Peak positions and shapes in neutron pair correlation functions from
  powders of highly anisotropic crystals

A. R. Bishop; A. Rahman; A. Rahman; B. H. Toby; D. A. Dimitrov; D. A. Dimitrov; E. S. Bozin; G. Albinet; G. C. Wick; G. L. Squires; G. Placzek; H. Röder; I. M. Lifshitz; J. D. Dunitz; J. L. Yarnell; J. P. Biberian; J. S. Chung; L. Van Hove; M. A. Krivoglaz; M. Born; P. A. Egelstaff; P. Ascarelli; R. A. Cowley; R. Kaplow; R. Migoni; S. W. Lovesey; T. Egami; Von A. Ludsteck; Y. Noda; Y. Waseda

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Peak positions and shapes in neutron pair correlation functions from powders of highly anisotropic crystals

Authors: A. R. Bishop
A. Rahman
A. Rahman
B. H. Toby
D. A. Dimitrov
D. A. Dimitrov
E. S. Bozin
G. Albinet
G. C. Wick
G. L. Squires
G. Placzek
H. Röder
I. M. Lifshitz
J. D. Dunitz
J. L. Yarnell
J. P. Biberian
J. S. Chung
L. Van Hove
M. A. Krivoglaz
M. Born
P. A. Egelstaff
P. Ascarelli
R. A. Cowley
R. Kaplow
R. Migoni
S. W. Lovesey
T. Egami
Von A. Ludsteck
Y. Noda
Y. Waseda
Publication date: 11 September 2000
Publisher: 'American Physical Society (APS)'
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Abstract

The effect of the powder average on the peak shapes and positions in neutron pair distribution functions of polycrystalline materials is examined. It is shown that for highly anisotropic crystals, the powder average leads to shifts in peak positions and to non-Gaussian peak shapes. The peak shifts can be as large as several percent of the lattice spacing

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