Ensemble Monte Carlo Electron Transport Simulation for GaN n+–n–n+ Diode

被引:0
作者
Baghdadi Berrabah
Choukria Sayah
Souheyla Ferouani
Sofiane Derrouiche
Benyounes Bouazza
机构
[1] Univ Ctr Ain Temouchent,Smart Structure Laboratory, Institute of Technology
[2] University Abou Bekr Belkaid of Tlemcen,Materials and Renewable Energies Laboratory
来源
Transactions on Electrical and Electronic Materials | 2021年 / 22卷
关键词
GaN; Monte Carlo; Poisson equation; Boltzmann equation; Electron velocity;
D O I
暂无
中图分类号
学科分类号
摘要
Ensemble Monte Carlo simulator is used for solution of Boltzmann transport equation coupling with Poisson equation. We study the electron transport in cubic GaN n+–n–n+ for voltages range from 0.5 to 4 V. In this simulation technique, spatial motion of electron is treated semi-classically and scattering mechanisms included are those due to phonons scattering and ionized impurities scattering. Profile of the electron density, average velocity, kinetic energy, electrostatic potential and electric field are computed. Results are reported for different lattice temperature and various active layer lengths.
引用
收藏
页码:290 / 300
页数:10
相关论文
共 50 条
[31]   ZrB2 Schottky diode contacts on n-GaN [J].
Khanna, R. ;
Ramani, K. ;
Cracium, V. ;
Singh, R. ;
Pearton, S. J. ;
Ren, F. ;
Kravchenko, I. I. .
APPLIED SURFACE SCIENCE, 2006, 253 (04) :2315-2319
[32]   On the Monte Carlo simulation of electron transport in the sub-1 keV energy range [J].
Thomson, Rowan M. ;
Kawrakow, Iwan .
MEDICAL PHYSICS, 2011, 38 (08) :4531-4534
[33]   Monte Carlo simulation of electron transport in low-light-level image intensifier [J].
Yan, Lei ;
Shi, Feng ;
Cheng, Hongchang ;
Cheng, Yaojin ;
Hou, Zhipeng ;
Shi, Hongli ;
Miao, Zhuang ;
Zhang, Xiaohui ;
Liu, Feng ;
Liu, Hui .
OPTIK, 2015, 126 (02) :219-222
[34]   Electron transport within bulk cubic boron nitride: A Monte Carlo simulation analysis [J].
Siddiqua, Poppy ;
Shur, Michael S. ;
O'Leary, Stephen K. .
JOURNAL OF APPLIED PHYSICS, 2020, 128 (18)
[35]   METHES: A Monte Carlo collision code for the simulation of electron transport in low temperature plasmas [J].
Rabie, M. ;
Franck, C. M. .
COMPUTER PHYSICS COMMUNICATIONS, 2016, 203 :268-277
[36]   Optimized Design of Ni/GaN Schottky Barrier IMPATT Diode With n-type GaN Deep Level Defects [J].
Zhang, Xiao-Yu ;
Lei, Hu ;
Du, Lin ;
Ji, Siwei ;
Li, Xiaotong ;
Li, Yang ;
Yang, Lin-An ;
Hao, Yue .
PROCEEDINGS OF THE 2021 CROSS STRAIT RADIO SCIENCE AND WIRELESS TECHNOLOGY CONFERENCE (CSRSWTC), 2021, :52-54
[37]   Electron transport properties of Al0.3Ga0.7 N/GaN high electron mobility transistor (HEMT) [J].
Akpinar, Omer ;
Bilgili, Ahmet Kuersat ;
Ozturk, Mustafa Kemal ;
Ozcelik, Sueleyman .
APPLIED PHYSICS A-MATERIALS SCIENCE & PROCESSING, 2020, 126 (08)
[38]   Electron transport properties of Al0.3Ga0.7 N/GaN high electron mobility transistor (HEMT) [J].
Ömer Akpınar ;
Ahmet Kürşat Bilgili ;
Mustafa Kemal Öztürk ;
Süleyman Özçelik .
Applied Physics A, 2020, 126
[39]   Two-Probe Measurements of Electron Transport in GaN:Si/(Ga,Mn)N/GaN:Si Spin Filter Structures [J].
Kalbarczyk, K. ;
Foltyn, M. ;
Grzybowski, M. ;
Stefanowicz, W. ;
Adhikari, R. ;
Li, Tian ;
Kruszka, R. ;
Kaminska, E. ;
Piotrowska, A. ;
Bonanni, A. ;
Dietl, T. ;
Sawicki, M. .
ACTA PHYSICA POLONICA A, 2016, 130 (05) :1196-1198
[40]   Characterization of an Mg-implanted GaN p-i-n diode [J].
Greenlee, Jordan D. ;
Anderson, Travis J. ;
Feigelson, Boris N. ;
Hobart, Karl D. ;
Kub, Francis J. .
PHYSICA STATUS SOLIDI A-APPLICATIONS AND MATERIALS SCIENCE, 2015, 212 (12) :2772-2775
12345