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杨良嵘, 邢慧芳, 屈虹男, 于杰淼, 刘会洲. 外场强化环境响应固相萃取技术[J]. 化学进展, 2019, 31(11): 1615-1622.
Liangrong Yang, Huifang Xing, Hongnan Qu, Jiemiao Yu, Huizhou Liu. External Field Enhanced Environmental Responsive Solid Extraction Technology[J]. Progress in Chemistry, 2019, 31(11): 1615-1622.
低浓度大体量复杂溶液中目标物的高效、精准、可控分离是当今化工分离科学领域的世界前沿课题。固相萃取技术目前用于低浓度复杂体系工业分离面临两方面挑战:一方面是高选择性精准捕获与温和绿色解吸难以兼具。另一方面是固相萃取技术缺少规模连续化分离的高效分离工艺设备。本文综述了为解决当前固相萃取技术存在的问题,实现低浓度复杂体系的高效精准和可控分离,新型环境响应固相萃取技术,磁场响应固相萃取技术以及电场、超声场辅助固相萃取技术取得的研究进展。最后,关于该应用领域固相萃取技术的研究发展方向进行了展望。本文对外场强化环境响应固相萃取技术的关键科学问题,包括环境响应问题、可控分离问题和过程放大问题进行了深入探讨,并对相关领域的发展提出了措施与建议。
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Adsorbent | qm (mg/g) | E. T. (min) | pH range | Ref |
---|---|---|---|---|
γ-Fe2O3@δ-FeOOH | 25.8 | — | 2.5 | 25 |
Fe3O4@PAA-DETA | 11.24 | — | 5.0 | 26 |
NiFe2O4 | 30 | — | 5.0 | 27 |
Fe3O4-PEI-MMT | 8.8 | — | 5.0 | 28 |
Fe3O4-Cyanex-301 | 30.8 | 120 | 2.0 | 29 |
ZnFe2O4-Ce3+ | 57.24 | 4320 | 2.0 | 30 |
Poly(MMA-DVB-GMA)-EDA | 61.35 | 60 | 2.0~3.0 | 31 |
Fe3O4@polypyrrole | 169.49 | 180 | 1.0~6.0 | 32 |
Poly(GMA-EGDMA)-PEI | 137.7 | 120 | 1.0~6.0 | 33 |
Poly(MA-DVB)-EDA | ~36 | 60 | 3.0 | 34 |
Magnetic chitosan beads | 69.4 | > 60 | 3.0~5.0 | 19b |
Magnetic chitosan-EDA | 51.813 | 10 | 2.0 | 35 |
Magnetic chitosan-CAGS | 58.48 | 110 | 2.0 | 19c |
Chitosan/ montmorillonite | 35.71 | 100 | 1.0~3.0 | 36 |
Magnetic chitosan nanoparticles | 55.80 | 150 | 2.0~3.0 | 37 |
Cyclodextrin-chitosan/GO | 67.66 | — | 1.0~3.0 | 38 |
MnFe2O4/Chitosan | 15.4 | 360 | 6.0 | 39 |
MnFe2O4-Chitosan | 51.79 | 480 | 5.0 | 39 |
Fe3O4-Fungus@alginate-PAA | 6.97 | 720 | 1.0 | 40 |
Fe3O4@PVA-PEI | 88.4 | 8 | 1.0~3.0 | 41 |
Fe3O4@PGMA-PEI | 492.6 | 10 | 1.0~7.0 | 42 |
Fe3O4@Pst-MIMCl | 104.0 | 30 | 1.0~7.0 | 43 |
Fe3O4@SiO2@CE-EDA | 171.5 | 10 | 1.0~6.0 | 44 |
Fe3O4@SiO2@CTS-PEI | 236.4 | 60~120 | 1.0~6.0 | 45 |
Fe3O4@SiO2@CTS-GTMAC | 233.1 | 40~120 | 1.0~7.0 | 43 |
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