Jun-ichi Ando

Last Updated :2023/02/02

Affiliations, Positions
Graduate School of Advanced Science and Engineering, Professor
E-mail
jandohiroshima-u.ac.jp
Other Contact Details
1-3-1, HIGASHI-HIROSHIMA, HIROSHIMA, Japan
TEL : (+81)82-424-7484 FAX : (+81)82-424-0735
Self-introduction
To understand the phenomena of faulting and rock flow in the Earth's interior, I am focusing on the research to observ the deformational microstructures created in the rocks. For this research, I mainly use optical microscope, transmission electron microscope, and scanning electron microscope. Geological surveys are also carried out as needed.

Basic Information

Major Professional Backgrounds

  • 1993/04/01, 1995/03/31, The Japan Society for the Promotion of Science for Japanese Junior Scientists, Postdoc Researcher
  • 1995/04/10, 1997/03/31, State University of New York, Postdoc Researcher
  • 1996/08/01, 2000/03/31, Hiroshima University, Faculty of Science, Assistant Professor
  • 2000/04/01, 2011/03/31, Hiroshima University, Graduate School of Science, Assistant Professor
  • 2011/04/01, 2016/02/29, Hiroshima University, Graduate School of Science, Associate Professor
  • 2016/03/01, 2020/03/31, Hiroshima University, Graduate School of Science, Professor

Educational Backgrounds

  • TOHOKU UNIVERSITY, Graduate School, Division of Natural Science, Department of Earth Science, Japan, 1989/04, 1993/03
  • TOHOKU UNIVERSITY, Graduate School, Division of Natural Science, Department of Earth Science, Japan, 1987/04, 1989/03
  • KAGOSHIMA UNIVERSITY, Faculty of Science, Department of Geology, Japan, 1983/04, 1987/03

Academic Degrees

  • Doctor of Science, TOHOKU UNIVERSITY
  • Master of Science, TOHOKU UNIVERSITY

Educational Activity

  • [Bachelor Degree Program] School of Science : Earth and Planetary Systems Science : Earth and Planetary Systems Science
  • [Master's Program] Graduate School of Advanced Science and Engineering : Division of Advanced Science and Engineering : Earth and Planetary Systems Science Program
  • [Doctoral Program] Graduate School of Advanced Science and Engineering : Division of Advanced Science and Engineering : Earth and Planetary Systems Science Program

In Charge of Primary Major Programs

  • Earth and Planetary Systems Science

Research Fields

  • Mathematical and physical sciences;Earth and planetary science;Geology
  • Mathematical and physical sciences;Earth and planetary science;Petrology / Mineralogy / Economic geology

Research Keywords

  • mantle rheology
  • microstructure of fault
  • deformation microstructure
  • plasticity
  • peridotite

Affiliated Academic Societies

Educational Activity

Course in Charge

  1. 2022, Liberal Arts Education Program1, 1Term, Introductory Seminar for First-Year Students
  2. 2022, Undergraduate Education, 3Term, Geologic Mapping
  3. 2022, Undergraduate Education, First Semester, Special Study for Graduation
  4. 2022, Undergraduate Education, Second Semester, Special Study for Graduation
  5. 2022, Undergraduate Education, Year, Geochemistry and Geophysics Internship
  6. 2022, Undergraduate Education, 3Term, Advanced Earth and Planetary Science
  7. 2022, Undergraduate Education, 3Term, Rock rheology
  8. 2022, Undergraduate Education, 4Term, Practice for Material Sciences of Earth and Planets B
  9. 2022, Undergraduate Education, 4Term, Practice for Earth and Planetary Materials Science II
  10. 2022, Undergraduate Education, 2Term, Experiments in General Geology A
  11. 2022, Graduate Education (Doctoral Program) , First Semester, Seminar on earth and planetary material science II
  12. 2022, Graduate Education (Master's Program) , 3Term, Survey of Earth and Planetary Systems Science
  13. 2022, Graduate Education (Master's Program) , 2Term, Geodynamics
  14. 2022, Graduate Education (Master's Program) , 1Term, Analytical Techniques for Earth and Planetary Materials Science
  15. 2022, Graduate Education (Master's Program) , Year, Exercise for Globalization I
  16. 2022, Graduate Education (Master's Program) , Year, Exercise for Globalization II
  17. 2022, Graduate Education (Master's Program) , Year, Externship for Earth and Planetary Systems Science
  18. 2022, Graduate Education (Master's Program) , Second Semester, Integrated Seminar on Earth and Planetary Systems Science
  19. 2022, Graduate Education (Master's Program) , First Semester, Midterm Exercise for Earth and Planetary Systems Science
  20. 2022, Graduate Education (Master's Program) , 1Term, Special Exercise for Earth and Planetary Systems Science A
  21. 2022, Graduate Education (Master's Program) , 2Term, Special Exercise for Earth and Planetary Systems Science A
  22. 2022, Graduate Education (Master's Program) , 3Term, Special Exercise for Earth and Planetary Systems Science B
  23. 2022, Graduate Education (Master's Program) , 4Term, Special Exercise for Earth and Planetary Systems Science B
  24. 2022, Graduate Education (Master's Program) , Academic Year, Special Study for Earth and Planetary Systems Science
  25. 2022, Graduate Education (Doctoral Program) , Academic Year, Special Study for Earth and Planetary Systems Science

Research Activities

Academic Papers

  1. ★, Mechanism of the olivine-ringwoodite transformation in the presence of aqueous fluid, Physics and Chemistry of Minerals, 33, 377-382, 200609
  2. Origin of the seismic anisotropy in the D'' layer inferred from shear deformation of post-perovskite phase, Earth and Planetary Science Letters, 252, 372-378, 200612
  3. Seismic slip record in carbonate-bearing fault zones: An insight from high-velocity friction experiments on siderite gouge, Geology, 35, 1131-1134, 200712
  4. Ultralow friction of carbonate faults caused by thermal decomposition, Science, 316, 878-881, 200703
  5. In situ strength measurements on natural upper-mantle minerals, Physics and Chemistry of Minerals, 35, 249-257, 2008
  6. Mineral chemistry and P-T condition of granular and sheared peridotite xenoliths from Kimberley, South Africa: Origin of the textural variation in the cratonic mantle, Lithos, 109, 333-340, 200903
  7. Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge, Nature, 461, 1114-1117, 2009
  8. Shear deformation of polycrystalline wadsleyite up to 2100 K at 14-17 GPa using a rotational Drickamer apparatus (RDA), Journal of Geophysical Research, 115, B08208, 2010
  9. Rheological contrast between garnet and clinopyroxene in the mantle wedge: An example from Higashi-akaishi peridotite mass, SW Japan, Physics of the Earth and Planetary Interiors, 184, 14-33, 2011
  10. Granular nanoparticles lubricate faults during seismic slip, Geology, 39, 599-602, 2011
  11. Water content of the mantle xenoliths from Kimberley and implications for explaining textural variations in cratonic roots, Geological Journal, 45, 1-10, 2011
  12. Plastic deformation experiments to high strain on mantle transition zone minerals wadsleyite and ringwoodite in the rotational Drickamer apparatus, Earth and Planetary Science Letters, 361, 7-15, 201506
  13. On oriented ilmenite needles in garnet porphyroblasts from deep crustal granulites: Implications for fluid evolution and cooling history, Lithos, 156, 230-240, 2013
  14. Frictional melting of clayey gouge during seismic fault slip: Experimental observation and implications, Journal of Geophysical Research, 41, 5457-5466, 2014
  15. Equation of state and phase transition of antigorite under high pressure and high temperature, Physics of the Earth and Planetary Interiors, 228, 56-62, 2014
  16. Coseismic microstructures of experimental fault zones in Carrara marble, Journal of Structural Geology, 66, 75-83, 2014
  17. Frictional strength of ground dolerite gouge at a wide range of slip rates, JOURNAL OF GEOPHYSICAL RESEARCH-SOLID EARTH, 121(4), 2961-2979, 201604
  18. ★, Deformation history of Pinatubo peridotite xenoliths: constraints from microstructural observation and determination of olivine slip systems, PHYSICS AND CHEMISTRY OF MINERALS, 44(4), 247-262, 201704
  19. The occurrence of fluor-wagnerite in UHT granulites and its implications towards understanding fluid regimes in the evolution of deep crust: a case study from the Eastern Ghats Belt, India, MINERALOGY AND PETROLOGY, 111(3), 417-429, 201706
  20. Microstructural observations of fracture-filling goethite vein along the Kerajang Fault Zone in the Rengali Province of eastern India, JOURNAL OF MINERALOGICAL AND PETROLOGICAL SCIENCES, 112(2), 102-107, 201704
  21. Coalescing microstructure and fabric transitions with AMS data in deformed limestone: Implications on deformation kinematics, JOURNAL OF STRUCTURAL GEOLOGY, 114, 294-309, 201809
  22. Elemental behavior during the corrosion process of sekishu roof-tile glaze affected with Lecidea s.lat. sp. (crustose lichen), Clay Minerals, 41, 819-826, 2006
  23. The phase boundary between wadsleyite and ringwoodite in Mg2SiO4 determined by in situ X-ray diffraction, Physics and Chemistry of Minerals, 33, 106-114, 2006
  24. Precise determination of phase relations in pyrolite across the 660 km seismic discontinuity in-situ X-ray diffraction and quench experiments, Physics of the Earth and Planetary Interiors, 143, 185-199, 2004
  25. ★, Striped iron zoning of olivine induced by dislocation creep in deformed peridotites, Nature, 414, 893-895, 2001
  26. High-pressure phase transformation in CaMgSi2O6 and implications for origin of ultra-deep diamond inclusions, Geophysical Research Letters, 27, 3541-3544, 2000
  27. Plastic deformation of silicate garnet II. High pressure experiments, Physics of the Earth and Planetary Interiors, 108, 305-318, 1998
  28. Rheology measurements at high pressure and temperature. In Properties of earth and planetary materials at high pressure and temperature, Geophysical Monograph Series, 101, 473-482, 1998
  29. Progress in the studies of texture development in quartzite : recent topics, The Memoirs of the Geological Society of Japan, 50, 21-32, 1998
  30. ★, Evaluation of the non-hydrostatic stress produced in a multianvil high-pressure apparatus, Physics and Chemistry of Minerals, 24, 139-148, 1997
  31. An experimental study of the garnet-perovskite transformation in the system MgSiO3-Mg3Al2Si3O12, Physics of the Earth and Planetary Interiors, 96, 147-157, 1996
  32. A new estimate of transition condition from basal to prism [c] slip systems in naturally deformed quartz, Tectonophysics, 250, 31-46, 1995
  33. ★, Dislocation microstructures in naturally deformed silicate garnets, Physics of the Earth and Planetary Interiors, 80, 105-116, 1993
  34. The architecture of long-lived fault zones: insights from microstructure and quartz lattice-preferred orientations in mylonites of the Median Tectonic Line, SW Japan, PROGRESS IN EARTH AND PLANETARY SCIENCE, 6, 20190305
  35. Serpentinite enigma of the Rakhabdev lineament in western India: Origin, deformation characterization and tectonic implications, JOURNAL OF MINERALOGICAL AND PETROLOGICAL SCIENCES, 115(2), 216-226, 202004
  36. Dehydrogenation of deep-seated hydrous olivine in "black-colored" dunites of arc origin, LITHOS, 384, 202103
  37. Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge., Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge., 461(7267), 2009
  38. Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge., Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge., 461(7267), 2009
  39. Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge., Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge., 461(7267), 2009
  40. Carbonate clumped isotope thermometry of fault rocks and its possibilities: tectonic implications from calcites within Himalayan Frontal Fold-Thrust Belt, PROGRESS IN EARTH AND PLANETARY SCIENCE, 8(1), 20210707