Dynamic loading platforms coupled to ultra-high speed X-ray imaging at beamline ID19 of the European Synchrotron ESRF.
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| Title: | Dynamic loading platforms coupled to ultra-high speed X-ray imaging at beamline ID19 of the European Synchrotron ESRF. |
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| Authors: | Rack, A.1 (AUTHOR) shock-bag@esrf.fr, Lukić, B.1,2 (AUTHOR), Chapman, D. J.3 (AUTHOR), Strucka, J.4 (AUTHOR), Yao, Y.4 (AUTHOR), Mughal, K.4 (AUTHOR), Maler, D.5 (AUTHOR), Efimov, S.5 (AUTHOR), Belozerov, O.5 (AUTHOR), Krasik, Y.5 (AUTHOR), Chittenden, J. P.4 (AUTHOR), Bland, S. N.4 (AUTHOR), Sollier, A.6,7 (AUTHOR), Ganzenmüller, G. C.8 (AUTHOR), Cohen, A.9 (AUTHOR), Levi-Hevroni, D.9 (AUTHOR), Proud, W. G.4 (AUTHOR), Song, P.3,10 (AUTHOR), Eakins, D. E.3 (AUTHOR) |
| Source: | High Pressure Research. Sep2024, Vol. 44 Issue 3, p400-417. 18p. |
| Subjects: | Dynamic testing of materials, Synchrotron radiation, Coherence (Optics), Light sources, X-ray imaging |
| Abstract: | The intersection of dynamic compression, high-rate material response and X-ray science has seen rapid growth, leading to the establishment of specialized end-stations at international facilities such as Linac Coherent Light Source LCLS (Matter at Extreme Conditions – MEC) and Advanced Photon Source APS (Dynamic Compression Sector – DCS), both USA. Although these facilities excel in working with X-rays tailored for small material volumes (i.e. $\lt 1\, {\rm mm}^3$ < 1 mm 3 ), it needs a different approach to delve into subsequent processes. This is particularly the case in the transition from the micro- to mesoscale: here the ESRF distinguishes itself. The large beam size (several cm2) of the ID19 beamline, in conjunction with a strong high energy component, source flux density, and outstanding imaging sensitivity, enables sub-surface visualization of engineering-scale structures as well as natural systems in representative volume, under high rate and shock. This is particularly valuable when studying materials with complex mesostructures and heterogeneities on relevant volumetric scales, which often dominate the dynamic material response. The study of the behavior of materials under dynamic loading presents a unique challenge due to inherently spanning over multiple lengths- and timescales. The evolution of sudden (thermo)mechanical excitation, starting from the lattice scale and progressing through grains, phase domains, and ultimately to structures, exhibits a spectrum of responses spanning from the microscopic to bulk length scales. Consequently, a diverse range of diagnostics as well as driver instrumentation is required to identify, study, and characterize this material response spectrum. This article shall introduce platforms available at beamline ID19 and underline their potential by selected showcase applications. Community access proposals such as the beamtime Block Allocation Group (BAG) allow for access in a routine manner. [ABSTRACT FROM AUTHOR] |
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| Database: | Engineering Source |
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| Abstract: | The intersection of dynamic compression, high-rate material response and X-ray science has seen rapid growth, leading to the establishment of specialized end-stations at international facilities such as Linac Coherent Light Source LCLS (Matter at Extreme Conditions – MEC) and Advanced Photon Source APS (Dynamic Compression Sector – DCS), both USA. Although these facilities excel in working with X-rays tailored for small material volumes (i.e. $\lt 1\, {\rm mm}^3$ < 1 mm 3 ), it needs a different approach to delve into subsequent processes. This is particularly the case in the transition from the micro- to mesoscale: here the ESRF distinguishes itself. The large beam size (several cm2) of the ID19 beamline, in conjunction with a strong high energy component, source flux density, and outstanding imaging sensitivity, enables sub-surface visualization of engineering-scale structures as well as natural systems in representative volume, under high rate and shock. This is particularly valuable when studying materials with complex mesostructures and heterogeneities on relevant volumetric scales, which often dominate the dynamic material response. The study of the behavior of materials under dynamic loading presents a unique challenge due to inherently spanning over multiple lengths- and timescales. The evolution of sudden (thermo)mechanical excitation, starting from the lattice scale and progressing through grains, phase domains, and ultimately to structures, exhibits a spectrum of responses spanning from the microscopic to bulk length scales. Consequently, a diverse range of diagnostics as well as driver instrumentation is required to identify, study, and characterize this material response spectrum. This article shall introduce platforms available at beamline ID19 and underline their potential by selected showcase applications. Community access proposals such as the beamtime Block Allocation Group (BAG) allow for access in a routine manner. [ABSTRACT FROM AUTHOR] |
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| ISSN: | 08957959 |
| DOI: | 10.1080/08957959.2024.2370369 |