Mechanical Impact of Heterogeneously Distributed H2O on Quartz Deformation
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https://hdl.handle.net/10037/34967Date
2024-07-31Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Pongrac, Petar; Jeřábek, Petr; Stunitz, Holger; Raimbourg, Hugues; Racek, Martin; Jollands, Michael C.; Gies, Nils; Lueder, Mona; Lexa, Ondrej; Nègre, LucilleAbstract
In order to identify relations between mechanical behavior, deformation mechanisms,
microstructural properties, and H2O distribution, Tana‐quartzite samples with added H2O ranging from 0 to
0.5 wt.% were deformed by axial shortening at constant displacement rates, at 900°C and 1 GPa, reaching up to
∼30% bulk strain. Samples with lower quantities of added H2O (0.1 and 0.2 wt.%) were in average ∼30 MPa
weaker than the as‐is samples with no added H2O. In contrast, samples with more than 0.2 wt.% added H2O
revealed more variable mechanical behavior, showing either weaker or stronger trend. The weaker samples
showed strain localization in their central parts in the vicinity of the thermocouple, that is, the hottest parts of the
samples, whereas the stronger samples showed localization in their upper, slightly colder parts. Bulk
deformation is accommodated by crystal plasticity and dissolution‐precipitation processes. Distribution of H2O
in our samples revealed systematic decrease of H2O content in the interiors of original grains, caused by
increasing strain and H2O draining into grain boundary regions. With increasing content of added H2O, the
quartz recrystallization gradually changes from subgrain‐rotation‐dominated to crack‐induced nucleation, along
with increasing quantity of melt/fluid pockets. The unexpected strain localization in the upper parts of stronger
samples most likely results from mode‐1‐cracking that led to drainage of grain boundaries (GB) due to the crack
dilatancy effect, and inhibited dissolution‐precipitation in the hottest part of the samples next to the
thermocouple. The locus of deformation isthen shifted to colder regions where more H2O is available along GB.
Publisher
WileyCitation
Pongrac P, Jeřábek P, Stunitz H, Raimbourg H, Racek M, Jollands, Gies N, Lueder, Lexa O, Nègre L. Mechanical Impact of Heterogeneously Distributed H2O on Quartz Deformation. Journal of Geophysical Research (JGR): Solid Earth. 2024;198(8)Metadata
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