Chen Qu, Wang Qi, Liu Ying-Chun, Wu Tao
Soft Matter Research Center and Department of Chemistry, Zhejiang University, Hangzhou 310027, People's Republic of China.
J Chem Phys. 2014 Jun 7;140(21):214507. doi: 10.1063/1.4879796.
Nanopores can serve as a molecule channel for transport of fluid, where water diffusion differs remarkably from that of simple particles. Hydrogen bonds play an essential role in the diffusion anomaly. Detailed investigations are carried out on the systems of rigid (6, 6), (7, 7), (8, 8), (9, 9), and (10, 10) armchair carbon nanotubes, solvated with Lennard-Jones water fluids. The role of hydrogen bonds is examined by diffusivity statistics and animation snapshots. It is found that in small (6,6) CNT, hydrogen bonds tend to aggregate water into a wire and lead to rapid collective drift. Confinement can stabilize the hydrogen bond of water molecules and enhance its lifetime. In relatively smaller CNTs, the diffusion mechanism could be altered by the temperature. Moreover, in larger nanotubes hydrogen bonding network allows the water to form regional concentrated clusters. This allows water fluid in extremely low density exhibit rather slow self-diffusion motion. This fundamental study attempts to provide insights in understanding nanoscale delivery system in aqueous solution.
纳米孔可作为流体传输的分子通道,其中水的扩散与简单粒子的扩散有显著差异。氢键在扩散异常中起着至关重要的作用。对用 Lennard-Jones 水流体溶剂化的刚性(6,6)、(7,7)、(8,8)、(9,9)和(10,10)扶手椅型碳纳米管系统进行了详细研究。通过扩散率统计和动画快照来研究氢键的作用。研究发现,在小尺寸的(6,6)碳纳米管中,氢键倾向于将水聚集成线状并导致快速的集体漂移。限制作用可以稳定水分子的氢键并延长其寿命。在相对较小的碳纳米管中,扩散机制可能会因温度而改变。此外,在较大的纳米管中,氢键网络使水形成区域浓缩簇。这使得极低密度的水流体表现出相当缓慢的自扩散运动。这项基础研究试图为理解水溶液中的纳米级输送系统提供见解。