Numerical investigation of the electrical conductivity of irradiated graphene

被引:2
作者
Kolesnikov, D. V. [1 ]
机构
[1] Joint Inst Nucl Res, Bogoliubov Lab Theoret Phys, Dubna, Russia
来源
SOLID STATE COMMUNICATIONS | 2020年 / 308卷
关键词
Graphene; Electronic transport; Electrical conductivity; QUANTUM TRANSPORT; TRANSISTORS;
D O I
10.1016/j.ssc.2020.113834
中图分类号
O469 [凝聚态物理学];
学科分类号
070205 ;
摘要
Transport properties of irradiated graphene (electrical conductivity and mobility) are numerically investigated using the real-space Kubo formalism. A micrometer-sized system consisting of millions of atoms with nanopores of various sizes and concentrations is described. Electrical conductivity and mobility as a function of carrier (hole) density are calculated to provide possible comparisons with experiments.
引用
收藏
页数:5
相关论文
共 28 条
[1]   Dangling bonds and magnetism of grain boundaries in graphene [J].
Akhukov, M. A. ;
Fasolino, A. ;
Gornostyrev, Y. N. ;
Katsnelson, M. I. .
PHYSICAL REVIEW B, 2012, 85 (11)
[2]   Scaling Properties of Charge Transport in Polycrystalline Graphene [J].
Dinh Van tuan ;
Kotakoski, Jani ;
Louvet, Thibaud ;
Ortmann, Frank ;
Meyer, Jannik C. ;
Roche, Stephan .
NANO LETTERS, 2013, 13 (04) :1730-1735
[3]   Edge scattering of electrons in graphene: Boltzmann equation approach to the transport in graphene nanoribbons and nanodisks [J].
Dugaev, V. K. ;
Katsnelson, M. I. .
PHYSICAL REVIEW B, 2013, 88 (23)
[4]   Modeling Radiation-Induced Scattering in Graphene [J].
Esqueda, I. Sanchez ;
Cress, C. D. .
IEEE TRANSACTIONS ON NUCLEAR SCIENCE, 2015, 62 (06) :2906-2911
[5]  
Fan Z., 2018, ARXIV 1811 07387V1
[6]   GPUQT: An efficient linear-scaling quantum transport code fully implemented on graphics processing units [J].
Fan, Zheyong ;
Vierimaa, Ville ;
Harju, Ari .
COMPUTER PHYSICS COMMUNICATIONS, 2018, 230 :113-120
[7]   Efficient linear-scaling quantum transport calculations on graphics processing units and applications on electron transport in graphene [J].
Fan, Zheyong ;
Uppstu, Andreas ;
Siro, Topi ;
Harju, Ari .
COMPUTER PHYSICS COMMUNICATIONS, 2014, 185 (01) :28-39
[8]   Bilayer Graphene Transistors for Analog Electronics [J].
Fiori, Gianluca ;
Neumaier, Daniel ;
Szafranek, Bart N. ;
Iannaccone, Giuseppe .
IEEE TRANSACTIONS ON ELECTRON DEVICES, 2014, 61 (03) :729-733
[9]   Device Performance of Graphene Nanoribbon Field-Effect Transistors in the Presence of Line-Edge Roughness [J].
Goharrizi, Arash Yazdanpanah ;
Pourfath, Mahdi ;
Fathipour, Morteza ;
Kosina, Hans .
IEEE TRANSACTIONS ON ELECTRON DEVICES, 2012, 59 (12) :3527-3532
[10]   Charge and spin transport anisotropy in nanopatterned graphene [J].
Gregersen, Soren Schou ;
Garcia, Jose H. ;
Jauho, Antti-Pekka ;
Roche, Stephan ;
Power, Stephen R. .
JOURNAL OF PHYSICS-MATERIALS, 2018, 1 (01)
123