Dislocation interactions during low-temperature plasticity of olivine and their impact on the evolution of lithospheric strength

Wallis, David; Hansen, Louis S.; Kumamoto, Kathryn M.; Thom, Christopher A.; Plümper, Oliver; Ohl, Markus; Durham, W. B.; Goldsby, D. L.; Armstrong, David E.J.; Meyers, C. D.; Goddard, Rellie M.; Warren, J. M.; Breithaupt, Thomas; Drury, M. R.; Wilkinson, Angus J.

doi:10.1016/j.epsl.2020.116349

Cited by 31 publications

(70 citation statements)

References 51 publications

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“…Therefore, although it is difficult to calculate the effective back stress from observed stress heterogeneity and vice versa, the mechanical data 31 and microstructural observations (Figs. 1, 2, and 4-6) 37,38 , are consistent in indicating the role of long-range dislocation interactions in generating kinematic strain hardening. Long-range internal stresses have been interpreted to play a key role in establishing steady-state creep by dislocationaccommodated grain boundary sliding, which was inferred by Hansen et al 23 to be the dominant deformation mechanism in the aggregates deformed at high temperatures that we investigated.…”

Section: Discussionmentioning

confidence: 52%

“…Strainhardening transients are exhibited by single crystals of olivine deforming by both low-temperature plasticity [30][31][32] and powerlaw creep at high temperatures 9,33,34 , with the transition between mechanisms occurring at temperatures of~1000-1100°C at typical experimental stresses and strain rates. Microstructural analyses of single crystals deformed in both temperature regimes indicate that strain hardening results from increases in dislocation density 9,[35][36][37] , short-range dislocation interactions 33 , and long-range interactions among dislocations via their stress fields 37,38 . Short-range interactions involve local rearrangement of atoms in the vicinity of adjacent dislocation cores.…”

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confidence: 99%

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Dislocation interactions in olivine control postseismic creep of the upper mantle

et al. 2021

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Changes in stress applied to mantle rocks, such as those imposed by earthquakes, commonly induce a period of transient creep, which is often modelled based on stress transfer among slip systems due to grain interactions. However, recent experiments have demonstrated that the accumulation of stresses among dislocations is the dominant cause of strain hardening in olivine at temperatures ≤600 °C, raising the question of whether the same process contributes to transient creep at higher temperatures. Here, we demonstrate that olivine samples deformed at 25 °C or 1150–1250 °C both preserve stress heterogeneities of ~1 GPa that are imparted by dislocations and have correlation lengths of ~1 μm. The similar stress distributions formed at these different temperatures indicate that accumulation of stresses among dislocations also provides a contribution to transient creep at high temperatures. The results motivate a new generation of models that capture these intragranular processes and may refine predictions of evolving mantle viscosity over the earthquake cycle.

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Section: Discussionmentioning

confidence: 52%

mentioning

confidence: 99%

Dislocation interactions in olivine control postseismic creep of the upper mantle

et al. 2021

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“…Laboratory experiments indicate that grain size reduction (Kumamoto et al., 2017) and increasing plastic strain (Hansen et al., 2019) lead to significant hardening of olivine at low temperature. At subduction zones, large bending‐related stresses in the lower part of the plate may create abundant dislocations with low mobility and large plastic strain, leading to high yield strength (Hansen et al., 2019; Wallis et al., 2020). Therefore, when flexed by long‐wavelength and high‐amplitude loads, the plate stiffens and does not readjust to smaller loads, resulting in low compensation and therefore high inferred

T_{e}

.…”

Section: Implications For the Rheology Of Oceanic Lithospherementioning

confidence: 99%

“…Strain hardening only occurs at low temperature, large plastic strain (up to 2%), and small grain size, and is limited by the onset of diffusion‐based, steady‐state creep mechanisms at higher temperature (Hansen et al., 2019; Wallis et al., 2020). Such hardening is therefore not expected to operate where very young and hot lithosphere is subducting, for example, in southern Chile, Central America and the Cascadia subduction zone, where temperature (and therefore steady‐state creep) effects dominate.…”

Section: Implications For the Rheology Of Oceanic Lithospherementioning

confidence: 99%

“…Finally, although this model remains speculative, hardening mechanisms remain to be rigorously incorporated and tested in yield strength envelope modeling of

T_{e}

(see Hansen et al., 2019; Wallis et al., 2020). In addition to the effect of temperature on yield strength, the amount of plastic strain (which can be calculated from observed plate curvature) could be considered when interpreting

T_{e}

results over oceanic domains.…”

Section: Implications For the Rheology Of Oceanic Lithospherementioning

confidence: 99%

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What Controls Effective Elastic Thickness of the Lithosphere in the Pacific Ocean?

Audet

et al. 2021

JGR Solid Earth

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The effective elastic thickness (Te) of the lithosphere is a proxy for mechanical strength and can be used to constrain lithospheric rheology and understand how surface deformation relates to deep Earth processes. Here, we map Te variations over the Pacific Ocean from the inversion of the admittance between free‐air gravity anomaly and bathymetry data calculated using a continuous wavelet transform, taking both surface and subsurface loads into account. The Pacific lithosphere show Te ranging between 0 and 80 km with a mean of 13.5 km and a standard deviation of 12.3 km. We find that Te is generally poorly correlated with plate loading age, crustal age, heat flow and Curie point depth, except for relatively young (<60 Ma) and warm lithospheres. Most oceanic plateaus and seamounts show Te≤10 km, with the lowest values (<5 km) around active spreading centers. The highest Te estimates (>30 km) are found along subduction zones and around the Hawaiian‐Emperor Seamount Chain (HESC). Taken together, these results support a temperature control on Te for small loads and warm lithosphere through steady‐state creep processes, but strain hardening operating at large plastic strain and low temperature could explain high Te associated with large‐amplitude and long‐wavelength loads (subduction zones and the HESC) and should be incorporated in yield strength models of oceanic Te.

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Dislocation creep of olivine: Low-temperature plasticity controls transient creep at high temperatures

Hansen¹,

Wallis²,

Breithaupt³

et al. 2020

Preprint

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Dislocation interactions during low-temperature plasticity of olivine and their impact on the evolution of lithospheric strength

Cited by 31 publications

References 51 publications

Dislocation interactions in olivine control postseismic creep of the upper mantle

Dislocation interactions in olivine control postseismic creep of the upper mantle

What Controls Effective Elastic Thickness of the Lithosphere in the Pacific Ocean?

Dislocation creep of olivine: Low-temperature plasticity controls transient creep at high temperatures

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