| Functional modification of zwitterionic polymers for PVDF membranes and the study on the performance |
| Authors: Xiaoji Zhou1,2.3, Tianshu Liu1,2, Yizhuo Sun1,2, Ying Cheng1,2, Renbi Bai1,2,3 |
| Units: 1.Centert for Separation and Purification Materials and Technologies, Suzhou 215009, China; 2.School of Environment and Science and Engineering, Suzhou, Unuversity of Science and Technology, Suzhou, 215009, China 3. Jiangsu Collabrative Innovation Center of Technology and Material Treatment, Suzhou, Unuversity of Science and Technology, Suzhou, 215009, China |
| KeyWords: zwitterionic copolymers, modified PVDF membranes, anti-fouling performance |
| ClassificationCode:TQ028.8 |
| year,volume(issue):pagination: 2021,41(4):84-92 |
|
Abstract: |
| A zwitterion polymer P(Stx-co-CBMAy) was obtained from carboxylic betaine methyl acrylate (CBMA) and styrene (St) by reactive radical polymerization. The modified PVDF membranes were prepared by immersion precipitate phase transformation (NIPS) with addition of polymer and the properties of the membrane were tested and studied. By anylasis of ATR-FTIR and XPS, the zwitterion polymers were enriched on the surface of the modified membrane which obviously affected membrane microstructure includes surface and section structure. The porosity and thickness of the modified membrane increased obviously. The membranes surface charge distribution were changed and the isoelectric point increases due to the addition of zwitterion polymer, which has a certain effect on the anti-fouling performance of the membrane. Under the condition of static adsorption, the adsorption capacity of 1.0 g/L BSA and LYZ solution at pH=5.3 by modified membrane was significantly reduced showing excellent anti-fouling performance. Dynamic filtration experiments of BSA and SA showed that most of the pollution of modified membranes M-P1 to BSA and SA was reversible, and the flux recovery rate of the modified membranes maintained a high level. |
|
Funds: |
| 江苏水处理技术与材料协同创新中心预研项目(XTCXSZ2019-4)苏州分离净化材料与技术重点实验室(SZS201512) |
|
AuthorIntro: |
| 周晓吉(1988- ),女,硕士研究生,实验师,研究方向为高分子材料的制备及其对膜的改性。 |
|
Reference: |
|
[1] Burnouf T, Radosevich M, Nanofiltration of plasma-derived biopharmaceutical products[J], Haemophilia, 2003, 9: 24–37. [2] Bruggen B V, Vandecasteele C, Removal of pollutants from surface water and groundwater by nanofiltration: overview of possible applications in the drinking water industry[J], Environ Pollut, 2003, 122 (3): 435–445. [3] Baker R W, Membrane Technology and Applications, 2nd ed.[M], J Wiley, Chichester; New York, 2004. [4] Liu F, Hashim N A, Liu Y, Moghareh M R A, Li K, Progress in the production and modification of PVDF membranes[J], J Membr Sci, 2011, 375 (1/2): 1–27. [5] Kang G., Cao Y., Development of antifouling reverse osmosis membranes for water treatment: a review[J], Water Res, 2012, 46 (3): 584–600. [6] 程莹, 蒋文韬, 张迪, 白仁碧, 周晓吉, 两性离子聚合物改性高分子膜抗污染性能的研究进展[J]. 膜科学与技术, 2019, 39 (03), 142-149. [7] Chen S., Li L., Zhao C., Zheng J., Surface hydration: principles and applications toward low-fouling/nonfouling biomaterials[J], Polymer, 2010, 51 (23): 5283–5293. [8] Lowe A B, McCormick C L, Synthesis and solution properties of zwitterionic polymers[J], Chem Rev, 2002, 102 (11): 4177–4189. [9] Feng W, Brash J L, Zhu S P, Non-biofouling materials prepared by atom transfer radical polymerization grafting of 2-methacryloloxyethyl phosphorylcholine: separate effects of graft density and chain length on protein repulsion[J], Biomaterials, 2006, 27 (6): 847–855. [10]Zhang Z, Chen S F, Chang Y, et al, Surface grafted sulfobetaine polymers via atom transfer radical polymerization as superlow fouling coatings[J], J Phys Chem B, 2006, 110 (22): 10799–10804. [11]Cheng G, Li G, Xue H, et al, Zwitterionic carboxybetaine polymer surfaces and their resistance to long-term biofilm formation[J], Biomaterials, 2009, 30 (28): 5234–5240. [12]Yang Q, Ulbricht M., Novel membrane adsorbers with grafted zwitterionic polymers synthesized by surface-initiated ATRP and their salt-modulated permeability and protein binding properties[J], Chem. Mater.. 2012, 24 (15): 2943–2951. [13]Li Q, Bi Q Y, Zhou B, et al, Zwitterionic sulfobetaine-grafted poly(vinylidene flfluoride) membrane surface with stably anti-protein-fouling performance via a two-step surface polymerization[J], Appl Surf Sci, 2012, 258 (10): 4707–4717. [14] 胡丹, 肖维新, 王晓琳, 聚电解质改性PVDF膜及其抗蛋白质污染研究[J], 膜科学与技术, 2020, 40(04): 62-71. [15]Rohani M M, Zydney A L, Protein transport through zwitterionic ultrafifiltration membranes, J Membr Sci, 2012, 397-398(7): 1–8. [16]Yang R, Gleason K K, Ultrathin antifouling coatings with stable surface zwitterionic functionality by initiated chemical vapor deposition (iCVD)[J], Langmuir, 2012, 28: 12266–12274. [17]Yang R, Xu J J, Ozaydin-Ince G, et al, Surface-tethered zwitterionic ultrathin antifouling coatings on reverse osmosis membranes by initiated chemical vapor deposition[J], Chem Mater, 2011, 23(5): 1263–1272. [18]Yue W W, Li H J, Xiang T, et al, Grafting of zwitterion from polysulfone membrane via surface-initiated ATRP with enhanced antifouling property and biocompatibility[J], J Membr Sci, 2013, 446 (21): 79–91. [19]Ladd J., Zhang Z, Chen S, et al. Zwitterionic Polymers Exhibiting High Resistance to Nonspecific Protein Adsorption from Human Serum and Plasma[J], Biomacromolecules, 2008, 9 (5):1357-1361. [20]Xu C, Liu X, Xie B, et al. Preparation of PES ultrafiltration membranes with natural amino acids based zwitterionic antifouling surfaces[J]. Appl Surf Sci. 2016, 385 (27), 130-138. [21]Yang Y, Ramos T L, Heo J, et al. Zwitterionic poly(arylene ether sulfone) copolymer/poly(arylene ether sulfone) blends for fouling-resistant desalination membranes[J]. J Membr Sci, 2018, 561 (17): 69-78. [22]Dizon G V, Venault A. Direct in-situ modification of PVDF membranes with a zwitterionic copolymer to form bi-continuous and fouling resistant membranes[J]. J Membr Sci, 2018, 550 (6): 45-58. [23]Han, Y, Song S J, Lu Y, et al. A method to modify PVDF microfiltration membrane via ATRP with low-temperature plasma pretreatment[J]. Appl Surf Sci, 2016, 379 (21): 474–479. [24]J. Ladd, Z. Zhang, S. Chen, et al. Biomacromolecules, 2008, 9(5), 1357-1361 [25]李妍, 周晓吉, 沈舒苏, 杨晶晶, 白仁碧. 一种两亲性共聚物的合成及其对PVDF膜的改性研究[J]. 膜科学与技术, 2016, 36 (12), 78-85. [26]陆茵, PVDF相转化成膜机理及制膜规律研究[D], 浙江: 浙江大学, 2003. [27]Broens L, Koenhen D M, Smolders C A, On the mechanism of formation of asymmetric ultra- and hyper-filtration membranes[J]. Desalination, 1977, 22(1-3), 205-219. [28]Mulder MHV, Hendrikman J O, Wijnans J G, et al. A rationale for the preparation of asymmetric pervaporation membranes[J]. J. Appl. Polym Sci, 1985, 30 (7), 2805-2820. [29]徐又一, 徐志康, 高分子膜材料[M]. 北京, 化学工业出版社, 2005, 19-72. |
|
Service: |
| 【Download】【Collect】 |
《膜科学与技术》编辑部 Address: Bluestar building, 19 east beisanhuan road, chaoyang district, Beijing; 100029 Postal code; Telephone:010-80492417/010-80485372; Fax:010-80485372 ; Email:mkxyjs@163.com
京公网安备11011302000819号