The scientist’s investigation covers issues in Permittivity, Composite material, Dielectric, Metamaterial and Drude model. His Permittivity study deals with the bigger picture of Optoelectronics. The study incorporates disciplines such as Dielectric loss and Relative permittivity in addition to Composite material.
His work deals with themes such as Composite number, Nickel, Amorphous carbon and Capacitor, which intersect with Dielectric. His Metamaterial research is multidisciplinary, relying on both Magnetic flux, Carbonization, Nanocomposite and Microstructure. His biological study deals with issues like Percolation threshold, which deal with fields such as Permeability.
Runhua Fan mainly focuses on Composite material, Permittivity, Dielectric, Metamaterial and Microstructure. His study explores the link between Composite material and topics such as Dielectric loss that cross with problems in Reflection loss. Runhua Fan interconnects Drude model, Percolation threshold, Conductivity and Electromagnetic shielding in the investigation of issues within Permittivity.
His work in Dielectric covers topics such as Electrical conductor which are related to areas like Plasma oscillation. His Metamaterial research is under the purview of Optoelectronics. Runhua Fan combines subjects such as Porosity and Permeability with his study of Microstructure.
Runhua Fan focuses on Composite material, Permittivity, Dielectric, Metamaterial and Electromagnetic shielding. His biological study spans a wide range of topics, including Dielectric loss, Conductivity and Capacitor. His work carried out in the field of Permittivity brings together such families of science as Plasmon, Ceramic, Electrical resistivity and conductivity, Plasma oscillation and Electrical conductor.
His studies in Dielectric integrate themes in fields like Thermal conduction, Nanocomposite, Percolation threshold and Nickel. When carried out as part of a general Metamaterial research project, his work on Negative refraction is frequently linked to work in Engineering physics and Work, therefore connecting diverse disciplines of study. In his study, Yttrium iron garnet and Ferromagnetism is strongly linked to Diamagnetism, which falls under the umbrella field of Electromagnetic shielding.
His primary areas of investigation include Permittivity, Composite material, Dielectric, Electrical resistivity and conductivity and Composite number. His Permittivity research includes themes of Plasmon, Ceramic, Electromagnetic shielding, Graphene and Metamaterial. His Metamaterial study deals with Percolation threshold intersecting with Aluminium and Nickel.
Much of his study explores Composite material relationship to Capacitor. His research in the fields of Dielectric loss overlaps with other disciplines such as Spatial distribution. His research investigates the connection between Electrical resistivity and conductivity and topics such as Drude model that intersect with problems in Conductivity, Silicon nitride, Thermal conductivity, Temperature coefficient and Absorption.
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Flexible polydimethylsiloxane/multi-walled carbon nanotubes membranous metacomposites with negative permittivity
Kai Sun;Kai Sun;Kai Sun;Peitao Xie;Zhongyang Wang;Tongming Su.
Bio-gel derived nickel/carbon nanocomposites with enhanced microwave absorption
Peitao Xie;Hongyu Li;Biao He;Feng Dang.
Journal of Materials Chemistry C (2018)
Random Composites of Nickel Networks Supported by Porous Alumina Toward Double Negative Materials
Zhi-cheng Shi;Run-hua Fan;Zi-dong Zhang;Lei Qian.
Advanced Materials (2012)
Oxygen vacancy derived local build-in electric field in mesoporous hollow Co3O4 microspheres promotes high-performance Li-ion batteries
Chuanxin Hou;Yue Hou;Yuqi Fan;Yanjie Zhai.
Journal of Materials Chemistry (2018)
3D Interconnected Porous Carbon Aerogels as Sulfur Immobilizers for Sulfur Impregnation for Lithium‐Sulfur Batteries with High Rate Capability and Cycling Stability
Zhiwei Zhang;Zhaoqiang Li;Fengbin Hao;Xuekun Wang.
Advanced Functional Materials (2014)
Tunable and weakly negative permittivity in carbon/silicon nitride composites with different carbonizing temperatures
Chuanbing Cheng;Chuanbing Cheng;Chuanbing Cheng;Runhua Fan;Zhongyang Wang;Qian Shao.
An Overview of Electrically Conductive Polymer Nanocomposites toward Electromagnetic Interference Shielding
Longfei Lyu;Jiurong Liu;Hu Liu;Chuntai Liu.
Engineered Science (2018)
Carbon nanospheres induced high negative permittivity in nanosilver-polydopamine metacomposites
Hongbo Gu;Xiaojiang Xu;Mengyao Dong;Mengyao Dong;Peitao Xie.
Tunneling-induced negative permittivity in Ni/MnO nanocomposites by a bio-gel derived strategy
Peitao Xie;Yifan Li;Qing Hou;Kunyan Sui.
Journal of Materials Chemistry C (2020)
Preparation of Iron Networks Hosted in Porous Alumina with Tunable Negative Permittivity and Permeability
Zhi-cheng Shi;Run-hua Fan;Ke-lan Yan;Kai Sun.
Advanced Functional Materials (2013)
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