Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels
Molecular dynamics simulations have now been broadly applied to investigate membrane transport and optimize membrane design, but mostly for nanostructures without the involvement of phase change due to the enormous computational time and spatial scale requirements. In the present study, a coarse-gra...
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sg-ntu-dr.10356-1410592020-06-03T09:20:34Z Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels Zhang, Hui Liu, Bo Kieu, Hieu Trung Wu, Mao See Zhou, Kun Law, Adrian Wing-Keung School of Civil and Environmental Engineering School of Mechanical and Aerospace Engineering Environmental Process Modelling Centre Nanyang Environment and Water Research Institute Engineering::Environmental engineering Membrane Distillation Corse-grained Molecular Dynamics Molecular dynamics simulations have now been broadly applied to investigate membrane transport and optimize membrane design, but mostly for nanostructures without the involvement of phase change due to the enormous computational time and spatial scale requirements. In the present study, a coarse-grained molecular dynamics model is developed to overcome the limitations in simulating membrane distillation through meso-size (2-5 nm) channels formed by graphene bilayer at the direct contact mode. The new coarse-grained approach enables the comprehensive evaluation of the influences of channel opening, hydrostatic pressure, and temperature. In addition, the evaporation processes at the membrane surface as well as the water vapour transport can now be analysed in a statistically reliable manner. The coarse-grained results show that the permeate flux through the graphene bilayer channels is almost three-order-of-magnitude higher than the commonly used microporous polymer membranes nowadays, which demonstrate the significant application potential. Increasing the hydrostatic pressure is found to be uneconomical due to its limited effects. The enhanced evaporation at small channel opening is due to the elevated collisions among the interface water molecules. Most importantly, the permeate flux shows a non-monotonic dependence on the channel opening. The flux is highest when the channel opening is 2 nm, after which the dominant transport of water molecules inside the channel transit from surface diffusion to activated Knudsen transport. This finding has an important implication towards the design of graphene bilayer membranes for membrane distillation in the future. MOE (Min. of Education, S’pore) 2020-06-03T09:20:34Z 2020-06-03T09:20:34Z 2018 Journal Article Zhang, H., Liu, B., Kiew, H. T., Wu, M. S., Zhou, K., & Law, A. W.-K. (2018). Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels. Journal of Membrane Science, 558, 34-44. doi:10.1016/j.memsci.2018.04.043 0376-7388 https://hdl.handle.net/10356/141059 10.1016/j.memsci.2018.04.043 2-s2.0-85046755400 558 34 44 en Journal of Membrane Science © 2018 Elsevier B.V. All rights reserved |
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Engineering::Environmental engineering Membrane Distillation Corse-grained Molecular Dynamics Zhang, Hui Liu, Bo Kieu, Hieu Trung Wu, Mao See Zhou, Kun Law, Adrian Wing-Keung Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels |
| description |
Molecular dynamics simulations have now been broadly applied to investigate membrane transport and optimize membrane design, but mostly for nanostructures without the involvement of phase change due to the enormous computational time and spatial scale requirements. In the present study, a coarse-grained molecular dynamics model is developed to overcome the limitations in simulating membrane distillation through meso-size (2-5 nm) channels formed by graphene bilayer at the direct contact mode. The new coarse-grained approach enables the comprehensive evaluation of the influences of channel opening, hydrostatic pressure, and temperature. In addition, the evaporation processes at the membrane surface as well as the water vapour transport can now be analysed in a statistically reliable manner. The coarse-grained results show that the permeate flux through the graphene bilayer channels is almost three-order-of-magnitude higher than the commonly used microporous polymer membranes nowadays, which demonstrate the significant application potential. Increasing the hydrostatic pressure is found to be uneconomical due to its limited effects. The enhanced evaporation at small channel opening is due to the elevated collisions among the interface water molecules. Most importantly, the permeate flux shows a non-monotonic dependence on the channel opening. The flux is highest when the channel opening is 2 nm, after which the dominant transport of water molecules inside the channel transit from surface diffusion to activated Knudsen transport. This finding has an important implication towards the design of graphene bilayer membranes for membrane distillation in the future. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Zhang, Hui Liu, Bo Kieu, Hieu Trung Wu, Mao See Zhou, Kun Law, Adrian Wing-Keung |
| format |
Article |
| author |
Zhang, Hui Liu, Bo Kieu, Hieu Trung Wu, Mao See Zhou, Kun Law, Adrian Wing-Keung |
| author_sort |
Zhang, Hui |
| title |
Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels |
| title_short |
Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels |
| title_full |
Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels |
| title_fullStr |
Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels |
| title_full_unstemmed |
Coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels |
| title_sort |
coarse-grained molecular dynamics study of membrane distillation through meso-size graphene channels |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/141059 |
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1681058192606363648 |