Electronic structure of the Ga1-xCrxN studied by high-energy photoemission spectroscopy

被引:3
|
作者
Kim, JJ
Makino, H
Yao, T [1 ]
Takata, Y
Kobayashi, K
Yamamoto, T
Hanada, T
Cho, MW
Ikenaga, E
Yabashi, A
Miwa, D
Nishino, Y
Tamasaku, K
Ishikawa, T
Shin, S
机构
[1] Tohoku Univ, Interdisciplinary Res Ctr, Aoba Ku, Sendai, Miyagi 9808578, Japan
[2] Tohoku Univ, Mat Res Inst, Sendai, Miyagi 9808577, Japan
[3] JASRI, SPring 8, Hyogo 6795198, Japan
[4] RIKEN, SPring 8, Hyogo 6795148, Japan
[5] Kochi Univ Technol, Dept Elect & Photon Syst Engn, Kochi 7828502, Japan
来源
JOURNAL OF ELECTRON SPECTROSCOPY AND RELATED PHENOMENA | 2005年 / 144卷
关键词
Cr-doped GaN; ferromagnetism; high-energy photoemission spectroscopy;
D O I
10.1016/j.elspec.2005.01.137
中图分类号
O433 [光谱学];
学科分类号
0703 ; 070302 ;
摘要
Valence band spectra of Ga1-xCrxN have been investigated by high-energy photoemission spectroscopy at the photon energy of 5.95 keV Cr doping does introduce a novel electronic structure in the bandgap and causes some change in valence band structure. Based on the first-principle calculation, Cr-associated electronic levels in the bandgap, are assigned to nonbonding and antibonding d states while the change of the valence band suggests that the Ga 4s originated states are significantly modified through hybridization with the Cr 3d orbital. The present result evidences that the Ga valence electrons are considerably modified through the interaction with the second nearest-neighbour Cr atoms. (c) 2005 Elsevier B.V. All rights reserved.
引用
收藏
页码:561 / 564
页数:4
相关论文
共 50 条
  • [31] Suppression of vacancy aggregation by silicon-doping in low-temperature-grown Ga1-xCrxN
    Yabuuchi, A.
    Maekawa, M.
    Kawasuso, A.
    Zhou, Y. -K.
    Hasegawa, S.
    Asahi, H.
    APPLIED PHYSICS LETTERS, 2013, 102 (14)
  • [32] The electronic structure of doped fullerenes studied using high energy spectroscopy
    Pichler, T
    Golden, MS
    Knupfer, M
    Fink, J
    ELECTRONIC PROPERTIES OF NOVEL MATERIALS - PROGRESS IN MOLECULAR NANOSTRUCTURES: XII INTERNATIONAL WINTERSCHOOL, 1998, 442 : 271 - 276
  • [33] Electronic structure of oxidized SiC(0001) studied by inverse photoemission spectroscopy
    Ostendorf, R.
    Wulff, K.
    Benesch, C.
    Zacharias, H.
    SURFACE SCIENCE, 2006, 600 (18) : 3839 - 3844
  • [34] Electronic structure of porphyrin/metal interfaces studied by UV photoemission spectroscopy
    Nagoya Univ, Nagoya, Japan
    Synthetic Metals, 1997, 86 (1 -3 pt 3) : 2399 - 2400
  • [35] The electronic structure of porphyrin/metal interfaces studied by UV photoemission spectroscopy
    Yoshimura, D
    Ishii, H
    Narioka, S
    Sei, M
    Miyazaki, T
    Ouchi, Y
    Hasegawa, S
    Harima, Y
    Yamashita, K
    Seki, K
    SYNTHETIC METALS, 1997, 86 (1-3) : 2399 - 2400
  • [36] INVESTIGATIONS OF THE ELECTRONIC-STRUCTURE OF CUPRATE SUPERCONDUCTORS BY HIGH-ENERGY SPECTROSCOPY
    FINK, J
    NUCKER, N
    ROMBERG, H
    ALEXANDER, M
    ADELMANN, P
    MANTE, J
    CLAESSEN, R
    BUSLAPS, T
    HARM, S
    MANZKE, R
    SKIBOWSKY, M
    JOURNAL OF THE LESS-COMMON METALS, 1990, 164 : 967 - 978
  • [37] Electronic structure of Mo1-xRex alloys studied through resonant photoemission spectroscopy
    Sundar, Shyam
    Banik, Soma
    Chandra, L. S. Sharath
    Chattopadhyay, M. K.
    Ganguli, Tapas
    Lodha, G. S.
    Pandey, Sudhir K.
    Phase, D. M.
    Roy, S. B.
    JOURNAL OF PHYSICS-CONDENSED MATTER, 2016, 28 (31)
  • [38] The electronic properties of carbon nanotubes studied by high resolution photoemission spectroscopy
    Larciprete, R
    Goldoni, A
    Lizzit, S
    Petaccia, L
    APPLIED SURFACE SCIENCE, 2005, 248 (1-4) : 8 - 13
  • [39] ELECTRONIC STRUCTURE OF GOLD STUDIED BY PHOTOEMISSION
    NILSSON, PO
    NORRIS, C
    WALLDEN, L
    PHYSIK DER KONDENSITERTEN MATERIE, 1970, 11 (03): : 220 - +
  • [40] BREMSSTRAHLUNG ISOCHROMAT SPECTROSCOPY (BIS OR HIGH-ENERGY INVERSE PHOTOEMISSION)
    FUGGLE, JC
    TOPICS IN APPLIED PHYSICS, 1992, 69 : 307 - 337
12345