Precision lattice parameter determination from transmission diffraction of thick specimens with irregular cross sections

S. R. Stock; M. Laugesen; H. Birkedal; A. Jakus; R. Shah; J. S. Park; J. D. Almer

doi:10.1107/S1600576718017132

Precision lattice parameter determination from transmission diffraction of thick specimens with irregular cross sections

S. R. Stock^*, M. Laugesen, H. Birkedal, A. Jakus, R. Shah, J. S. Park, J. D. Almer

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

10 Citations (Scopus)

Abstract

Accurate determination of lattice parameters from X-ray diffraction requires that the diffraction angles be measured very precisely, and significant errors result if the sample–detector separation differs from that assumed. Transmission diffraction from bones, which have a complex cross section and must be left intact, is a situation where this separation is difficult to measure and it may differ from position to position across the specimen. This article describes a method for eliminating the effect of variable sample cross section. Diffraction patterns for each position on the specimen are collected before and after 180° rotation about an axis normal to the cross section of interest. This places the centroid of the diffracting mass at the center of rotation and provides the absolute lattice parameters from the average apparent lattice parameters at the two rotation angles. Diffraction patterns were collected across the cross section of three specimens: a 3D-printed elliptical cylinder of Hyperelastic Bone (HB), which is composed primarily of synthetic hydroxyapatite (hAp), a 3D-printed HB model of the second metacarpal bone (Mc2), and a modern human Mc2 containing nanocrystalline carbonated apatite (cAp). Rietveld refinement was used to determine precise unit-cell parameters a_apparent and c_apparent for each pattern of each scan, and these values determined the actual average ⟨a⟩ and ⟨c⟩ for each sample. The results indicate that the 0°/180° rotation method works well enough to uncover variations approaching 1 × 10⁻³ Å in cAp unit-cell parameters in intact bones with irregular cross sections.

Original language	English
Journal	Journal of Applied Crystallography
Volume	52
Pages (from-to)	40-46
Number of pages	7
ISSN	0021-8898
DOIs	https://doi.org/10.1107/S1600576718017132
Publication status	Published - 2019

Keywords

bone
human second metacarpal bone
hydroxyapatite
Rietveld refinement
unit-cell parameters
X-ray diffraction

Access to Document

10.1107/S1600576718017132

Library access?

Check availability with the Royal Danish Library

Cite this

@article{984a5339220644aeb5fc3fed489f0ff0,

title = "Precision lattice parameter determination from transmission diffraction of thick specimens with irregular cross sections",

abstract = "Accurate determination of lattice parameters from X-ray diffraction requires that the diffraction angles be measured very precisely, and significant errors result if the sample–detector separation differs from that assumed. Transmission diffraction from bones, which have a complex cross section and must be left intact, is a situation where this separation is difficult to measure and it may differ from position to position across the specimen. This article describes a method for eliminating the effect of variable sample cross section. Diffraction patterns for each position on the specimen are collected before and after 180° rotation about an axis normal to the cross section of interest. This places the centroid of the diffracting mass at the center of rotation and provides the absolute lattice parameters from the average apparent lattice parameters at the two rotation angles. Diffraction patterns were collected across the cross section of three specimens: a 3D-printed elliptical cylinder of Hyperelastic Bone (HB), which is composed primarily of synthetic hydroxyapatite (hAp), a 3D-printed HB model of the second metacarpal bone (Mc2), and a modern human Mc2 containing nanocrystalline carbonated apatite (cAp). Rietveld refinement was used to determine precise unit-cell parameters aapparent and capparent for each pattern of each scan, and these values determined the actual average ⟨a⟩ and ⟨c⟩ for each sample. The results indicate that the 0°/180° rotation method works well enough to uncover variations approaching 1 × 10−3 {\AA} in cAp unit-cell parameters in intact bones with irregular cross sections.",

keywords = "bone, human second metacarpal bone, hydroxyapatite, Rietveld refinement, unit-cell parameters, X-ray diffraction",

author = "Stock, {S. R.} and M. Laugesen and H. Birkedal and A. Jakus and R. Shah and Park, {J. S.} and Almer, {J. D.}",

year = "2019",

doi = "10.1107/S1600576718017132",

language = "English",

volume = "52",

pages = "40--46",

journal = "Journal of Applied Crystallography",

issn = "0021-8898",

publisher = "International Union of Crystallography",

}

Precision lattice parameter determination from transmission diffraction of thick specimens with irregular cross sections. / Stock, S. R.; Laugesen, M.; Birkedal, H. et al.
In: Journal of Applied Crystallography, Vol. 52, 2019, p. 40-46.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

TY - JOUR

T1 - Precision lattice parameter determination from transmission diffraction of thick specimens with irregular cross sections

AU - Stock, S. R.

AU - Laugesen, M.

AU - Birkedal, H.

AU - Jakus, A.

AU - Shah, R.

AU - Park, J. S.

AU - Almer, J. D.

PY - 2019

Y1 - 2019

N2 - Accurate determination of lattice parameters from X-ray diffraction requires that the diffraction angles be measured very precisely, and significant errors result if the sample–detector separation differs from that assumed. Transmission diffraction from bones, which have a complex cross section and must be left intact, is a situation where this separation is difficult to measure and it may differ from position to position across the specimen. This article describes a method for eliminating the effect of variable sample cross section. Diffraction patterns for each position on the specimen are collected before and after 180° rotation about an axis normal to the cross section of interest. This places the centroid of the diffracting mass at the center of rotation and provides the absolute lattice parameters from the average apparent lattice parameters at the two rotation angles. Diffraction patterns were collected across the cross section of three specimens: a 3D-printed elliptical cylinder of Hyperelastic Bone (HB), which is composed primarily of synthetic hydroxyapatite (hAp), a 3D-printed HB model of the second metacarpal bone (Mc2), and a modern human Mc2 containing nanocrystalline carbonated apatite (cAp). Rietveld refinement was used to determine precise unit-cell parameters aapparent and capparent for each pattern of each scan, and these values determined the actual average ⟨a⟩ and ⟨c⟩ for each sample. The results indicate that the 0°/180° rotation method works well enough to uncover variations approaching 1 × 10−3 Å in cAp unit-cell parameters in intact bones with irregular cross sections.

AB - Accurate determination of lattice parameters from X-ray diffraction requires that the diffraction angles be measured very precisely, and significant errors result if the sample–detector separation differs from that assumed. Transmission diffraction from bones, which have a complex cross section and must be left intact, is a situation where this separation is difficult to measure and it may differ from position to position across the specimen. This article describes a method for eliminating the effect of variable sample cross section. Diffraction patterns for each position on the specimen are collected before and after 180° rotation about an axis normal to the cross section of interest. This places the centroid of the diffracting mass at the center of rotation and provides the absolute lattice parameters from the average apparent lattice parameters at the two rotation angles. Diffraction patterns were collected across the cross section of three specimens: a 3D-printed elliptical cylinder of Hyperelastic Bone (HB), which is composed primarily of synthetic hydroxyapatite (hAp), a 3D-printed HB model of the second metacarpal bone (Mc2), and a modern human Mc2 containing nanocrystalline carbonated apatite (cAp). Rietveld refinement was used to determine precise unit-cell parameters aapparent and capparent for each pattern of each scan, and these values determined the actual average ⟨a⟩ and ⟨c⟩ for each sample. The results indicate that the 0°/180° rotation method works well enough to uncover variations approaching 1 × 10−3 Å in cAp unit-cell parameters in intact bones with irregular cross sections.

KW - bone

KW - human second metacarpal bone

KW - hydroxyapatite

KW - Rietveld refinement

KW - unit-cell parameters

KW - X-ray diffraction

UR - http://www.scopus.com/inward/record.url?scp=85059680693&partnerID=8YFLogxK

U2 - 10.1107/S1600576718017132

DO - 10.1107/S1600576718017132

M3 - Journal article

SN - 0021-8898

VL - 52

SP - 40

EP - 46

JO - Journal of Applied Crystallography

JF - Journal of Applied Crystallography

ER -

Precision lattice parameter determination from transmission diffraction of thick specimens with irregular cross sections

Abstract

Keywords

Access to Document

Library access?

Other files and links

Fingerprint

Cite this