Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene
Synthetic water channels offer great promise to replace natural aquaporins (AQPs) for making new‐generation biomimetic membranes for water treatment. However, the water permeability of the current synthetic water channels is still far below that of AQPs. Here, peptide‐attached (pR)‐pillar[5]arene (p...
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sg-ntu-dr.10356-1439192020-10-03T20:11:11Z Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene Li, Qing Li, Xuesong Ning, Lulu Tan, Choon-Hong Mu, Yuguang Wang, Rong School of Civil and Environmental Engineering School of Biological Sciences School of Physical and Mathematical Sciences Singapore Membrane Technology Centre Engineering::Environmental engineering Diastereomers Pillar[5]arene Synthetic water channels offer great promise to replace natural aquaporins (AQPs) for making new‐generation biomimetic membranes for water treatment. However, the water permeability of the current synthetic water channels is still far below that of AQPs. Here, peptide‐attached (pR)‐pillar[5]arene (pR‐PH) channels are reported to mimic the high permeability of AQPs. It is demonstrated that the pR‐PH channels with an open pore can transport water smoothly and efficiently. The pR‐PH channels are competitive with AQPs in terms of water permeability and are much superior to diastereomer peptide‐attached (pS)‐pillar[5]arene (pS‐PH) and other reported synthetic water channels. The exceptional water‐transport properties of the pR‐PH channels are further demonstrated in a composite polymeric membrane that incorporates the nanochannels into the top selective layer. This membrane gives a significantly improved water flux while retaining high salt rejection. The results establish a tangible foundation for developing highly efficient artificial water channel‐based biomimetic membrane for water purification applications. Economic Development Board (EDB) National Research Foundation (NRF) Public Utilities Board (PUB) Accepted version The authors thank Prof. William B. Krantz from University of Colorado for comments on the manuscript and for editing the text. This work was supported by PUB, Singapore’s National Water Agency and a grant from the Singapore National Research Foundation (EWI 1501-IRIS-04). The funding support from the Singapore Economic Development Board to the Singapore Membrane Technology Centre (SMTC) is gratefully acknowledged. 2020-10-01T03:10:38Z 2020-10-01T03:10:38Z 2019 Journal Article Li, Q., Li, X., Ning, L., Tan, C.-H., Mu, Y., & Wang, R. (2019). Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene. Small, 15(6), 1804678-. doi:10.1002/smll.201804678 1613-6810 https://hdl.handle.net/10356/143919 10.1002/smll.201804678 30637936 6 15 en Small This is the accepted version of the following article: Li, Q., Li, X., Ning, L., Tan, C.-H., Mu, Y., & Wang, R. (2019). Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene. Small, 15(6), 1804678-. doi:10.1002/smll.201804678, which has been published in final form at http://doi.org/10.1002/smll.201804678. This article may be used for non-commercial purposes in accordance with the Wiley Self-Archiving Policy [https://authorservices.wiley.com/authorresources/Journal-Authors/licensing/self-archiving.html]. application/pdf |
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Engineering::Environmental engineering Diastereomers Pillar[5]arene Li, Qing Li, Xuesong Ning, Lulu Tan, Choon-Hong Mu, Yuguang Wang, Rong Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene |
| description |
Synthetic water channels offer great promise to replace natural aquaporins (AQPs) for making new‐generation biomimetic membranes for water treatment. However, the water permeability of the current synthetic water channels is still far below that of AQPs. Here, peptide‐attached (pR)‐pillar[5]arene (pR‐PH) channels are reported to mimic the high permeability of AQPs. It is demonstrated that the pR‐PH channels with an open pore can transport water smoothly and efficiently. The pR‐PH channels are competitive with AQPs in terms of water permeability and are much superior to diastereomer peptide‐attached (pS)‐pillar[5]arene (pS‐PH) and other reported synthetic water channels. The exceptional water‐transport properties of the pR‐PH channels are further demonstrated in a composite polymeric membrane that incorporates the nanochannels into the top selective layer. This membrane gives a significantly improved water flux while retaining high salt rejection. The results establish a tangible foundation for developing highly efficient artificial water channel‐based biomimetic membrane for water purification applications. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Li, Qing Li, Xuesong Ning, Lulu Tan, Choon-Hong Mu, Yuguang Wang, Rong |
| format |
Article |
| author |
Li, Qing Li, Xuesong Ning, Lulu Tan, Choon-Hong Mu, Yuguang Wang, Rong |
| author_sort |
Li, Qing |
| title |
Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene |
| title_short |
Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene |
| title_full |
Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene |
| title_fullStr |
Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene |
| title_full_unstemmed |
Hyperfast water transport through biomimetic nanochannels from peptide-attached (pR)-pillar[5]arene |
| title_sort |
hyperfast water transport through biomimetic nanochannels from peptide-attached (pr)-pillar[5]arene |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143919 |
| _version_ |
1681059808211369984 |