Observation of Band Gap in Epitaxial Bilayer Graphene Field Effect Transistors

被引:17
|
作者
Tanabe, Shinichi [1 ]
Sekine, Yoshiaki [1 ]
Kageshima, Hiroyuki [1 ]
Nagase, Masao [1 ]
Hibino, Hiroki [1 ]
机构
[1] NTT Corp, NTT Basic Res Labs, Kanagawa 2430198, Japan
来源
JAPANESE JOURNAL OF APPLIED PHYSICS | 2011年 / 50卷 / 04期
关键词
ELECTRIC-FIELD;
D O I
10.1143/JJAP.50.04DN04
中图分类号
O59 [应用物理学];
学科分类号
摘要
Bilayer graphene was grown on the Si-face of SiC by thermal decomposition. Its electronic properties were investigated in top-gate Hall bar devices. By controlling the carrier density using gate voltage, we were able to access the charge neutrality point. The conductance at the charge neutrality point showed a strong temperature dependence, and its temperature dependence was well fitted with thermal activation and variable-range hopping mechanisms. The electrical detection of a band gap opening in bilayer graphene grown on SiC is a promising step toward the realization of graphene-based electronics using epitaxial graphene. (C) 2011 The Japan Society of Applied Physics
引用
收藏
页数:4
相关论文
共 50 条
  • [21] Current Saturation and Voltage Gain in Bilayer Graphene Field Effect Transistors
    Szafranek, B. N.
    Fiori, G.
    Schall, D.
    Neumaier, D.
    Kurz, H.
    NANO LETTERS, 2012, 12 (03) : 1324 - 1328
  • [22] Analysis of ballistic monolayer and bilayer graphene field-effect transistors
    Ouyang, Yijian
    Campbell, Paul
    Guo, Jing
    APPLIED PHYSICS LETTERS, 2008, 92 (06)
  • [23] Topological band gap in intercalated epitaxial graphene
    Kim, Minsung
    Wang, Cai-Zhuang
    Tringides, Michael C.
    Hupalo, Myron
    Ho, Kai-Ming
    SOLID STATE COMMUNICATIONS, 2023, 373
  • [24] Observation of Coulomb blockade in nanostructured epitaxial bilayer graphene on SiC
    Chua, Cassandra
    Lartsev, Arseniy
    Sui, Jinggao
    Panchal, Vishal
    Puddy, Reuben
    Richardson, Carly
    Smith, Charles G.
    Janssen, T. J. B. M.
    Tzalenchuk, Alexander
    Yakimova, Rositsa
    Kubatkin, Sergey
    Connolly, Malcolm R.
    CARBON, 2017, 119 : 426 - 430
  • [25] Biased bilayer graphene: Semiconductor with a gap tunable by the electric field effect
    Castro, Eduardo V.
    Novoselov, K. S.
    Morozov, S. V.
    Peres, N. M. R.
    Dos Santos, J. M. B. Lopes
    Nilsson, Johan
    Guinea, F.
    Geim, A. K.
    Castro Neto, A. H.
    PHYSICAL REVIEW LETTERS, 2007, 99 (21)
  • [26] Electrical noise inside the band gap of bilayer graphene
    Aamir, Md. Ali
    Ghosh, Arindam
    2D MATERIALS, 2019, 6 (02)
  • [27] Band Gap and Correlated Phenomena in Bilayer and Trilayer Graphene
    Lee, Yongjin
    Myhro, Kevin
    Tran, David
    Gilgren, Nathaniel
    Velasco, Jairo, Jr.
    Bao, Wenzhong
    Deo, Michael
    Lau, Chun Ning
    MICRO- AND NANOTECHNOLOGY SENSORS, SYSTEMS, AND APPLICATIONS V, 2013, 8725
  • [28] Asymmetry gap in the electronic band structure of bilayer graphene
    McCann, Edward
    PHYSICAL REVIEW B, 2006, 74 (16):
  • [29] High On-Off Ratio Bilayer Graphene Complementary Field Effect Transistors
    Majumdar, Kausik
    Murali, Kota V. R. M.
    Bhat, Navakanta
    Xia, Fengnian
    Lin, Yu-Ming
    2010 INTERNATIONAL ELECTRON DEVICES MEETING - TECHNICAL DIGEST, 2010,
  • [30] Improved voltage gain in mechanically stacked bilayer graphene field effect transistors
    Pandey, Himadri
    Kataria, Satender
    Passi, Vikram
    Iannazzo, Mario
    Alarcon, Eduard
    Lemme, Max C.
    2016 JOINT INTERNATIONAL EUROSOI WORKSHOP AND INTERNATIONAL CONFERENCE ON ULTIMATE INTEGRATION ON SILICON (EUROSOI-ULIS 2016), 2016, : 143 - 146
12345