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Pore distributions in nanocrystalline metals from small-angle neutron scattering

Journal Article · · Acta Materialia
;  [1];  [2]
  1. Northwestern Univ., Evanston, IL (United States). Materials Science and Engineering Dept.
  2. Argonne National Lab., IL (United States). Materials Science Div.
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Recent upgrades in inert-gas condensation processing equipment have produced nanocrystalline metal samples with high densities and low-impurity levels. Typical Cu and Pd samples have densities {ge}98% of theoretical and oxygen and hydrogen impurity concentrations {le}0.5 at. %. Lower porosity and impurity levels may make it difficult to produce and maintain samples with the smallest nanocrystalline grain sizes. These improved samples were studied by small-angle neutron scattering (SANS) to determine the volume fraction and size distribution of pores. Excellent correlation was obtained between the total volume fraction of pores and the Archimedes density for Pd, signifying that most of the pores were relatively small and in the detectability range of SANS ({approx}1--100 nm). Nanocrystalline Cu is shown to exhibit a wider pore size distribution. For Pd, the average pore sizes were slightly smaller than the average grain size, while for Cu the pore size and grain size were about the same. Both materials exhibited a trend of increasing pore size with increasing grain size. In terms of processing prerequisites, the principal condition for the production of high-density nanocrystalline Cu is an exceptionally clean synthesis environment, while nanocrystalline Pd requires compaction at elevated temperatures. These differences are the result of Cu having both a lower melting point and a greater susceptibility to contamination by gaseous impurities such as oxygen.

OSTI ID:
634665
Journal Information:
Acta Materialia, Journal Name: Acta Materialia Journal Issue: 12 Vol. 46; ISSN 1359-6454; ISSN ACMAFD
Country of Publication:
United States
Language:
English

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Related Subjects

36 MATERIALS SCIENCE
COPPER
GRAIN SIZE
IMPURITIES
NEUTRONS
PALLADIUM
PORE STRUCTURE
SMALL ANGLE SCATTERING