Temperature-Dependent ac Conductivity of the Fibonacci Lattice
DING Jian-wen1 , YAN Xiao-hong1,2 , FANG Xian-cheng1
1 Department of Physics, Xiangtan University, Xiangtan 411105
2 Institute of Solid State Physics, Chinese Academy of Sciences, Hefei 230031
Temperature-Dependent ac Conductivity of the Fibonacci Lattice
DING Jian-wen1 ;YAN Xiao-hong1,2 ;FANG Xian-cheng1
1 Department of Physics, Xiangtan University, Xiangtan 411105
2 Institute of Solid State Physics, Chinese Academy of Sciences, Hefei 230031
关键词 :
72.80.-r ,
61.44.Br
Abstract : A new practical equation is derived from the Miller-Abrahams theory for different site-energies, and the temperature-dependent conductivity of Fibonacci lattice is calculated by a real-space renormalization-group approach. It is shown that there exist two types of temperature-dependent conductivity at low- and high-frequencies. Furthermore, it is found that the low-frequency conductivity oscillates dramatically with temperature.
Key words :
72.80.-r
61.44.Br
出版日期: 1999-07-01
引用本文:
DING Jian-wen;YAN Xiao-hong;FANG Xian-cheng. Temperature-Dependent ac Conductivity of the Fibonacci Lattice[J]. 中国物理快报, 1999, 16(7): 529-531.
链接本文:
https://cpl.iphy.ac.cn/CN/
或
https://cpl.iphy.ac.cn/CN/Y1999/V16/I7/529
[1]
ZHU Ke;LI Cheng-Feng;ZHU Zhen-Gang. Measurement of Electrical Conductivity of Porous Titanium and Ti6Al4V Prepared by the Powder Metallurgy Method
[2]
LI Lian-He;FAN Tian-You. Final Governing Equation of Plane Elasticity of Icosahedral Quasicrystals and General Solution Based on Stress Potential Function
[3]
ZHANG Yong-Gang;JIANG Xun-Ya;ZHU Cheng;GU Yi;LI Ai-Zhen;QI Ming;FENG Song-Lin. Growth and Characterization of GaAs/AlGaAs Thue--Morse Quasicrystal Photonic Bandgap Structures
[4]
LI Cheng-Feng;ZHU Zhen-Gang. Apparent Electrical Conductivity of Porous Titanium Prepared by the Powder Metallurgy Method
[5]
ZHOU Xiang;HU Cheng-Zheng;GONG Ping;ZHU Jia-Kun. Linear and Nonlinear Optical Properties of Quasicrystals
[6]
WANG Xiao-Dong;QI Min;DONG Chuang;. Bergman Clusters Related to Bulk Amorphous Alloys and Quasi-crystals
[7]
HOU Zhi-Lin;FU Xiu-Jun;LIU You-Yan. Electronic Transmission Properties of Two-Dimensional Quasi-lattice
[8]
FENG Yi;ZHENG Hai-Wu;ZHU Zhen-Gang;ZU Fang-Qiu. Electrical Conductivity of Aluminum Alloy Foams
[9]
LI Cui-Lian;LIU You-Yan. Phason-Strain Influence on Low-Temperature Specific Heat of
the Decagonal Al-Ni-Co Quasicrystal
[10]
WANG Jian-Bo;J. GASTALDI;WANG Ren-Hui. Preliminary Characterization of Loop-Shaped Defect in the AlPdMn Icosahedral Quasicrystal by Conventional X-Ray Topography
[11]
WANG Xiao-Guang;PAN Shao-Hua;YANG Guo-Zhen. Antitrace Maps and Light Transmission Coefficients for Generalized Fibonacci Multilayers
[12]
WANG Yong;HUANG Xiu-Qing;GONG Chang-De. Light Transmission Through Symmetric Fibonacci-Class Multilayers
[13]
XU Lu;MAI Zhen-hong. Inner Modulation in Quasicrystals and Approximants
[14]
LIU Kaifeng;WENG Yumin;ZHU Lei*;WANG Shenyi*;ZONG Xiangfu. Photoconductivity Characteristics of Porous Silicon
[15]
HE Yuliang;CHU Yiming;LIN Hongyi;JIANG Shusheng. Microstructure and Electron Conduction Mechanism of Hydrogenated Nano-crystalline Silicon Films
1999, Vol. 16 
