Extracting grain-orientation-dependent data from in situ time-of-flight neutron diffraction. I. Inverse pole figures

G. M. Stoica; A. D. Stoica; K. An; D. Ma; S. C. Vogel; J. S. Carpenter; X. L. Wang

doi:10.1107/S1600576714023036

Extracting grain-orientation-dependent data from in situ time-of-flight neutron diffraction. I. Inverse pole figures

G. M. Stoica, A. D. Stoica, K. An, D. Ma, S. C. Vogel, J. S. Carpenter, X. L. Wang

Materials Engineering

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17 Scopus citations

Abstract

The problem of calculating the inverse pole figure (IPF) is analyzed from the perspective of the application of time-of flight neutron diffraction to in situ monitoring of the thermomechanical behavior of engineering materials. On the basis of a quasi-Monte Carlo (QMC) method, a consistent set of grain orientations is generated and used to compute the weighting factors for IPF normalization. The weighting factors are instrument dependent and were calculated for the engineering materials diffractometer VULCAN (Spallation Neutron Source, Oak Ridge National Laboratory). The QMC method is applied to face-centered cubic structures and can be easily extended to other crystallographic symmetries. Examples include 316LN stainless steel in situ loaded in tension at room temperature and an Al-2%Mg alloy, substantially deformed by cold rolling and in situ annealed up to 653 K.

Original language	English
Pages (from-to)	2019-2029
Number of pages	11
Journal	Journal of Applied Crystallography
Volume	47
Issue number	6
DOIs	https://doi.org/10.1107/S1600576714023036
State	Published - Dec 1 2014

Keywords

grain orientation
inverse pole figures
texture analysis
thermomechanical behavior
time-of flight neutron diffraction

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10.1107/S1600576714023036

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title = "Extracting grain-orientation-dependent data from in situ time-of-flight neutron diffraction. I. Inverse pole figures",

abstract = "The problem of calculating the inverse pole figure (IPF) is analyzed from the perspective of the application of time-of flight neutron diffraction to in situ monitoring of the thermomechanical behavior of engineering materials. On the basis of a quasi-Monte Carlo (QMC) method, a consistent set of grain orientations is generated and used to compute the weighting factors for IPF normalization. The weighting factors are instrument dependent and were calculated for the engineering materials diffractometer VULCAN (Spallation Neutron Source, Oak Ridge National Laboratory). The QMC method is applied to face-centered cubic structures and can be easily extended to other crystallographic symmetries. Examples include 316LN stainless steel in situ loaded in tension at room temperature and an Al-2%Mg alloy, substantially deformed by cold rolling and in situ annealed up to 653 K.",

keywords = "grain orientation, inverse pole figures, texture analysis, thermomechanical behavior, time-of flight neutron diffraction",

author = "Stoica, {G. M.} and Stoica, {A. D.} and K. An and D. Ma and Vogel, {S. C.} and Carpenter, {J. S.} and Wang, {X. L.}",

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AU - Stoica, G. M.

AU - Stoica, A. D.

AU - An, K.

AU - Ma, D.

AU - Vogel, S. C.

AU - Carpenter, J. S.

AU - Wang, X. L.

PY - 2014/12/1

Y1 - 2014/12/1

N2 - The problem of calculating the inverse pole figure (IPF) is analyzed from the perspective of the application of time-of flight neutron diffraction to in situ monitoring of the thermomechanical behavior of engineering materials. On the basis of a quasi-Monte Carlo (QMC) method, a consistent set of grain orientations is generated and used to compute the weighting factors for IPF normalization. The weighting factors are instrument dependent and were calculated for the engineering materials diffractometer VULCAN (Spallation Neutron Source, Oak Ridge National Laboratory). The QMC method is applied to face-centered cubic structures and can be easily extended to other crystallographic symmetries. Examples include 316LN stainless steel in situ loaded in tension at room temperature and an Al-2%Mg alloy, substantially deformed by cold rolling and in situ annealed up to 653 K.

AB - The problem of calculating the inverse pole figure (IPF) is analyzed from the perspective of the application of time-of flight neutron diffraction to in situ monitoring of the thermomechanical behavior of engineering materials. On the basis of a quasi-Monte Carlo (QMC) method, a consistent set of grain orientations is generated and used to compute the weighting factors for IPF normalization. The weighting factors are instrument dependent and were calculated for the engineering materials diffractometer VULCAN (Spallation Neutron Source, Oak Ridge National Laboratory). The QMC method is applied to face-centered cubic structures and can be easily extended to other crystallographic symmetries. Examples include 316LN stainless steel in situ loaded in tension at room temperature and an Al-2%Mg alloy, substantially deformed by cold rolling and in situ annealed up to 653 K.

KW - grain orientation

KW - inverse pole figures

KW - texture analysis

KW - thermomechanical behavior

KW - time-of flight neutron diffraction

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SN - 0021-8898

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SP - 2019

EP - 2029

JO - Journal of Applied Crystallography

JF - Journal of Applied Crystallography

IS - 6

ER -

Extracting grain-orientation-dependent data from in situ time-of-flight neutron diffraction. I. Inverse pole figures

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Keywords

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