An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems

Arthur Sakellariou; Tim J. Senden; Tim J. Sawkins; Mark A. Knackstedt; Michael L. Turner; Anthony C. Jones; Mohammad Saadatfar; Ray J. Roberts; Ajay Limaye; Christoph H. Arns; Adrian P. Sheppard; Rob M. Sok

doi:10.1117/12.559200

An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems

Arthur Sakellariou^*, Tim J. Senden, Tim J. Sawkins, Mark A. Knackstedt, Michael L. Turner, Anthony C. Jones, Mohammad Saadatfar, Ray J. Roberts, Ajay Limaye, Christoph H. Arns, Adrian P. Sheppard, Rob M. Sok

^*Corresponding author for this work

Research output: Contribution to journal › Conference article › peer-review

35 Citations (Scopus)

Abstract

A fully integrated X-ray tomography facility with the ability to generate tomograms with 2048³ voxels at 2 micron spatial resolution was built to satisfy the requirements of a virtual materials testing laboratory. The instrument comprises of a continuously pumped micro-focus X-ray gun, a milli-degree rotation stage and a high resolution and large field X-ray camera, configured in a cone beam geometry with a circular trajectory. The purpose of this facility is to routinely analyse and investigate real world biological, geological and synthetic materials at a scale in which the traditional domains of physics, chemistry, biology and geology merge. During the first 2 years of operation, approximately 4 Terabytes of data have been collected, processed and analysed, both as static and in some cases as composite dynamic data sets. This incorporates over 300 tomograms with 1024³ voxels and 50 tomograms with 2048³ voxels for a wide range of research fields. Specimens analysed include sedimentary rocks, soils, bone, soft tissue, ceramics, fibre-reinforced composites, foams, wood, paper, fossils, sphere packs, bio-morphs and small animals. In this paper, the flexibility of the facility is highlighted with some prime examples.

Original language	English
Article number	51
Pages (from-to)	473-484
Number of pages	12
Journal	Proceedings of SPIE - The International Society for Optical Engineering
Volume	5535
DOIs	https://doi.org/10.1117/12.559200
Publication status	Published - 2004
Event	Developments in X-Ray Tomography IV - Denver, CO, United States Duration: 4 Aug 2004 → 6 Aug 2004

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Sakellariou, A., Senden, T. J., Sawkins, T. J., Knackstedt, M. A., Turner, M. L., Jones, A. C., Saadatfar, M., Roberts, R. J., Limaye, A., Arns, C. H., Sheppard, A. P., & Sok, R. M. (2004). An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems. Proceedings of SPIE - The International Society for Optical Engineering, 5535, 473-484. Article 51. https://doi.org/10.1117/12.559200

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title = "An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems",

abstract = "A fully integrated X-ray tomography facility with the ability to generate tomograms with 20483 voxels at 2 micron spatial resolution was built to satisfy the requirements of a virtual materials testing laboratory. The instrument comprises of a continuously pumped micro-focus X-ray gun, a milli-degree rotation stage and a high resolution and large field X-ray camera, configured in a cone beam geometry with a circular trajectory. The purpose of this facility is to routinely analyse and investigate real world biological, geological and synthetic materials at a scale in which the traditional domains of physics, chemistry, biology and geology merge. During the first 2 years of operation, approximately 4 Terabytes of data have been collected, processed and analysed, both as static and in some cases as composite dynamic data sets. This incorporates over 300 tomograms with 10243 voxels and 50 tomograms with 20483 voxels for a wide range of research fields. Specimens analysed include sedimentary rocks, soils, bone, soft tissue, ceramics, fibre-reinforced composites, foams, wood, paper, fossils, sphere packs, bio-morphs and small animals. In this paper, the flexibility of the facility is highlighted with some prime examples.",

keywords = "Mesoscale physics, Porous media, Transport and mechanical properties, X-ray micro-tomography",

author = "Arthur Sakellariou and Senden, {Tim J.} and Sawkins, {Tim J.} and Knackstedt, {Mark A.} and Turner, {Michael L.} and Jones, {Anthony C.} and Mohammad Saadatfar and Roberts, {Ray J.} and Ajay Limaye and Arns, {Christoph H.} and Sheppard, {Adrian P.} and Sok, {Rob M.}",

year = "2004",

doi = "10.1117/12.559200",

language = "English",

volume = "5535",

pages = "473--484",

journal = "Proceedings of SPIE - The International Society for Optical Engineering",

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note = "Developments in X-Ray Tomography IV ; Conference date: 04-08-2004 Through 06-08-2004",

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Sakellariou, A, Senden, TJ, Sawkins, TJ, Knackstedt, MA, Turner, ML, Jones, AC, Saadatfar, M, Roberts, RJ, Limaye, A, Arns, CH, Sheppard, AP & Sok, RM 2004, 'An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems', Proceedings of SPIE - The International Society for Optical Engineering, vol. 5535, 51, pp. 473-484. https://doi.org/10.1117/12.559200

An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems. / Sakellariou, Arthur; Senden, Tim J.; Sawkins, Tim J. et al.
In: Proceedings of SPIE - The International Society for Optical Engineering, Vol. 5535, 51, 2004, p. 473-484.

Research output: Contribution to journal › Conference article › peer-review

TY - JOUR

T1 - An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems

AU - Sakellariou, Arthur

AU - Senden, Tim J.

AU - Sawkins, Tim J.

AU - Knackstedt, Mark A.

AU - Turner, Michael L.

AU - Jones, Anthony C.

AU - Saadatfar, Mohammad

AU - Roberts, Ray J.

AU - Limaye, Ajay

AU - Arns, Christoph H.

AU - Sheppard, Adrian P.

AU - Sok, Rob M.

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AB - A fully integrated X-ray tomography facility with the ability to generate tomograms with 20483 voxels at 2 micron spatial resolution was built to satisfy the requirements of a virtual materials testing laboratory. The instrument comprises of a continuously pumped micro-focus X-ray gun, a milli-degree rotation stage and a high resolution and large field X-ray camera, configured in a cone beam geometry with a circular trajectory. The purpose of this facility is to routinely analyse and investigate real world biological, geological and synthetic materials at a scale in which the traditional domains of physics, chemistry, biology and geology merge. During the first 2 years of operation, approximately 4 Terabytes of data have been collected, processed and analysed, both as static and in some cases as composite dynamic data sets. This incorporates over 300 tomograms with 10243 voxels and 50 tomograms with 20483 voxels for a wide range of research fields. Specimens analysed include sedimentary rocks, soils, bone, soft tissue, ceramics, fibre-reinforced composites, foams, wood, paper, fossils, sphere packs, bio-morphs and small animals. In this paper, the flexibility of the facility is highlighted with some prime examples.

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KW - Porous media

KW - Transport and mechanical properties

KW - X-ray micro-tomography

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U2 - 10.1117/12.559200

DO - 10.1117/12.559200

M3 - Conference article

AN - SCOPUS:20144378880

SN - 0277-786X

VL - 5535

SP - 473

EP - 484

JO - Proceedings of SPIE - The International Society for Optical Engineering

JF - Proceedings of SPIE - The International Society for Optical Engineering

M1 - 51

T2 - Developments in X-Ray Tomography IV

Y2 - 4 August 2004 through 6 August 2004

ER -

An x-ray tomography facility for quantitative prediction of mechanical and transport properties in geological, biological and synthetic systems

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