Observation of nonconservation characteristics of radio frequency noise mechanism of 40-nm n-MOSFET

doi:10.1088/1674-1056/27/2/027201

中国物理B ›› 2018, Vol. 27 ›› Issue (2): 27201-027201.doi: 10.1088/1674-1056/27/2/027201

• CONDENSED MATTER: ELECTRONIC STRUCTURE, ELECTRICAL, MAGNETIC, AND OPTICAL PROPERTIES • 上一篇下一篇

Observation of nonconservation characteristics of radio frequency noise mechanism of 40-nm n-MOSFET

Jun Wang(王军), Xiao-Mei Peng(彭小梅), Zhi-Jun Liu(刘志军), Lin Wang(王林), Zhen Luo(罗震), Dan-Dan Wang(王丹丹)

1. School of Information Engineering, Southwest University of Science and Technology, Mianyang 621010, China;
2. Department of Physics, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA

收稿日期:2017-11-09 修回日期:2017-11-12 出版日期:2018-02-05 发布日期:2018-02-05
通讯作者: Jun Wang E-mail:junwang@swust.edu.cn
基金资助:
Project supported by the National Natural Science Foundation of China (Grant No. 69901003) and the Scientific Research Fund of Sichuan Provincial Education Department.

Observation of nonconservation characteristics of radio frequency noise mechanism of 40-nm n-MOSFET

Jun Wang(王军)¹, Xiao-Mei Peng(彭小梅)¹, Zhi-Jun Liu(刘志军)², Lin Wang(王林)¹, Zhen Luo(罗震)¹, Dan-Dan Wang(王丹丹)¹

1. School of Information Engineering, Southwest University of Science and Technology, Mianyang 621010, China;
2. Department of Physics, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA

Received:2017-11-09 Revised:2017-11-12 Online:2018-02-05 Published:2018-02-05
Contact: Jun Wang E-mail:junwang@swust.edu.cn
About author:72.70.+m; 72.30.+q; 73.43.Fj
Supported by:
Project supported by the National Natural Science Foundation of China (Grant No. 69901003) and the Scientific Research Fund of Sichuan Provincial Education Department.

摘要/Abstract

摘要： Bias non-conservation characteristics of radio-frequency noise mechanism of 40-nm n-MOSFET are observed by modeling and measuring its drain current noise. A compact model for the drain current noise of 40-nm MOSFET is proposed through the noise analysis. This model fully describes three kinds of main physical sources that determine the noise mechanism of 40-nm MOSFET, i.e., intrinsic drain current noise, thermal noise induced by the gate parasitic resistance, and coupling thermal noise induced by substrate parasitic effect. The accuracy of the proposed model is verified by noise measurements, and the intrinsic drain current noise is proved to be the suppressed shot noise, and with the decrease of the gate voltage, the suppressed degree gradually decreases until it vanishes. The most important findings of the bias non-conservative nature of noise mechanism of 40-nm n-MOSFET are as follows. (i) In the strong inversion region, the suppressed shot noise is weakly affected by the thermal noise of gate parasitic resistance. Therefore, one can empirically model the channel excess noise as being like the suppressed shot noise. (ii) In the middle inversion region, it is almost full of shot noise. (iii) In the weak inversion region, the thermal noise is strongly frequency-dependent, which is almost controlled by the capacitive coupling of substrate parasitic resistance. Measurement results over a wide temperature range demonstrate that the thermal noise of 40-nm n-MOSFET exists in a region from the weak to strong inversion, contrary to the predictions of suppressed shot noise model only suitable for the strong inversion and middle inversion region. These new findings of the noise mechanism of 40-nm n-MOSFET are very beneficial for its applications in ultra low-voltage and low-power RF, such as novel device electronic structure optimization, integrated circuit design and process technology evaluation.

关键词: nanoscale MOSFET, non-conservation characteristics, noise mechanism, radio frequency

Abstract: Bias non-conservation characteristics of radio-frequency noise mechanism of 40-nm n-MOSFET are observed by modeling and measuring its drain current noise. A compact model for the drain current noise of 40-nm MOSFET is proposed through the noise analysis. This model fully describes three kinds of main physical sources that determine the noise mechanism of 40-nm MOSFET, i.e., intrinsic drain current noise, thermal noise induced by the gate parasitic resistance, and coupling thermal noise induced by substrate parasitic effect. The accuracy of the proposed model is verified by noise measurements, and the intrinsic drain current noise is proved to be the suppressed shot noise, and with the decrease of the gate voltage, the suppressed degree gradually decreases until it vanishes. The most important findings of the bias non-conservative nature of noise mechanism of 40-nm n-MOSFET are as follows. (i) In the strong inversion region, the suppressed shot noise is weakly affected by the thermal noise of gate parasitic resistance. Therefore, one can empirically model the channel excess noise as being like the suppressed shot noise. (ii) In the middle inversion region, it is almost full of shot noise. (iii) In the weak inversion region, the thermal noise is strongly frequency-dependent, which is almost controlled by the capacitive coupling of substrate parasitic resistance. Measurement results over a wide temperature range demonstrate that the thermal noise of 40-nm n-MOSFET exists in a region from the weak to strong inversion, contrary to the predictions of suppressed shot noise model only suitable for the strong inversion and middle inversion region. These new findings of the noise mechanism of 40-nm n-MOSFET are very beneficial for its applications in ultra low-voltage and low-power RF, such as novel device electronic structure optimization, integrated circuit design and process technology evaluation.

Key words: nanoscale MOSFET, non-conservation characteristics, noise mechanism, radio frequency

中图分类号: (Noise processes and phenomena)

72.70.+m

72.30.+q (High-frequency effects; plasma effects) 73.43.Fj (Novel experimental methods; measurements)

王军, 彭小梅, 刘志军, 王林, 罗震, 王丹丹. Observation of nonconservation characteristics of radio frequency noise mechanism of 40-nm n-MOSFET[J]. 中国物理B, 2018, 27(2): 27201-027201.

Jun Wang(王军), Xiao-Mei Peng(彭小梅), Zhi-Jun Liu(刘志军), Lin Wang(王林), Zhen Luo(罗震), Dan-Dan Wang(王丹丹). Observation of nonconservation characteristics of radio frequency noise mechanism of 40-nm n-MOSFET[J]. Chin. Phys. B, 2018, 27(2): 27201-027201.

参考文献 21

[1]	Navid R, Jungemann C, Lee T H, and Dutton R W 2007 J. Appl. Phys. 101 124501
[2]	Wang S C, Su p, Chen K M, Liao K H, Chen B Y, Huang S Y, Hung C C and Huang G W 2010 IEEE Trans. Microw. Theory Technol. 58 740
[3]	Antonopoulos A, Bucher M, Papathanasiou K, Mavredakis N, Makris N, Sharma R K, Sakalas P and Schroter M 2013 IEEE Trans. Electron Dev. 60 3726
[4]	Chan L H K, Yeo K S, Chew K W J and Ong S N 2015 IEEE Trans. Microw. Theory Technol. 63 141
[5]	Chalkiadaki, M A and Enz C C 2015 IEEE Trans. Microw. Theory Technol. 63 2173
[6]	Jeon J, Lee J, Kim J, Park C H, Lee H, Oh H, Kang H K, Park B G and Shin H 2009 Symposium on VLSI Technology, Jun, 2009, Kyoto, Japan, p. 48
[7]	Mahajan V M, Patalay P R, Jindal R P, Shichijo, H, Martin S, Hou, F C, Machala C and Trombley D E 2012 IEEE Trans. Electron Dev. 59 197
[8]	Andersson S and Svensson C 2005 Electron. Lett. 41 869
[9]	Spathis C, Birbas A and Georgakopoulou 2015 AIP Adv. 5 087114
[10]	Tsididis Y 1999 Operation and Modeling of the MOS Transistor (Boston, MA:WCB/McGraw-Hill) p. 66
[11]	Wang J, Wang L and Wang D D 2016 Acta Phys. Sin. 65237102(in Chinese)
[12]	Ong SN, Yeo K S and Chew W J 2012 Sliod State Electron. 68 32
[13]	Smit G D J, Scholten A J, Pijper R M T, Tiemeijer L F, van der Toorn R and Klaassen D B M 2014 IEEE Trans. Electron Dev. 61 245
[14]	Shi J, Xiong Y Z, Kang K, Nan L and Lin F 2009 IEEE Trans. Electron Dev. Lett. 30 185
[15]	Fabian Z R, Reydezel T T and Roberto S M A 2015 IEEE Trans. Mi-crow. Theory Technol. 63 4255
[16]	Ytterdal T, Cheng Y H and Fjeldly T A 2003 Device Modeling for Analog and RF CMOS Circuit Design (John Wiley & Sons, Ltd) Chapter 3
[17]	Himmerlfarb M and Belostotski 2016 IEEE Trans. Microw. Theory Technol. 64 258
[18]	Wang D D 2017 "Equivalent Circuit Modeling of Nanoscale MOSFET in Millimeter-wave Band", Dissertation (Mianyang:Southwest University of Science and Technology) (in Chinese)
[19]	Wang J, Chen H L and Tang G D 2003 Chin. J. Electron. 12 471
[20]	Lee C I, Lin W C and Lin Y T 2015 IEEE Trans. Electron Dev. Lett. 36 291
[21]	Chan L H K, Yeo K S, Chew K W J, Ong S N, Loo X S, Boon C C and Do M A 2012 IEEE Trans. Electron Dev. Lett. 33 1117

Observation of nonconservation characteristics of radio frequency noise mechanism of 40-nm n-MOSFET

Observation of nonconservation characteristics of radio frequency noise mechanism of 40-nm n-MOSFET

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献 21

相关文章 15

Metrics

本文评价

推荐阅读 0

[1]	Ya-Rong Zhang(张亚容), Qian-Han Han(韩乾翰), Jun-Lin Fang(方骏林), Ying Guo(郭颖), and Jian-Jun Shi(石建军). Ignition dynamics of radio frequency discharge in atmospheric pressure cascade glow discharge[J]. 中国物理B, 2023, 32(2): 25201-025201.
[2]	Tian Guo(郭天), Peiliang Liu(刘培亮), and Chaohong Lee(李朝红). New designed helical resonator to improve measurement accuracy of magic radio frequency[J]. 中国物理B, 2022, 31(9): 93201-093201.
[3]	Xinchuang Zhang(张新创), Mei Wu(武玫), Bin Hou(侯斌), Xuerui Niu(牛雪锐), Hao Lu(芦浩), Fuchun Jia(贾富春), Meng Zhang(张濛), Jiale Du(杜佳乐), Ling Yang(杨凌), Xiaohua Ma(马晓华), and Yue Hao(郝跃). Improved device performance of recessed-gate AlGaN/GaN HEMTs by using in-situ N₂O radical treatment[J]. 中国物理B, 2022, 31(5): 57301-057301.
[4]	Xin-Lu Lin(林新璐), Wen-Xiong Zhao(赵文雄), Qiu-Chen Wu(吴秋晨), Yu-Feng Zhang(张玉峰), Hasitha Mahabaduge, and Xiang-Xin Liu(刘向鑫). Development of ZnTe film with high copper doping efficiency for solar cells[J]. 中国物理B, 2022, 31(10): 108802-108802.
[5]	杨光, 吕昭征, 张祥, 屈凡明, 吕力. Probing the minigap in topological insulator-based Josephson junctions under radio frequency irradiation[J]. 中国物理B, 2019, 28(12): 127402-127402.
[6]	杨臻, 宋慧敏, 金迪, 贾敏, 王康. Electrical and thermal characterization of near-surface electrical discharge plasma actuation driven by radio frequency voltage at low pressure[J]. 中国物理B, 2018, 27(8): 85205-085205.
[7]	陆志军, Shigeki Fukuda, 周祖圣, 裴士伦, 王盛昌, 肖欧正, UnNisa Zaib, 白博文, 裴国玺, 董东, 周宁闯, 王少哲, 池云龙. Design and development of radio frequency output window for circular electron-positron collider klystron[J]. 中国物理B, 2018, 27(11): 118402-118402.
[8]	裴敏洁, 齐大龙, 齐迎朋, 贾天卿, 张诗按, 孙真荣. Compressing ultrafast electron pulse by radio frequency cavity[J]. 中国物理B, 2017, 26(4): 44102-044102.
[9]	刘悦, 赵璐璐, 周艳文. Effect of driving frequency on electron heating in capacitively coupled RF argon glow discharges at low pressure[J]. 中国物理B, 2017, 26(11): 115201-115201.
[10]	王蔚龙, 李军, 宋慧敏, 金迪, 贾敏, 吴云. Thermal and induced flow characteristics of radio frequency surface dielectric barrier discharge plasma actuation at atmospheric pressure[J]. 中国物理B, 2017, 26(1): 15205-015205.
[11]	王蔚龙, 宋慧敏, 李军, 贾敏, 吴云, 金迪. Electrical and optical characteristics of the radio frequency surface dielectric barrier discharge plasma actuation[J]. 中国物理B, 2016, 25(4): 45203-045203.
[12]	刘政豪, 魏玉科, 王达, 张琛, 马平, 王越. Fabrication and properties of high performance YBa₂Cu₃O_7-δ radio frequency SQUIDs with step-edge Josephson junctions[J]. , 2014, 23(9): 97401-097401.
[13]	王松柏, 雷光玖, 刘东平, 杨思泽. Balmer-alpha and Balmer-beta Stark line intensity profiles for high-power hydrogen inductively coupled plasmas[J]. , 2014, 23(7): 75201-075201.
[14]	Alireza Samavati, Z. Othaman, S. K. Ghoshal, R. J. Amjad. Germanium nanoislands grown by radio frequency magnetron sputtering：Annealing time dependent surface morphology and photoluminescence[J]. 中国物理B, 2013, 22(9): 98102-098102.
[15]	罗博文, 董建绩, 于源, 杨婷, 张新亮 . Photonic multi-shape UWB pulse generation using a semiconductor optical amplifier-based nonlinear optical loop mirror[J]. 中国物理B, 2013, 22(2): 23201-023201.