - | |
2018 | Alginate/ PAMc | MB | 1124 | After 5 cycles, the adsorption removal rate was slightly reduced | P2 | Langmuir | - | Electrostatic interactions | |
2018 | PNIPAM@ PS/CS/PAA | Cationic dyes | - | - | P2 | Langmuir | - | Electrostatic interactions | |
2019 | CA/PVA | MB | 1437.48 | - | P2 | Langmuir | Spontaneous and endothermic | Electrostatic interactions | |
2019 | starch/PVA/borax | MB | 144.68 | - | - | - | - | Electrostatic interactions | |
2019 | GO/PAA | CV MB | 851.31 771.14 | - | P2 | Langmuir, D-R | - | Electrostatic interactions, π-π interactions | |
2019 | Alginate/PAM/OA-POSS | MB | 75.41 | - | P2 | Redlich-Peterson | Spontaneous and endothermic | - | |
2020 | GO/PAA | MB | - | - | - | - | - | Electrostatic interactions, π-π interactions | |
2020 | GO/AAMd | MB Rh B | - | After 10~14 cycles, the adsorption efficiency remained almost unchanged | P2 | - | - | Electrostatic interactions, π-π interactions | |
2020 | Starch/PAA | MB CR | 133.65 64.73 | - | P2 | Freundlich | - | Electrostatic interactions |
Year | Double Network hydrogels | Adsorbed pollutant | Maximum adsorption capacity(mg/g) | Regenerability | Kinetic model | Adsorption isotherm | Adsorption thermodynamics | adsorption mechanism | ref |
---|---|---|---|---|---|---|---|---|---|
2017 | Alginate/GRa | TC CIP | 290.70 344.83 | After 10 cycles, the adsorption capacity remained above 200 mg/g | P2 | Langmuir | - | Electrostatic interactions | |
2019 | κ-Carrageenan/ SA | CIP | 229 | - | P2 | Langmuir-Freundlich | - | Hydrogen bond, electrostatic interactions | |
2019 | SA/κ-Carrageenan | CIP | 291.6 | - | P2 | Langmuir-Freundlich | spontaneous and endothermic | Hydrogen bond, electrostatic interactions | |
2020 | N -GR/Alginate | CIP | 301.36 | - | P2 | Langmuir | Hydrogen bond, electrostatic and π-π interactions | ||
2020 | FeS/GR aerogelc | TC | - | - | - | - | - | Hydrogen bond, π-π interactions |
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