Characterizing Non-Linear Microwave Behavior of Semiconductor Materials with Scanning Microwave Impedance Microscopy

被引:0
|
作者
Friedman, Stuart [1 ]
Yang, Yongliang [1 ]
Amster, Oskar [1 ]
Stanke, Fred [1 ]
机构
[1] Prime Nano Inc, Palo Alto, CA 94306 USA
来源
2016 IEEE MTT-S INTERNATIONAL MICROWAVE SYMPOSIUM (IMS) | 2016年
关键词
Nanowires; nanotechnology;
D O I
暂无
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
As semiconductor technology advances, it can benefit from characterization of more complex materials with smaller geometries. Scanning Microwave Impedance Microscopy, sMIM, provides such with its measurements of the real and imaginary components of a sample's microwave impedance as seen by the tip of an atomic force microscope. sMIM can image capacitance C and its variation with bias, C-V, a non-linear property. With such images to navigate, sMIM can measure C as a function of bias at chosen locations. Images and measurements can be made for a broad range materials, from un-doped to highly doped. C-V curves from two microelectronic samples are shown below.
引用
收藏
页数:3
相关论文
共 50 条
  • [1] Practical Quantitative Scanning Microwave Impedance Microscopy of Semiconductor Devices
    Amster, Oskar
    Yang, Yongliang
    Drevniok, B.
    Friedman, Stuart
    Stanke, Fred
    Dixon-Warren, St J.
    2017 IEEE 24TH INTERNATIONAL SYMPOSIUM ON THE PHYSICAL AND FAILURE ANALYSIS OF INTEGRATED CIRCUITS (IPFA), 2017,
  • [2] MICROWAVE BEHAVIOR OF NON-LINEAR DIELECTRICS
    BETHE, K
    PHILIPS RESEARCH REPORTS, 1970, (02): : 1 - &
  • [3] Nanoscale Scanning Microwave Impedance Microscopy on Advanced Functional Materials
    Ren, Yuan
    Wu, Di
    Liu, Yingnan
    Wu, Xiaoyu
    Lai, Keji
    2015 45TH EUROPEAN MICROWAVE CONFERENCE (EUMC), 2015, : 650 - 653
  • [4] Extending Electrical Scanning Probe Microscopy Measurements of Semiconductor Devices Using Microwave Impedance Microscopy
    Drevniok, Benedict
    Dixon-Warren, St. John
    Amster, Oskar
    Friedman, Stuart L.
    Yang, Yongfang
    ISTFA 2015: CONFERENCE PROCEEDINGS FROM THE 41ST INTERNATIONAL SYMPOSIUM FOR TESTING AND FAILURE ANALYSIS, 2015, : 82 - 86
  • [5] Practical quantitative scanning microwave impedance microscopy
    Amster, Oskar
    Stanke, Fred
    Friedman, Stuart
    Yang, Yongliang
    Dixon-Warren, St J.
    Drevniok, B.
    MICROELECTRONICS RELIABILITY, 2017, 76 : 214 - 217
  • [6] A Scanning Microwave Impedance Microscopy Study of α-In2Se3 Ferroelectric Semiconductor
    Wang, Lin
    Chen, Han
    Chen, Mingfeng
    Long, Yinfeng
    Liu, Kai
    Loh, Kian Ping
    ADVANCED FUNCTIONAL MATERIALS, 2024, 34 (28)
  • [7] Nano C-V imaging of Semiconductor Devices with Scanning Microwave Impedance Microscopy
    Amster, Oskar
    Rubin, Kurt
    Yang, Yongliang
    Iyer, Dorai
    Messinger, A.
    Crowder, R.
    2018 25TH IEEE INTERNATIONAL SYMPOSIUM ON THE PHYSICAL AND FAILURE ANALYSIS OF INTEGRATED CIRCUITS (IPFA), 2018,
  • [8] Comparison of Impedance Matching Networks for Scanning Microwave Microscopy
    Hoffmann, Johannes
    de Preville, Sophie
    Eckmann, Bruno
    Lin, Hung-Ju
    Herzog, Benedikt
    Haddadi, Kamel
    Theron, Didier
    Gramse, Georg
    Richert, Damien
    Moran-Meza, Jose
    Piquemal, Francois
    IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 2024, 73 : 1 - 9
  • [9] Scanning microwave impedance microscopy and its applications: A review
    Tami, Diego
    Ohlberg, Douglas A. A.
    do Rego, Cassio Goncalves
    Medeiros-Ribeiro, Gilberto
    Ramirez, Jhonattan C.
    APL MATERIALS, 2025, 13 (01):
  • [10] Electromagnetic and Semiconductor Modeling of Scanning Microwave Microscopy Setups
    Gungor, Arif Can
    Celuch, Malgorzata
    Smajic, Jasmin
    Olszewska-Placha, Marzena
    Leuthold, Juerg
    IEEE JOURNAL ON MULTISCALE AND MULTIPHYSICS COMPUTATIONAL TECHNIQUES, 2020, 5 : 209 - 216
12345