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Methodology toward 3D micro X-ray fluorescence imaging using an energy dispersive charge-coupled device detector

Jan Garrevoet (UGent) , Bart Vekemans (UGent) , Pieter Tack (UGent) , Björn De Samber (UGent) , Sylvia Schmitz, Frank E Brenker, Gerald Falkenberg and Laszlo Vincze (UGent)
(2014) ANALYTICAL CHEMISTRY. 86(23). p.11826-11832
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Abstract
A new three-dimensional (3D) micro X-ray fluorescence (mu XRF) methodology based on a novel 2D energy dispersive CCD detector has been developed and evaluated at the P06 beamline of the Petra-III storage ring (DESY) in Hamburg, Germany. This method is based on the illumination of the investigated sample cross-section by a horizontally focused beam (vertical sheet beam) while fluorescent X-rays are detected perpendicularly to the sheet beam by a 2D energy dispersive (ED) CCD detector allowing the collection of 2D cross-sectional elemental images of a certain depth within the sample, limited only by signal self-absorption effects. 3D elemental information is obtained by a linear scan of the sample in the horizontal direction across the vertically oriented sheet beam and combining the detected cross-sectional images into a 3D elemental distribution data set. Results of the 3D mu XRF analysis of mineral inclusions in natural deep Earth diamonds are presented to illustrate this new methodology.
Keywords
DIAMONDS, INCLUSIONS, MANTLE, MATO-GROSSO, TRANSITION ZONE, BRAZIL, PHASE, JUINA, XRF

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MLA
Garrevoet, Jan, et al. “Methodology toward 3D Micro X-Ray Fluorescence Imaging Using an Energy Dispersive Charge-Coupled Device Detector.” ANALYTICAL CHEMISTRY, vol. 86, no. 23, 2014, pp. 11826–32, doi:10.1021/ac503410s.
APA
Garrevoet, J., Vekemans, B., Tack, P., De Samber, B., Schmitz, S., Brenker, F. E., … Vincze, L. (2014). Methodology toward 3D micro X-ray fluorescence imaging using an energy dispersive charge-coupled device detector. ANALYTICAL CHEMISTRY, 86(23), 11826–11832. https://doi.org/10.1021/ac503410s
Chicago author-date
Garrevoet, Jan, Bart Vekemans, Pieter Tack, Björn De Samber, Sylvia Schmitz, Frank E Brenker, Gerald Falkenberg, and Laszlo Vincze. 2014. “Methodology toward 3D Micro X-Ray Fluorescence Imaging Using an Energy Dispersive Charge-Coupled Device Detector.” ANALYTICAL CHEMISTRY 86 (23): 11826–32. https://doi.org/10.1021/ac503410s.
Chicago author-date (all authors)
Garrevoet, Jan, Bart Vekemans, Pieter Tack, Björn De Samber, Sylvia Schmitz, Frank E Brenker, Gerald Falkenberg, and Laszlo Vincze. 2014. “Methodology toward 3D Micro X-Ray Fluorescence Imaging Using an Energy Dispersive Charge-Coupled Device Detector.” ANALYTICAL CHEMISTRY 86 (23): 11826–11832. doi:10.1021/ac503410s.
Vancouver
1.
Garrevoet J, Vekemans B, Tack P, De Samber B, Schmitz S, Brenker FE, et al. Methodology toward 3D micro X-ray fluorescence imaging using an energy dispersive charge-coupled device detector. ANALYTICAL CHEMISTRY. 2014;86(23):11826–32.
IEEE
[1]
J. Garrevoet et al., “Methodology toward 3D micro X-ray fluorescence imaging using an energy dispersive charge-coupled device detector,” ANALYTICAL CHEMISTRY, vol. 86, no. 23, pp. 11826–11832, 2014.
@article{5805409,
  abstract     = {{A new three-dimensional (3D) micro X-ray fluorescence (mu XRF) methodology based on a novel 2D energy dispersive CCD detector has been developed and evaluated at the P06 beamline of the Petra-III storage ring (DESY) in Hamburg, Germany. This method is based on the illumination of the investigated sample cross-section by a horizontally focused beam (vertical sheet beam) while fluorescent X-rays are detected perpendicularly to the sheet beam by a 2D energy dispersive (ED) CCD detector allowing the collection of 2D cross-sectional elemental images of a certain depth within the sample, limited only by signal self-absorption effects. 3D elemental information is obtained by a linear scan of the sample in the horizontal direction across the vertically oriented sheet beam and combining the detected cross-sectional images into a 3D elemental distribution data set. Results of the 3D mu XRF analysis of mineral inclusions in natural deep Earth diamonds are presented to illustrate this new methodology.}},
  author       = {{Garrevoet, Jan and Vekemans, Bart and Tack, Pieter and De Samber, Björn and Schmitz, Sylvia and Brenker, Frank E and Falkenberg, Gerald and Vincze, Laszlo}},
  issn         = {{0003-2700}},
  journal      = {{ANALYTICAL CHEMISTRY}},
  keywords     = {{DIAMONDS,INCLUSIONS,MANTLE,MATO-GROSSO,TRANSITION ZONE,BRAZIL,PHASE,JUINA,XRF}},
  language     = {{eng}},
  number       = {{23}},
  pages        = {{11826--11832}},
  title        = {{Methodology toward 3D micro X-ray fluorescence imaging using an energy dispersive charge-coupled device detector}},
  url          = {{http://doi.org/10.1021/ac503410s}},
  volume       = {{86}},
  year         = {{2014}},
}
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