New application of classical X-ray diffraction methods for epitaxial film characterization

被引:0
|
作者
Peterse, WJAM
Scholte, PMLO
Steinfort, AJ
Tuinstra, F
机构
[1] Faculty of Applied Physics, Delft University of Technology, 2628CJ Delft
来源
THIN SOLID FILMS | 1996年 / 289卷 / 1-2期
关键词
epitaxy; interfaces; surface structure; X-ray diffraction;
D O I
10.1016/S0040-6090(96)08883-9
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
The quality of an epilayer is characterized by its in-plane misfit and orientation with respect to the substrate, its out-of-plane cell parameter, its orientation distribution and its in-plane and out-of-plane strains. We adapted the Weissenberg equi-inclination geometry such that combined with a powder diffractometer it provides all the information mentioned, in two single scans. The powder diffractometer data are used to determine the out-of-plane texture of the film, while the photographic Weissenberg film provides a complete overview of the in-plane characteristics. The method can be performed with standard laboratory equipment in a simple and reliable way. The method is illustrated with four different epilayer/substrate systems.
引用
收藏
页码:49 / 53
页数:5
相关论文
共 50 条
  • [31] Residual Stress State Characterization of Machined Components by X-ray Diffraction and Multiparameter Micromagnetic Methods
    J. Epp
    T. Hirsch
    Experimental Mechanics, 2010, 50 : 195 - 204
  • [32] On the Use of an External Reference Sample in the X-ray Diffraction Analysis of Epitaxial Layers
    Drozdov, Yu N.
    Yunin, P. A.
    JOURNAL OF SURFACE INVESTIGATION, 2016, 10 (01): : 96 - 100
  • [33] Image plate X-ray diffraction and X-ray reflectivity characterization of protective coatings and thin films
    Lee, SL
    Windover, D
    Doxbeck, M
    Nielsen, M
    Kumar, A
    Lu, TM
    THIN SOLID FILMS, 2000, 377 : 447 - 454
  • [34] Structural Characterization of Gallbladder Stones Using Energy Dispersive X-ray Spectroscopy and X-ray Diffraction
    Almarshad, Hassan A.
    Badawy, Sayed M.
    Alsharari, Abdalkarem F.
    COMBINATORIAL CHEMISTRY & HIGH THROUGHPUT SCREENING, 2018, 21 (07) : 495 - 500
  • [35] X-ray source characterization and sample heating on x-ray diffraction experiments at the National Ignition Facility
    Krygier, A.
    Wehrenberg, C. E.
    Bernier, J. V.
    Clarke, S.
    Coleman, A. L.
    Coppari, F.
    Duffy, T. S.
    Gorman, M. G.
    Hohenberger, M.
    Kalantar, D.
    Kemp, G. E.
    Khan, S. F.
    Krauland, C.
    Kraus, R. G.
    Lazicki, A.
    MacDonald, M. J.
    MacPhee, A. G.
    Marley, E.
    Marshall, M. C.
    May, M.
    McNaney, J. M.
    Millot, M.
    Ping, Y.
    Poole, P. L.
    Rygg, J. R.
    Schneider, M.
    Sio, H.
    Stoupin, S.
    Swift, D.
    Yeamans, C.
    Zobrist, T.
    Smith, R. F.
    Eggert, J. H.
    PHYSICS OF PLASMAS, 2022, 29 (10)
  • [36] New X-ray diffraction method for materials science
    Swiatek, Z
    Bonarski, JT
    Ciach, R
    Kuznicki, ZT
    THIN SOLID FILMS, 1998, 319 (1-2) : 16 - 19
  • [37] X-ray characterization of as-deposited, epitaxial films of Bi(012) on Au(111)
    Jeffrey, CA
    Zheng, SH
    Bohannan, E
    Harrington, DA
    Morin, S
    SURFACE SCIENCE, 2006, 600 (01) : 95 - 105
  • [38] X-ray diffraction characterization of polymer intercalated graphite oxide
    Blanton, Thomas N.
    Majumdar, Debasis
    POWDER DIFFRACTION, 2012, 27 (02) : 104 - 107
  • [39] X-ray diffraction characterization of magnetostriction in Terfenol-D
    Rodriguez, Mark A.
    Faltas, Mina
    Valdez, Nichole R.
    Lowry, Daniel R.
    POWDER DIFFRACTION, 2025,
  • [40] Structural characterization of ZnTe films by X-ray diffraction technique
    Kalita, PK
    Sarma, BK
    Das, HL
    INDIAN JOURNAL OF PHYSICS AND PROCEEDINGS OF THE INDIAN ASSOCIATION FOR THE CULTIVATION OF SCIENCE-PART A, 2003, 77A (05): : 487 - 490
12345