SLAC/MEC LJ55 experiment on hcp-Fe plasticity ...
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Title :
SLAC/MEC LJ55 experiment on hcp-Fe plasticity under shock compression
Author(s) :
Merkel, Sébastien [Auteur]
Unité Matériaux et Transformations (UMET) - UMR 8207
Hok, Sovanndara [Auteur]
Bolme, Cindy [Auteur]
Rittman, Dylan [Auteur]
Ramos, Kyle James [Auteur]
Morrow, Benjamin [Auteur]
Lee, Hae Ja [Auteur]
Nagler, Bob [Auteur]
Galtier, Eric [Auteur]
Granados, Eduardo [Auteur]
Hashim, Akel [Auteur]
Mao, Wendy L [Auteur]
Gleason, Arianna E [Auteur]
Unité Matériaux et Transformations (UMET) - UMR 8207
Hok, Sovanndara [Auteur]
Bolme, Cindy [Auteur]
Rittman, Dylan [Auteur]
Ramos, Kyle James [Auteur]
Morrow, Benjamin [Auteur]
Lee, Hae Ja [Auteur]
Nagler, Bob [Auteur]
Galtier, Eric [Auteur]
Granados, Eduardo [Auteur]
Hashim, Akel [Auteur]
Mao, Wendy L [Auteur]
Gleason, Arianna E [Auteur]
Date of online release :
2021-09-24
Data repository :
Zenodo
HAL domain(s) :
Chimie/Matériaux
Physique [physics]/Matière Condensée [cond-mat]/Science des matériaux [cond-mat.mtrl-sci]
Physique [physics]/Physique [physics]/Géophysique [physics.geo-ph]
Physique [physics]/Astrophysique [astro-ph]
Planète et Univers [physics]/Astrophysique [astro-ph]
Planète et Univers [physics]/Sciences de la Terre
Physique [physics]/Matière Condensée [cond-mat]/Science des matériaux [cond-mat.mtrl-sci]
Physique [physics]/Physique [physics]/Géophysique [physics.geo-ph]
Physique [physics]/Astrophysique [astro-ph]
Planète et Univers [physics]/Astrophysique [astro-ph]
Planète et Univers [physics]/Sciences de la Terre
English abstract : [en]
Iron is a key constituent of planets and an important technological material. Here, we combine in situ ultrafast x-ray diffraction with laser-induced shock compression experiments on Fe up to 187(10) GPa and 4070(285) K ...
Show more >Iron is a key constituent of planets and an important technological material. Here, we combine in situ ultrafast x-ray diffraction with laser-induced shock compression experiments on Fe up to 187(10) GPa and 4070(285) K at 108 s−1 in strain rate to study the plasticity of hexagonal-close-packed (hcp)-Fe under extreme loading states. {10¯12} deformation twinning controls the polycrystalline Fe microstructures and occurs within 1 ns, highlighting the fundamental role of twinning in hcp polycrystals deformation at high strain rates. The measured deviatoric stress initially increases to a significant elastic overshoot before the onset of flow, attributed to a slower defect nucleation and mobility. The initial yield strength of materials deformed at high strain rates is thus several times larger than their longer-term flow strength. These observations illustrate how time-resolved ultrafast studies can reveal distinctive plastic behavior in materials under extreme environments.Show less >
Show more >Iron is a key constituent of planets and an important technological material. Here, we combine in situ ultrafast x-ray diffraction with laser-induced shock compression experiments on Fe up to 187(10) GPa and 4070(285) K at 108 s−1 in strain rate to study the plasticity of hexagonal-close-packed (hcp)-Fe under extreme loading states. {10¯12} deformation twinning controls the polycrystalline Fe microstructures and occurs within 1 ns, highlighting the fundamental role of twinning in hcp polycrystals deformation at high strain rates. The measured deviatoric stress initially increases to a significant elastic overshoot before the onset of flow, attributed to a slower defect nucleation and mobility. The initial yield strength of materials deformed at high strain rates is thus several times larger than their longer-term flow strength. These observations illustrate how time-resolved ultrafast studies can reveal distinctive plastic behavior in materials under extreme environments.Show less >
Language :
Anglais
Related reference(s) :
Administrative institution(s) :
Université de Lille
CNRS
INRAE
ENSCL
CNRS
INRAE
ENSCL
Collections :
Research team(s) :
Matériaux Terrestres et Planétaires
Submission date :
2023-12-01T08:19:10Z
2023-12-01T14:57:39Z
2023-12-05T10:40:48Z
2024-11-05T10:02:10Z
2023-12-01T14:57:39Z
2023-12-05T10:40:48Z
2024-11-05T10:02:10Z
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