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This volume highlights some of the frontiers in the study of plastic deformation of minerals and rocks. The research into the plastic properties of minerals and rocks had a major peak in late 1960s to early 1970s, largely stimulated by research in the laboratory of D.T. Griggs and his students and associates. It is the same time when the theory of plate tectonics was established and provided a first quantitative theoretical framework for understanding geological processes. The theory of plate tectonics stimulated the study of deformation properties of Earth materials, both in the brittle and the ductile regimes. Many of the foundations of plastic deformation of minerals and rocks were established during this period. Also, new experimental techniques were developed, including deformation apparatus for high-pressure and high-temperature conditions, electron micros-copy study of defects in minerals, and the X-ray technique of deformation fabric analysis. The field benefited greatly from materials science concepts of deformation that were introduced, including the models of point defects and their interaction with dislocations. A summary of progress is given by the volume "Flow and Fracture of Rocks: The Griggs Volume," published in 1972 by the American Geophysical Union.
Since then, the scope of Earth sciences has greatly expanded. Geodynamics became concerned with the Earth’s deep interior where seismologists discovered heterogeneities and anisotropy at all scales that were previously thought to be typical of
Yale University New Haven, Connecticut
University of California Berkeley, California
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