Microscale and nanoscale strain mapping techniques applied to creep of rocks
Usually several deformation mechanisms interact to accommodate plastic deformation. Quantifying the contribution of each to the total strain is necessary to bridge the gaps from observations of microstructures, to geomechanical descriptions, to extrapolating from laboratory data to field observa...
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Copernicus Publications
2017-07-01
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| Series: | Solid Earth |
| Online Access: | https://www.solid-earth.net/8/751/2017/se-8-751-2017.pdf |
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doaj-73577406b5e845049de1069da67e16eb2020-11-25T02:04:44ZengCopernicus PublicationsSolid Earth1869-95101869-95292017-07-01875176510.5194/se-8-751-2017Microscale and nanoscale strain mapping techniques applied to creep of rocksA. Quintanilla-Terminel0M. E. Zimmerman1B. Evans2D. L. Kohlstedt3Department of Earth Sciences, University of Minnesota, Minneapolis, MN 55455, USADepartment of Earth Sciences, University of Minnesota, Minneapolis, MN 55455, USAEarth, Atmospheric and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, MA 02139, USADepartment of Earth Sciences, University of Minnesota, Minneapolis, MN 55455, USAUsually several deformation mechanisms interact to accommodate plastic deformation. Quantifying the contribution of each to the total strain is necessary to bridge the gaps from observations of microstructures, to geomechanical descriptions, to extrapolating from laboratory data to field observations. Here, we describe the experimental and computational techniques involved in microscale strain mapping (MSSM), which allows strain produced during high-pressure, high-temperature deformation experiments to be tracked with high resolution. MSSM relies on the analysis of the relative displacement of initially regularly spaced markers after deformation. We present two lithography techniques used to pattern rock substrates at different scales: photolithography and electron-beam lithography. Further, we discuss the challenges of applying the MSSM technique to samples used in high-temperature and high-pressure experiments. We applied the MSSM technique to a study of strain partitioning during creep of Carrara marble and grain boundary sliding in San Carlos olivine, synthetic forsterite, and Solnhofen limestone at a confining pressure, <i>P</i><sub>c</sub>, of 300 MPa and homologous temperatures, <i>T</i>∕<i>T</i><sub><i>m</i></sub>, of 0.3 to 0.6. The MSSM technique works very well up to temperatures of 700 °C. The experimental developments described here show promising results for higher-temperature applications.https://www.solid-earth.net/8/751/2017/se-8-751-2017.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
A. Quintanilla-Terminel M. E. Zimmerman B. Evans D. L. Kohlstedt |
| spellingShingle |
A. Quintanilla-Terminel M. E. Zimmerman B. Evans D. L. Kohlstedt Microscale and nanoscale strain mapping techniques applied to creep of rocks Solid Earth |
| author_facet |
A. Quintanilla-Terminel M. E. Zimmerman B. Evans D. L. Kohlstedt |
| author_sort |
A. Quintanilla-Terminel |
| title |
Microscale and nanoscale strain mapping techniques applied to creep of rocks |
| title_short |
Microscale and nanoscale strain mapping techniques applied to creep of rocks |
| title_full |
Microscale and nanoscale strain mapping techniques applied to creep of rocks |
| title_fullStr |
Microscale and nanoscale strain mapping techniques applied to creep of rocks |
| title_full_unstemmed |
Microscale and nanoscale strain mapping techniques applied to creep of rocks |
| title_sort |
microscale and nanoscale strain mapping techniques applied to creep of rocks |
| publisher |
Copernicus Publications |
| series |
Solid Earth |
| issn |
1869-9510 1869-9529 |
| publishDate |
2017-07-01 |
| description |
Usually several deformation mechanisms interact to accommodate
plastic deformation. Quantifying the contribution of each to the total
strain is necessary to bridge the gaps from observations of microstructures, to
geomechanical descriptions, to extrapolating from laboratory
data to field observations. Here, we describe the experimental and computational
techniques involved in microscale strain mapping (MSSM), which allows
strain produced during high-pressure, high-temperature deformation
experiments to be tracked with high resolution. MSSM relies on the analysis
of the relative displacement of initially regularly spaced markers after
deformation. We present two lithography techniques used to pattern rock
substrates at different scales: photolithography and electron-beam
lithography. Further, we discuss the challenges of applying the MSSM
technique to samples used in high-temperature and high-pressure experiments. We
applied the MSSM technique to a study of strain partitioning during creep of
Carrara marble and grain boundary sliding in San Carlos olivine, synthetic
forsterite, and Solnhofen limestone at a confining pressure, <i>P</i><sub>c</sub>, of 300 MPa
and homologous temperatures, <i>T</i>∕<i>T</i><sub><i>m</i></sub>, of 0.3 to 0.6. The MSSM technique works very
well up to temperatures of 700 °C. The experimental developments
described here show promising results for higher-temperature applications. |
| url |
https://www.solid-earth.net/8/751/2017/se-8-751-2017.pdf |
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AT aquintanillaterminel microscaleandnanoscalestrainmappingtechniquesappliedtocreepofrocks AT mezimmerman microscaleandnanoscalestrainmappingtechniquesappliedtocreepofrocks AT bevans microscaleandnanoscalestrainmappingtechniquesappliedtocreepofrocks AT dlkohlstedt microscaleandnanoscalestrainmappingtechniquesappliedtocreepofrocks |
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