His primary areas of study are Band gap, Condensed matter physics, Carbon, Nanotechnology and Graphene. His studies in Band gap integrate themes in fields like Electron mobility, Monolayer, Semiconductor, Atom and Silicene. His research in Condensed matter physics tackles topics such as Fermi level which are related to areas like Antiferromagnetism.
While the research belongs to areas of Carbon, he spends his time largely on the problem of Chemical physics, intersecting his research to questions surrounding Adsorption, Graphyne, Boron, Nitrogen and Substitution reaction. As part of one scientific family, Mingwen Zhao deals mainly with the area of Nanotechnology, narrowing it down to issues related to the Diffusion, and often Binding energy, MXenes, Electrolyte, Dissolution and Intercalation. The study incorporates disciplines such as Ab initio quantum chemistry methods and Dirac in addition to Graphene.
The scientist’s investigation covers issues in Condensed matter physics, Band gap, Nanotechnology, Graphene and Chemical physics. Mingwen Zhao interconnects Monolayer and Fermi level in the investigation of issues within Condensed matter physics. His research integrates issues of Silicene, Nanowire, Semiconductor and Topological insulator in his study of Band gap.
Many of his research projects under Nanotechnology are closely connected to Zigzag with Zigzag, tying the diverse disciplines of science together. His Graphene study combines topics from a wide range of disciplines, such as Fermi energy, Lattice and Dirac. His Chemical physics study also includes
His primary areas of study are Monolayer, Condensed matter physics, Oxygen evolution, Water splitting and Graphene. His Monolayer research integrates issues from Ion, Anode, Lithium sulfur and Energy conversion efficiency. Particularly relevant to Superconductivity is his body of work in Condensed matter physics.
His Oxygen evolution research is multidisciplinary, incorporating perspectives in Chemical physics, Catalysis and Metal-organic framework. Mingwen Zhao has included themes like Electrocatalyst and Hydrogen in his Water splitting study. His Graphene research incorporates themes from Hamiltonian, Nanomaterials and Molecular dynamics.
His scientific interests lie mostly in Oxygen evolution, Water splitting, Monolayer, Photocatalysis and Chemical physics. His Monolayer research incorporates elements of Ion, Polarization, Anode and Ferroelectricity. His Chemical physics study integrates concerns from other disciplines, such as Nanomaterials, Graphene and Molecular dynamics.
The various areas that Mingwen Zhao examines in his Photocatalytic water splitting study include Electron mobility, Electric field and Band gap. His work in Band gap covers topics such as Hydrogen which are related to areas like Condensed matter physics, Nanowire and Metal. His Condensed matter physics research is multidisciplinary, incorporating elements of Fermi level and Gibbs free energy.
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Broadband Few‐Layer MoS2 Saturable Absorbers
Shuxian Wang;Haohai Yu;Huaijin Zhang;Aizhu Wang.
Advanced Materials (2014)
From UV to Near‐Infrared, WS2 Nanosheet: A Novel Photocatalyst for Full Solar Light Spectrum Photodegradation
Yuanhua Sang;Zhenhuan Zhao;Mingwen Zhao;Pin Hao.
Advanced Materials (2015)
Phagraphene: A Low-Energy Graphene Allotrope Composed of 5-6-7 Carbon Rings with Distorted Dirac Cones.
Zhenhai Wang;Xiang-Feng Zhou;Xiaoming Zhang;Qiang Zhu.
Nano Letters (2015)
Strain energy and electronic structures of silicon carbide nanotubes: Density functional calculations
Mingwen Zhao;Yueyuan Xia;Feng Li;R. Q. Zhang.
Physical Review B (2005)
Exfoliation of hexagonal boron nitride by molten hydroxides.
Xianlei Li;Xiaopeng Hao;Mingwen Zhao;Yongzhong Wu.
Advanced Materials (2013)
Tunable electronic structures of graphene/boron nitride heterobilayers
Yingcai Fan;Mingwen Zhao;Zhenhai Wang;Xuejuan Zhang.
Applied Physics Letters (2011)
High Mobility and High Storage Capacity of Lithium in sp–sp2 Hybridized Carbon Network: The Case of Graphyne
Hongyu Zhang;Mingwen Zhao;Xiujie He;Zhenhai Wang.
Journal of Physical Chemistry C (2011)
Ultrabroadband MoS2 Photodetector with Spectral Response from 445 to 2717 nm.
Ying Xie;Bo Zhang;Shuxian Wang;Dong Wang.
Advanced Materials (2017)
Stability and electronic structure of AlN nanotubes
Mingwen Zhao;Yueyuan Xia;Dongju Zhang;Liangmo Mei.
Physical Review B (2003)
A Photoresponsive Rutile TiO2 Heterojunction with Enhanced Electron-Hole Separation for High-Performance Hydrogen Evolution.
Chaomin Gao;Tao Wei;Yanyan Zhang;Xiaohan Song.
Advanced Materials (2019)
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