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Deformation mechanisms, rheology and tectonics : microstructures, mechanics and anisotropy (2011)

Prior, David J. ; Rutter, E. H. 1946- ; Tatham, Daniel J.

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Keywords: Rock deformation ; Geology, Structural ; Rock mechanics ; Aufsatzsammlung ; Gestein ; Deformation ; Deformationsverhalten ; Gefüge ; Rheologie ; Tektonik ; Strukturgeologie ; Deformation ; Kristallgitter ; Anisotropie

Description / Table of Contents: This collection of papers presents recent advances in the study of deformation mechanisms and rheology and their applications to tectonics. Many of the contributions exploit new petrofabric techniques, particularly electron backscatter diffraction, to help understand evolution of rock microstructure and mechanical properties. Papers in the first section (lattice preferred orientations and anisotropy) show a growing emphasis on the determination of elastic properties from petrofabrics, from which acoustic properties can be computed for comparison with in-situ seismic measurements. Such research will underpin geodynamic interpretation of large-scale active tectonics. Contributions in the second section (microstructures, mechanisms and rheology) study the relations between microstructural evolution during deformation and mechanical properties. Many of the papers explore how different mechanisms compete and interact to control the evolution of grain size and petrofabrics. Contributors make use of combinations of laboratory experiments, field studies and computational methods, and several relate microstructural and mechanical evolution to large-scale tectonic processes observed in nature--

Type of Medium: Online Resource

Pages: 1 Online-Ressource (XI, 342 Seiten)

ISBN: 9781862393387

Series Statement: Geological Society special publication 360

URL: http://sp.lyellcollection.org/content/360/1

DDC: 551.8

RVK:

TG 3000

Language: English

Note: Deformation mechanisms, rheology and tectonics: microstructures, mechanics and anisotropy: introduction , Constraints on the seismic properties of the middle and lower continental crust , Mica-controlled anisotropy within mid-to-upper crustal mylonites: an EBSD study of mica fabrics in the Alpine Fault Zone, New Zealand , From crystal to crustal: petrofabric-derived seismic modelling of regional tectonics , Deformation mechanisms of plagioclase and seismic anisotropy of the Acebuches metabasites (SW Iberian massif) , Seismic velocity in antigorite-bearing serpentinite mylonites , Obliteration of olivine crystallographic preferred orientation patterns in subduction-related antigorite-bearing mantle peridotite: an example from the Higashi-Akaishi body, SW Japan , Dissolution precipitation creep versus crystalline plasticity in high-pressure metamorphic serpentinites , Crystal fabric development and slip systems in a quartz mylonite: an approach via transmission electron microscopy and viscoplastic self-consistent modelling , Calculating anisotropic physical properties from texture data using the MTEX open-source package , The microstructural and rheological evolution of shear zones , Torsion experiments on coarse-grained dunite: implications for microstructural evolution when diffusion creep is suppressed , Characterization of microstructures and interpretation of flow mechanisms in naturally deformed, fine-grained anhydrite by means of EBSD analysis , Grain growth and the lifetime of diffusion creep deformation , Microstructures in deforming-reactive systems , Biases in three-diemensional vorticity analysis using porphyroclast system: limits and application to natural examples , Diffusion-creep modelling of fibrous pressure shadows II: influence of inclusion size and interface roughness , Rock mechanics constraints on mid-crustal low-viscosity flow beneath Tibet

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Geochemical and EBSD (electron backscatter diffraction) data test in University of Otago (2019)

Shao, Yilun ; Prior, David J ; Scott, James M ; [et al.]

PANGAEA

In: Supplement to: Shao, Yilun; Prior, David J; Scott, James M; Negrini, Marianne (submitted): Pre-Alpine Fault fabrics in mantle xenoliths from East Otago, South Island, New Zealand.

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Publication Date: 2023-01-13

Description: Major and minor geochemistry information and measured EBSD (electron backscatter diffraction), accompanied with MTEX toolbox scripts example.

Keywords: EBSD; Major element; minor element; MTEX script

Type: Dataset

Format: application/zip, 257.8 MBytes

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Band-pass-filtered ice-sheet surface elevation, thickness, velocity and derived data maps for the northern Greenland Ice Sheet (2018)

Bons, Paul D ; Kleiner, Thomas ; Llorens, Maria-Gema ; [et al.]

PANGAEA

In: Supplement to: Bons, Paul D; Kleiner, Thomas; Llorens, Maria-Gema; Prior, David J; Sachau, Till; Weikusat, Ilka; Jansen, Daniela (2018): Greenland Ice Sheet: Higher Nonlinearity of Ice Flow Significantly Reduces Estimated Basal Motion. Geophysical Research Letters, 45(13), 6542-6548, https://doi.org/10.1029/2018GL078356

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Publication Date: 2023-02-06

Keywords: File content; File format; File name; File size; MULT; Multiple investigations; Northern_Greenland_Ice_Sheet; Uniform resource locator/link to file

Type: Dataset

Format: text/tab-separated-values, 75 data points

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Seismic anisotropy of temperate ice in polar ice sheets (2020)

Llorens, Maria-Gema ; Griera, Albert ; Bons, Paul D. ; [et al.]

AGU

In: EPIC3Journal of Geophysical Research: Earth Surface, AGU, 125, pp. e2020JF005714, ISSN: 2169-9003

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Publication Date: 2020-11-02

Description: We present a series of simple shear numerical simulations of dynamic recrystallization of two‐phase non‐linear viscous materials that represent temperate ice. Firstly, we investigate the effect of the presence of water on the resulting microstructures and, secondly, how water influences on P‐wave (Vp) and fast S‐wave (Vs) velocities. Regardless the water percentage, all simulations evolve from a random fabric to a vertical single maximum. For a purely solid aggregate, the highest Vp quickly aligns with the maximum c‐axis orientation. At the same time, the maximum c‐axis development reduces Vs in this orientation. When water is present, the developed maximum c‐axis orientation is less intense, which results in lower Vp and Vs. At high percentage of water, Vp does not align with the maximum c‐axis orientation. If the bulk modulus of ice is assumed for the water phase (i.e., implying that water is at high pressure), we find a remarkable decrease of Vs while Vp remains close to the value for purely solid ice. These results suggest that the decrease in Vs observed at the base of the ice sheets could be explained by the presence of water at elevated pressure, which would reside in isolated pockets at grain triple junctions. Under these conditions water would not favor sliding between ice grains. However, if we consider that deformation dominates over recrystallization water pockets get continuously stretched, allowing water films to be located at grain boundaries. This configuration would modify and even overprint the maximum c‐axis‐dependent orientation and the magnitude of seismic anisotropy.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

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Insights into seismic anisotropy of temperate ice during simple shear deformation (2020)

Llorens, Maria-Gema ; Griera, Albert ; Gomez-Rivas, Enrique ; [et al.]

Computational Infrastructure for Geodynamics (CIG)

In: EPIC3Tectonics Community Science Workshop, virtual, 2020-07-27-2020-07-31University of California, Davis, Computational Infrastructure for Geodynamics (CIG)

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Publication Date: 2020-08-03

Description: The ice mass balances of Antarctic and Greenland ice sheets represent the largest uncertainty for predicting future sea-level rise. Understanding how ice flows from the accumulation to the ablation zone is therefore crucial for correctly estimating the changing mass in polar ice-sheets. On Earth, ice crystals have a hexagonal symmetry (ice lh) with a strong anisotropy favouring basal slip. This results in a progressive development of a vertical c-axis preferred orientation (LPO) of ice polycrystalline aggregates during deformation. In depth, the elastic anisotropy of polycrystalline ice gradually increases due the development of a vertical LPO. Observations of P-wave (Vp) and S-wave (Vs) velocities in ice sheets reveal a strong decrease of ~25% of Vs in depth, while Vp remains approximately constant. According to Wittlinger and Farra (2015) the low Vs may be due to the presence of unfrozen liquids resulting from pre-melting at grain joints and/or melting of chemical solutions buried in ice. Although previous studies of two-phase rocks (including melt and water) show that seismic velocities depend on both LPO and water content, studies on the effect of melt on polar ice seismic velocity are scarce. In this contribution we investigate the changes in P- and faster S-wave velocities during deformation of polycrystalline ice with different melt fractions.

Repository Name: EPIC Alfred Wegener Institut

Type: Conference , notRev

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Greenland Ice Sheet - Higher non-linearity of ice flow significantly reduces estimated basal motion (2018)

Bons, Paul D. ; Kleiner, Thomas ; Llorens, Maria-Gema ; [et al.]

AGU, Wiley

In: EPIC3Geophysical Research Letters, AGU, Wiley, 45(13), pp. 6542-6548, ISSN: 00948276

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Publication Date: 2018-07-30

Description: In times of warming in polar regions, the prediction of ice sheet discharge is of utmost importance to society, because of its impact on sea level rise. In simulations the flow rate of ice is usually implemented as proportional to the differential stress to the power of the exponent n=3. This exponent influences the softness of the modeled ice, as higher values would produce faster flow under equal stress. We show that the stress exponent, which best fits the observed state of the Greenland Ice Sheet, equals n=4. Our results, which are not dependent on a possible basal sliding component of flow, indicate that most of the interior northern ice sheet is currently frozen to bedrock, except for the large ice streams and marginal ice. Ice in the polar ice sheets flows towards the oceans under its own weight. Knowing how fast the ice flows is of crucial importance to predict future sea level rise. The flow has two components: (1) internal shearing flow of ice and (2) basal motion, which is sliding along the base of ice sheets, especially when the ice melts at this base. To determine the first component we need to know how "soft" the ice is. By considering the flow velocities at the surface of the northern Greenland Ice Sheet and calculating the stresses that cause the flow, we determined that the ice is effectively softer than is usually assumed. Previous studies indicated that the base of the ice is thawed in large parts (up to about 50%) of the Greenland Ice Sheet. Our study shows that that is probably overestimated, because these studies assumed ice to be harder than it actually is. Our new assessment reduces the area with basal motion and thus melting to about 6-13% in the Greenland study area.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

Format: application/pdf

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Development of crystallographic preferred orientation during cataclasis in low-temperature carbonate fault gouge (2020)

Demurtas, Matteo ; Smith, Steven ; Prior, David J. ; [et al.]

Elsevier

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Publication Date: 2020-02-18

Description: Grain size reduction due to cataclasis is a key process controlling fault frictional properties during the seismic cycle. We investigated the role of cleavage planes on fracturing and microstructural evolution during cataclasis in wet and dry carbonate fault gouges (50 wt% calcite, 50 wt% dolomite) deformed in a rotary-shear apparatus over a wide range of slip rates (30 μms−1 to 1 ms−1) and displacements (0.05–0.4 m). During shearing, progressive strain localization forms a narrow slip zone that undergoes significant frictional heating (at high slip rates), but the bulk gouge always accommodates low finite shear strains and deforms at low temperatures. Microstructural analysis of the bulk gouges indicates that deformation occurred by brittle fracturing and twinning. Microfractures in calcite are closely spaced, often exploit cleavage r-rhomb planes, and occur mainly subparallel to the expected principal stress orientation (σ1). Instead, twin planes typically occur sub-perpendicular to σ1. Electron backscatter diffraction analysis of the bulk gouges shows that calcite develops a well-defined crystallographic preferred orientation (CPO) at all investigated deformation conditions. The CPO is defined by a clustering of the calcite c-axes around an orientation sub-parallel to σ1. The calcite CPO is interpreted to result from grain rotation during granular flow, followed by brittle fracturing that occurred preferentially along calcite cleavage planes. This interpretation is supported by measurements of calcite grain shape-preferred orientations that show a population of elongate calcite grains oriented with their long axes sub-parallel to σ1. Our experimental results indicate that well-defined CPOs can form at low temperature in cataclastic fault rocks, and that mineral cleavage can strongly influence the evolution of grain sizes and shapes during comminution.

Description: Published

Description: 37-50

Description: 3T. Sorgente sismica

Description: 2IT. Laboratori analitici e sperimentali

Description: JCR Journal

Repository Name: Istituto Nazionale di Geofisica e Vulcanologia (INGV)

Type: article

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Grain Size Sensitive Creep During Simulated Seismic Slip in Nanogranular Fault Gouges: Constraints From Transmission Kikuchi Diffraction (TKD) (2020)

Demurtas, Matteo ; Smith, Steven A.F. ; Prior, David J. ; [et al.]

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Publication Date: 2020-02-18

Description: Nanograins (≪1 μm) are common in the principal slip zones of natural and experimental faults, but their formation and influence on fault mechanical behavior are poorly understood. We performed transmission Kikuchi diffraction (spatial resolution 20–50 nm) on the principal slip zone of an experimental carbonate gouge (50 wt% calcite, 50 wt% dolomite) that was deformed at a maximum slip rate of 1.2 m/s for 0.4 m displacement. The principal slip zone (PSZ) consists of nanogranular aggregates of calcite, Mg‐calcite, dolomite and periclase, dominated by grain sizes in the range of 100–300 nm. Nanograins in the ultrafine (〈 800 nm) PSZ matrix have negligible internal lattice distortion, while grains 〉 800 nm in size contain subgrains. A weak crystallographic preferred orientation is observed as a clustering of calcite c‐axes within the PSZ. The high‐resolution microstructural observations from transmission Kikuchi diffraction, in combination with published flow laws for calcite, are compatible with high‐velocity slip in the PSZ having been accommodated by a combination of grain size sensitive creep in the ultrafine matrix, and grain size insensitive creep in the larger grains, with the former process likely controlling the bulk rheology of the PSZ after dynamic weakening. If the activation energy for creep is lowered by the nanogranular nature of the aggregates, this could facilitate grain size sensitive creep at high (coseismic) strain rates and only moderate bulk temperatures of approximately 600 °C, although temperatures up to 1000 °C could be locally achieved due to processes such as flash heating.

Description: Published

Description: 10197-10209

Description: 3T. Sorgente sismica

Description: 2IT. Laboratori analitici e sperimentali

Description: JCR Journal

Repository Name: Istituto Nazionale di Geofisica e Vulcanologia (INGV)

Type: article

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Crystallographic preferred orientation (CPO) development governs strain weakening in ice: insights from high-temperature deformation experiments (2022)

Fan, Sheng ; Cross, Andrew J. ; Prior, David J. ; [et al.]

American Geophysical Union

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Publication Date: 2022-10-26

Description: © The Author(s), 2021. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Fan, S., Cross, A. J., Prior, D. J., Goldsby, D. L., Hager, T. F., Negrini, M., & Qi, C. Crystallographic preferred orientation (CPO) development governs strain weakening in ice: insights from high-temperature deformation experiments. Journal of Geophysical Research: Solid Earth, 126(12), (2021): e2021JB023173, https://doi.org/10.1029/2021JB023173.

Description: Strain weakening leads to the formation of high-strain shear zones and strongly influences terrestrial ice discharge. In glacial flow models, strain weakening is assumed to arise from the alignment of weak basal planes—the development of a crystallographic preferred orientation, CPO—during flow. However, in experiments, ice strain weakening also coincides with grain size reduction, which has been invoked as a weakening mechanism in other minerals. To interrogate the relative contributions of CPO development and grain size reduction toward ice strain weakening, we deformed initially isotropic polycrystalline ice samples to progressively higher strains between −4 and −30°C. Microstructural measurements were subsequently combined with flow laws to separately model the mechanical response expected to arise from CPO development and grain size reduction. Magnitudes of strain weakening predicted by the constitutive flow laws were then compared with the experimental measurements. Flow laws that only consider grain size do not predict weakening with strain despite grain size reduction. In contrast, flow laws solely considering CPO effects can reproduce the measured strain weakening. Thus, it is reasonable to assume that strain weakening in ice is dominated by CPO development, at least under high temperature (Th ≥ 0.9) and high stress (〉1 MPa), like those in our experiments. We speculate that at high homologous temperatures (Th ≥ 0.9), CPO development will also govern the strain weakening behavior of other viscously anisotropic minerals, like olivine and quartz. Overall, we emphasize that geodynamic and glaciological models should incorporate CPOs to account for strain weakening, especially at high homologous temperatures.

Description: This work was supported by a NASA fund (grant no. NNX15AM69G) to David L. Goldsby and two Marsden Funds of the Royal Society of New Zealand (grant nos. UOO1116, UOO052) to David J. Prior. Sheng Fan was supported by the University of Otago doctoral scholarship, the Antarctica New Zealand doctoral scholarship, a research grant from New Zealand Ministry of Business, Innovation and Employment through the Antarctic Science Platform (ANTA1801) (grant no. ASP-023-03), and a New Zealand Antarctic Research Institute (NZARI) Early Career Researcher Seed Grant (grant no. NZARI 2020-1-5).

Keywords: High-temperature deformation ; Ice ; Strain weakening ; Grain size ; Crystallographic preferred orientation (CPO) ; Electron backscatter diffraction (EBSD)

Repository Name: Woods Hole Open Access Server

Type: Article

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Using misorientation and weighted burgers vector statistics to understand intragranular boundary development and grain boundary formation at high temperatures (2023)

Fan, Sheng ; Wheeler, John ; Prior, David J. ; [et al.]

American Geophysical Union

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Publication Date: 2023-02-21

Description: Author Posting. © American Geophysical Union, 2022. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research: Solid Earth 127(8), (2022): e2022JB024497, https://doi.org/10.1029/2022JB024497.

Description: During plastic deformation, strain weakening can be achieved, in part, via strain energy reduction associated with intragranular boundary development and grain boundary formation. Grain boundaries (in 2D) are segments between triple junctions, that connect to encircle grains; every boundary segment in the encircling loop has a high (〉10°) misorientation angle. Intragranular boundaries terminate within grains or dissect grains, usually containing boundary segments with a low (〈10°) misorientation angle. We analyze electron backscatter diffraction (EBSD) data from ice deformed at −30°C (Th≈ 0.9). Misorientation and weighted Burgers vector (WBV) statistics are calculated along planar intragranular boundaries. Misorientation angles change markedly along each intragranular boundary, linking low- (〈10°) and high-angle (10–38°) segments that exhibit distinct misorientation axes and WBV directions. We suggest that these boundaries might be produced by the growth and intersection of individual intragranular boundary segments comprising dislocations with distinct slip systems. There is a fundamental difference between misorientation axis distributions of intragranular boundaries (misorientation axes mostly confined to ice basal plane) and grain boundaries (no preferred misorientation axis). These observations suggest during progressive subgrain rotation, intragranular boundaries remain crystallographically controlled up to large misorientation angles (〉〉10°). In contrast, the apparent lack of crystallographic control for grain boundaries suggests misorientation axes become randomized, likely due to the activation of additional mechanisms (such as grain boundary sliding) after grain boundary formation, linking boundary segments to encircle a grain. Our findings on ice intragranular boundary development and grain boundary formation may apply more broadly to other rock-forming minerals (e.g., olivine, quartz).

Description: This work was supported by a NASA fund (Grant No. NNX15AM69G) to David L. Goldsby and two Marsden Funds of the Royal Society of New Zealand (Grant Nos. UOO1116, UOO052) to David J. Prior. Sheng Fan was supported by the University of Otago doctoral scholarship, the Antarctica New Zealand doctoral scholarship, a research grant from New Zealand Ministry of Business, Innovation and Employment through the Antarctic Science Platform (ANTA1801) (Grant No. ASP-023-03), and a New Zealand Antarctic Research Institute (NZARI) Early Career Researcher Seed Grant (Grant No. NZARI 2020-1-5). Open access publishing facilitated by University of Otago, as part of the Wiley – University of Otago agreement via the Council of Australian University Librarians.

Keywords: High temperature deformation ; Misorientation ; Weighted Burgers vector ; Intragranular boundary ; Grain boundary ; Boundary geometry

Repository Name: Woods Hole Open Access Server

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