Dark-field hyperspectral X-ray imaging

C K Egan; SDM Jacques; T Connolley; M D Wilson; M C Veale; P Seller; R J Cernik

doi:10.1098/Rspa.2013.0629

Dark-field hyperspectral X-ray imaging

C K Egan, SDM Jacques, T Connolley, M D Wilson, M C Veale, P Seller, R J Cernik

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Abstract

In recent times, there has been a drive to develop non-destructive X-ray imaging techniques that provide chemical or physical insight. To date, these methods have generally been limited; either requiring raster scanning of pencil beams, using narrow bandwidth radiation and/or limited to small samples. We have developed a novel full-field radiographic imaging technique that enables the entire physio-chemical state of an object to be imaged in a single snapshot. The method is sensitive to emitted and scattered radiation, using a spectral imaging detector and polychromatic hard X-radiation, making it particularly useful for studying large dense samples for materials science and engineering applications. The method and its extension to three-dimensional imaging is validated with a series of test objects and demonstrated to directly image the crystallographic preferred orientation and formed precipitates across an aluminium alloy friction stir weld section.

Original language	English
Article number	20130629
Journal	PROCEEDINGS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES
Volume	470
Issue number	2165
DOIs	https://doi.org/10.1098/Rspa.2013.0629 https://doi.org/10.1098/rspa.2013.0629
Publication status	Published - 2014

Keywords

energy-dispersive x-ray diffraction
x-ray imaging
computed tomography
materials characterization
diffraction computed-tomography
active phase evolution
scanning tomography
system

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POST-PEER-REVIEW-NON-PUBLISHERS.PDFAccepted author manuscript, 1.17 MB

Structural Evolution across multiple time and length scales
Withers, P., Cartmell, S., Cernik, R., Derby, B., Eichhorn, S., Freemont, A., Hollis, C., Mummery, P., Sherratt, M., Thompson, G. & Watts, D.
1/06/11 → 31/05/16
Project: Research

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title = "Dark-field hyperspectral X-ray imaging",

abstract = "In recent times, there has been a drive to develop non-destructive X-ray imaging techniques that provide chemical or physical insight. To date, these methods have generally been limited; either requiring raster scanning of pencil beams, using narrow bandwidth radiation and/or limited to small samples. We have developed a novel full-field radiographic imaging technique that enables the entire physio-chemical state of an object to be imaged in a single snapshot. The method is sensitive to emitted and scattered radiation, using a spectral imaging detector and polychromatic hard X-radiation, making it particularly useful for studying large dense samples for materials science and engineering applications. The method and its extension to three-dimensional imaging is validated with a series of test objects and demonstrated to directly image the crystallographic preferred orientation and formed precipitates across an aluminium alloy friction stir weld section.",

keywords = "energy-dispersive x-ray diffraction, x-ray imaging, computed tomography, materials characterization, diffraction computed-tomography, active phase evolution, scanning tomography, system",

author = "Egan, {C K} and SDM Jacques and T Connolley and Wilson, {M D} and Veale, {M C} and P Seller and Cernik, {R J}",

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doi = "10.1098/Rspa.2013.0629",

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T1 - Dark-field hyperspectral X-ray imaging

AU - Egan, C K

AU - Jacques, SDM

AU - Connolley, T

AU - Wilson, M D

AU - Veale, M C

AU - Seller, P

AU - Cernik, R J

N1 - Ad4ci Times Cited:6 Cited References Count:34

PY - 2014

Y1 - 2014

N2 - In recent times, there has been a drive to develop non-destructive X-ray imaging techniques that provide chemical or physical insight. To date, these methods have generally been limited; either requiring raster scanning of pencil beams, using narrow bandwidth radiation and/or limited to small samples. We have developed a novel full-field radiographic imaging technique that enables the entire physio-chemical state of an object to be imaged in a single snapshot. The method is sensitive to emitted and scattered radiation, using a spectral imaging detector and polychromatic hard X-radiation, making it particularly useful for studying large dense samples for materials science and engineering applications. The method and its extension to three-dimensional imaging is validated with a series of test objects and demonstrated to directly image the crystallographic preferred orientation and formed precipitates across an aluminium alloy friction stir weld section.

AB - In recent times, there has been a drive to develop non-destructive X-ray imaging techniques that provide chemical or physical insight. To date, these methods have generally been limited; either requiring raster scanning of pencil beams, using narrow bandwidth radiation and/or limited to small samples. We have developed a novel full-field radiographic imaging technique that enables the entire physio-chemical state of an object to be imaged in a single snapshot. The method is sensitive to emitted and scattered radiation, using a spectral imaging detector and polychromatic hard X-radiation, making it particularly useful for studying large dense samples for materials science and engineering applications. The method and its extension to three-dimensional imaging is validated with a series of test objects and demonstrated to directly image the crystallographic preferred orientation and formed precipitates across an aluminium alloy friction stir weld section.

KW - energy-dispersive x-ray diffraction

KW - x-ray imaging

KW - computed tomography

KW - materials characterization

KW - diffraction computed-tomography

KW - active phase evolution

KW - scanning tomography

KW - system

U2 - 10.1098/Rspa.2013.0629

DO - 10.1098/Rspa.2013.0629

M3 - Article

SN - 1364-5021

VL - 470

JO - PROCEEDINGS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES

JF - PROCEEDINGS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES

IS - 2165

M1 - 20130629

ER -

Dark-field hyperspectral X-ray imaging

Abstract

Keywords

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Projects

Structural Evolution across multiple time and length scales

Cite this