| Stimuli responsive conductive polyaniline membrane: in-filtration electrical tuneability and anti-fouling performance |
| Authors: Lili Xu 1,2,3,4,5, Emma Emanuelsson 2, Jun Wang 1,3,4,5 |
| Units: 1. State Key Laboratory of Environmental Aquatic Chemistry, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, 18 Shuangqing Road, Beijing, 100085, China 2. Department of Chemical Engineering, University of Bath, Bath, United Kingdom, BA2 7AY. 3. National Engineering Laboratory for Industrial Wastewater Treatment, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, 18 Shuangqing Road, Beijing, 100085, China 4. National Engineering Laboratory for Industrial Wastewater Treatment, Research Centre for Eco-Environmental Sciences, Chinese Academy of Sciences, 18 Shuangqing Road, Beijing, 100085, China. 5. University of Chinese Academy of Sciences, 19 Yuquan Road, Beijing, 100049, China |
| KeyWords: polyaniline, electrically tuneablility, membrane fouling, smart membrane |
| ClassificationCode:TQ028.8 |
| year,volume(issue):pagination: 2018,38(3):55-62 |
|
Abstract: |
|
As conventional membranes cannot have their physical and chemical properties tuned in-situ to offer control of membrane performance during operation, there is a need for stimuli responsive membranes which can self-regulatively adjust their performance in response to chemical and/or physical stimuli in the environments. Despite extensive efforts in designing electrically conductive polyaniline (PANI) membranes, there remains an insufficient understanding of the electrically induced transformations in these membranes, especially the control over membrane separation and transportation through the application of electrical potentials. In this study, we focused on the electrical tuneability of PANI membrane in response to the externally applied potential and firstly proposed the hypothesis of electrical tuneability in PANI membranes. PANI was synthesised via chemical oxidation of aniline whereby PAMPSA serve as templates and flat sheet PANI membranes were prepared via non-solvent induced phase separation (NIPS). In terms of tuneable properties under applied electrical potential, the permeance of the in-situ doped PANI-PAMPSA membrane could be varied during cross-flow filtration and bovine serum albumin (BSA) foulant could be removed. This new PANI synthesis method therefore opens the pathway for more filtration stable electrically tuneable membranes to be produced, enabling a new range of applications to be developed (such as anti-fouling membranes). |
|
Funds: |
| 国家重点研发计划课题2016YFC0400501,国家自然科学基金51578533 |
|
AuthorIntro: |
| 徐莉莉,1988年11月,山东蓬莱,研究方向:电响应膜制备与应用,E-mail:xllmyname@163.com |
|
Reference: |
|
[1] F. Meng, S.-R. Chae, A. Drews, M. Kraume, H.-S. Shin, F. Yang, Recent advances in membrane bioreactors (MBRs): membrane fouling and membrane material, Water research, 43 (2009) 1489-1512. [2] A. Drews, Membrane fouling in membrane bioreactors—characterisation, contradictions, cause and cures, Journal of membrane science, 363 (2010) 1-28. [3] R.B. Kaner, Gas, liquid and enantiomeric separations using polyaniline, Synthetic metals, 125 (2001) 65-71. [4] D. Roy, J.N. Cambre, B.S. Sumerlin, Future perspectives and recent advances in stimuli-responsive materials, Progress in Polymer Science, 35 (2010) 278-301. [5] C. Liangyin, X. Rui, J. Xiaojie, Stimuli-responsive membranes: smart tools for controllable mass-transfer and separation processes, Chinese Journal of Chemical Engineering, 19 (2011) 891-903. [6] D. Wandera, S.R. Wickramasinghe, S.M. Husson, Stimuli-responsive membranes, Journal of Membrane Science, 357 (2010) 6-35. [7] M.A.C. Stuart, W.T. Huck, J. Genzer, M. Müller, C. Ober, M. Stamm, G.B. Sukhorukov, I. Szleifer, V.V. Tsukruk, M. Urban, Emerging applications of stimuli-responsive polymer materials, Nature materials, 9 (2010) 101-113. [8] D.L. Pile, A.C. Hillier, Electrochemically modulated transport through a conducting polymer membrane, Journal of membrane science, 208 (2002) 119-131. [9] C. Weidlich, K.-M. Mangold, Electrochemically switchable polypyrrole coated membranes, Electrochimica Acta, 56 (2011) 3481-3484. [10] S. Bhadra, D. Khastgir, N.K. Singha, J.H. Lee, Progress in preparation, processing and applications of polyaniline, Progress in Polymer Science, 34 (2009) 783-810. [11] E. Genies, A. Boyle, M. Lapkowski, C. Tsintavis, Polyaniline: a historical survey, Synthetic Metals, 36 (1990) 139-182. [12] M. Sairam, S.K. Nataraj, T.M. Aminabhavi, S. Roy, C.D. Madhusoodana, Polyaniline Membranes for Separation and Purification of Gases, Liquids, and Electrolyte Solutions, Separation & Purification Reviews, 35 (2006) 249-283. [13] J. Pellegrino, The Use of Conducting Polymers in Membrane‐Based Separations, Annals of the New York Academy of Sciences, 984 (2003) 289-305. [14] E.M. Andrade, F.V. Molina, M.I. Florit, D. Posadas, Volume Changes of Poly (2‐methylaniline) upon Redox Switching Anion and Relaxation Effects, Electrochemical and Solid-State Letters, 3 (2000) 504-507. [15] L. Xu, S. Shahid, J. Shen, E. Emanuelsson, D.A. Patterson, A wide range and high resolution one-filtration molecular weight cut-off method for aqueous based nanofiltration and ultrafiltration membranes, Journal of Membrane Science, 525 (2017) 304–311. [16] C. Yan, L. Zou, R. Short, Polyaniline-modified activated carbon electrodes for capacitive deionisation, Desalination, 333 (2014) 101-106. [17] X.M. Feng, R.M. Li, Y.W. Ma, R.F. Chen, N.E. Shi, Q.L. Fan, W. Huang, One‐Step Electrochemical Synthesis of Graphene/Polyaniline Composite Film and Its Applications, Advanced Functional Materials, 21 (2011) 2989-2996. [18] K.R. Reddy, B.C. Sin, K.S. Ryu, J. Noh, Y. Lee, In situ self-organization of carbon black–polyaniline composites from nanospheres to nanorods: Synthesis, morphology, structure and electrical conductivity, Synthetic Metals, 159 (2009) 1934-1939. [19] J. Jang, J. Ha, J. Cho, Fabrication of Water‐Dispersible Polyaniline‐Poly (4‐styrenesulfonate) Nanoparticles For Inkjet‐Printed Chemical‐Sensor Applications, Advanced materials, 19 (2007) 1772-1775. [20] L. Hechavarr??a, H. Hu, M.E. Rincón, Polyaniline–poly (2-acrylamido-2-methyl-1-propanosulfonic acid) composite thin films: structure and properties, Thin Solid Films, 441 (2003) 56-62. [21] O. Misoon, K. Seok, Effect of dodecyl benzene sulfonic acid on the preparation of polyaniline/activated carbon composites by in situ emulsion polymerization, Electrochimica Acta, 59 (2012) 196-201. [22] J.-W. Jeon, J. O’Neal, L. Shao, J.L. Lutkenhaus, Charge storage in polymer acid-doped polyaniline-based layer-by-layer electrodes, ACS applied materials & interfaces, 5 (2013) 10127-10136. [23] R. Rohani, Linking the Microstructural and Separation Properties of Electrically Tuneable Polyaniline Pressure Filtration Membranes, in, University of Auckland, Auckland, 2013. [24] L. Xu, S. Shahid, A.K. Holda, E.A.C. Emanuelsson, D.A. Patterson, Stimuli responsive conductive polyaniline membrane: In-filtration electrical tuneability of flux and MWCO, Journal of Membrane Science, 552 (2018) 153-166. |
|
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