We study the mechanism of van der Waals(vdW)interactions on phonon transport in atomic scale,which would boost developments in heat management and energy conversion.Commonly,the vdW interactions are regarded as a hind...We study the mechanism of van der Waals(vdW)interactions on phonon transport in atomic scale,which would boost developments in heat management and energy conversion.Commonly,the vdW interactions are regarded as a hindrance in phonon transport.Here we propose that the vdW confinement can enhance phonon transport.Through molecular dynamics simulations,it is realized that the vdW confinement is able to make more than two-fold enhancement on thermal conductivity of both polyethylene single chain and graphene nanoribbon.The quantitative analyses of morphology,local vdW potential energy and dynamical properties are carried out to reveal the underlying physical mechanism.It is found that the confined vdW potential barriers reduce the atomic thermal displacement magnitudes,leading to less phonon scattering and facilitating thermal transport.Our study offers a new strategy to modulate the phonon transport.展开更多
Leidenfrost effect is a common and important phenomenon which has many applications,however there is a limited body of knowledge about the Leidenfrost effect at the nanoscale regime.We investigate the impact of substr...Leidenfrost effect is a common and important phenomenon which has many applications,however there is a limited body of knowledge about the Leidenfrost effect at the nanoscale regime.We investigate the impact of substrate wettability on Leidenfrost point temperature(LPT) of nanoscale water film via molecular dynamics simulations,and reveal a new mechanism different from that at the macroscale.In the molecular dynamics simulations,a method of monitoring density change at different heating rates is proposed to obtain accurate LPT under different surface wettability.The results show that LPT decreases firstly and then increases with the surface wettability at the nanoscale,which is different from the monotonous increasing trend at the macroscale.The mechanism is elucidated by analyzing the competitive effect of adhesion force and interfacial thermal resistance,as well as different contributions of gravity on LPT at the nanoscale and macroscale.The investigations can deepen the understanding of Leidenfrost effect at the nanoscale regime and also facilitate to guide the applications of heat transfer and flow transport.展开更多
基金Supported by the National Natural Science Foundation of China(Grant Nos.51606072 and 51576077).
文摘We study the mechanism of van der Waals(vdW)interactions on phonon transport in atomic scale,which would boost developments in heat management and energy conversion.Commonly,the vdW interactions are regarded as a hindrance in phonon transport.Here we propose that the vdW confinement can enhance phonon transport.Through molecular dynamics simulations,it is realized that the vdW confinement is able to make more than two-fold enhancement on thermal conductivity of both polyethylene single chain and graphene nanoribbon.The quantitative analyses of morphology,local vdW potential energy and dynamical properties are carried out to reveal the underlying physical mechanism.It is found that the confined vdW potential barriers reduce the atomic thermal displacement magnitudes,leading to less phonon scattering and facilitating thermal transport.Our study offers a new strategy to modulate the phonon transport.
基金Supported by the National Key Research and Development Program of China(Grant No.2018YFE0127800)。
文摘Leidenfrost effect is a common and important phenomenon which has many applications,however there is a limited body of knowledge about the Leidenfrost effect at the nanoscale regime.We investigate the impact of substrate wettability on Leidenfrost point temperature(LPT) of nanoscale water film via molecular dynamics simulations,and reveal a new mechanism different from that at the macroscale.In the molecular dynamics simulations,a method of monitoring density change at different heating rates is proposed to obtain accurate LPT under different surface wettability.The results show that LPT decreases firstly and then increases with the surface wettability at the nanoscale,which is different from the monotonous increasing trend at the macroscale.The mechanism is elucidated by analyzing the competitive effect of adhesion force and interfacial thermal resistance,as well as different contributions of gravity on LPT at the nanoscale and macroscale.The investigations can deepen the understanding of Leidenfrost effect at the nanoscale regime and also facilitate to guide the applications of heat transfer and flow transport.