Shenqiu Mo scite author profile

Shenqiu Mo

2Publications

45Citation Statements Received

97Citation Statements Given

How they've been cited

102

How they cite others

144

Affiliations

Huazhong University of Science and Technology, Interface (United Kingdom), National Institute of Clean and Low-Carbon Energy

Publications

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Unexpectedly high cross-plane thermoelectric performance of layered carbon nitrides

Ding

et al. 2019

J. Mater. Chem. A

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Organic thermoelectric (TE) materials create a brand new perspective to search for high-efficiency TE materials, due to their small thermal conductivity. The overlap of pz orbitals, commonly existing in organic π-stacking semiconductors, can potentially result in high electronic mobility comparable to inorganic electronics. Here we propose a strategy to utilize the overlap of pz orbitals to increase the TE efficiency of layered polymeric carbon nitride (PCN). Through first-principles calculations and classical molecular dynamics simulations, we find that A-A stacked PCN has unexpectedly high cross-plane ZT up to 0.52 at 300 K, which can contribute to n-type TE groups. The high ZT originates from its one-dimensional charge transport and small thermal conductivity. The thermal contribution of the overlap of pz orbitals is investigated, which noticeably enhances the thermal transport when compared with the thermal conductivity without considering the overlap effect. For a better understanding of its TE advantages, we find that the low-dimensional charge transport results from strong pz-overlap interactions and the in-plane electronic confinement, by comparing π-stacking carbon nitride derivatives and graphite. This study can provide a guidance to search for high cross-plane TE performance in layered materials.

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Ultra-fast vapor generation by a graphene nano-ratchet: a theoretical and simulation study

Ding

Peng

et al. 2017

Nanoscale

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Vapor generation is of prime importance for a broad range of applications: domestic water heating, desalination and wastewater treatment, etc. However, the natural evaporation is slow and low efficiency. Ratchet effect can give rise to nonzero mass flux under a zero-mean time-dependent drive. In this paper, we proposed a nano-ratchet, multilayer graphene with cone-shaped nanopores (MGCN), to accelerate the vapor generation. By performing molecular dynamics simulations, we found that the air molecules spontaneously transport across MGCN and form a remarkable pressure difference between the two sides of MGCN. Besides, we studied the dependence of pressure difference on the ambient temperature and the geometry of MGCN in detail.By further analysis of the diffusive transport, we identified that the pressure difference relates to the competition between ratchet transport and Knudsen diffusion. The pressure difference could give rise to 15 times enhancement of vapor generation at least, which shows there is a widely potential application of the ratchet effect of MGCN.

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Shenqiu Mo

Unexpectedly high cross-plane thermoelectric performance of layered carbon nitrides

Ultra-fast vapor generation by a graphene nano-ratchet: a theoretical and simulation study

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