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@E‚·‚ׂÄF52
@E‘æˆê’˜ŽÒ˜_•¶”F15
@EORCID ID: 0000-0003-3571-6722
@
yˆø—pó‹µz(2019”N4ŒŽ25“ú)
@Publons / Google Scholar Citations
@E”íˆø—p”‚̇Œv: 453 / 588
@Eh-index: 13 / 14
@EResearcherID: D-4896-2017

yis’†z   
[54] I. Ohira et al., “Še’†.
[53] L. Wang et al., “Še’†.

y2020z
[52] D. Simonova, E. Bykova, M. Bykov, T. Kawazoe, A. Simonov, N. Dubrovinskaia, and L. Dubrovinsky, Structural study of ƒÂ-AlOOH up to 29 GPa, Minerals, Žó—.
[51] ²–숟¹”ü, ˆÉ“¡³ˆê, —鑺–¾­, ã–ì—Yˆê˜Y, ”ª–ØW, ˆäã“O, ì“Y‹MÍ (2020), “¯ˆÊ‘Ì•ª”zŒW”‚ւ̈³—͂̉e‹¿, ‚ˆ³—͂̉Ȋw‚Æ‹Zp, 30 (2), 85-94, DOI: 10.4131/jshpreview.30.85.

y2019z
[50] L. Zhang, J.R. Smyth, T. Kawazoe, S.D. Jacobsen, J. Niu, X. He, and S. Qin (2019), Stability, composition, and crystal structure of Fe-bearing phase E in the transition zone, American Mineralogist, 104 (11), 1620-1624, DOI: 10.2138/am-2019-6750.
[49] N. Satta, H. Marquardt, A. Kurnosov, J. Buchen, T. Kawazoe, C. McCammon, and T. Boffa Ballaran (2019), Single crystal elasticity of iron-bearing phase E and seismic detection of water in Earth's upper mantle, American Mineralogist, 104 (10), 1526-1529, DOI: 10.2138/am-2019-7084.
[48] T. Ishii, R. Huang, R. Myhill, H. Fei, I. Koemets, Z. Liu, F. Maeda, L. Yuan, L. Wang, D. Druzhbin, T. Yamamoto, S. Bhat, R. Farla, T. Kawazoe, N. Tsujino, E. Kulik, Y. Higo, Y. Tange, and T. Katsura (2019), Sharp 660-km discontinuity controlled by extremely narrow binary post-spinel transition, Nature Geoscience, 12 (10), 869-872, DOI: 10.1038/s41561-019-0452-1.
[47] I. Ohira, J.M. Jackson, N.V. Solomatova, W. Sturhahn, G.J. Finkelstein, S. Kamada, T. Kawazoe, F. Maeda, N. Hirao, S. Nakano, T.S. Toellner, A. Suzuki, and E. Ohtani (2019), Compressional behavior and spin state of ƒÂ-(Al,Fe)OOH at high pressures, American Mineralogist, 104 (9), 1273-1284, DOI: 10.2138/am-2019-6913.
[46] A. Nakajima, T. Sakamaki, T. Kawazoe, and A. Suzuki (2019), Hydrous magnesium-rich magma genesis at the top of the lower mantle, Scientific Reports, 9, 7420, DOI: 10.1038/s41598-019-43949-2.
[45] T. Komabayashi, G. Pesce, R. Sinmyo, T. Kawazoe, H. Breton, Y. Shimoyama, K. Glazyrin, Z. Konopkova, and M. Mezouar (2019), Phase relations in the system Fe-Ni-Si to 200 GPa and 3900 K and implications for Earth's core, Earth and Planetary Science Letters, 512, 83-88, DOI: 10.1016/j.epsl.2019.01.056.
[44] L. Wang, N. Miyajima, T. Kawazoe, and T. Katsura (2019), Activation of [100](001) slip system by water incorporation in olivine and the cause of seismic anisotropy decrease with depth in the asthenosphere, American Mineralogist, 104, 47-52, DOI: 10.2138/am-2019-6574.

y2018”Nz
[43] J. Buchen, H. Marquardt, S. Speziale, T. Kawazoe, T. Boffa Ballaran, and A. Kurnosov (2018), High-pressure single-crystal elasticity of wadsleyite and the seismic signature of water in the shallow transition zone, Earth and Planetary Science Letters, 498, 77-87, DOI: 10.1016/j.epsl.2018.06.027.
[42] K. Schulze, H. Marquardt, T. Kawazoe, T. Boffa Ballaran, C. McCammon, M. Koch-Mueller, A. Kurnosov, and K. Marquardt (2018), Seismically invisible water in the Earth's transition zone?, Earth and Planetary Science Letters, 498, 9-16, DOI: 10.1016/j.epsl.2018.06.021.
[41] Correction to: L. Zhang, J.R. Smyth, T. Kawazoe, S.D. Jacobsen, and S. Qin (2018), Transition metals in the transition zone: partitioning of Ni, Co, and Zn between olivine, wadsleyite, ringwoodite, and clinoenstatite, Contributions to Mineralogy and Petrology, 173, 60.
[40] L. Zhang, J.R. Smyth, T. Kawazoe, S.D. Jacobsen, and S. Qin (2018), Transition metals in the transition zone: partitioning of Ni, Co, and Zn between olivine, wadsleyite, ringwoodite, and clinoenstatite, Contributions to Mineralogy and Petrology, 173, 52, DOI: 10.1007/s00410-018-1478-x.
[39] B.C. Nzogang, S. Thilliez, A. Mussi, T. Kawazoe, N. Miyajima, J. Bouquerel, and P. Cordier (2018), Application of Scanning Precession Electron Diffraction in the Transmission Electron Microscope to the characterization of deformation in wadsleyite and ringwoodite, Minerals, 8(4), 153, DOI: 10.3390/min8040153.
[38] T. Ishii, R. Huang, H. Fei, I. Koemets, Z. Liu, F. Maeda, L. Yuan, L. Wang, D. Druzhbin, T. Yamamoto, S. Bhat, R. Farla, T. Kawazoe, N. Tsujino, E. Kulik, Y. Higo, Y. Tange, and T. Katsura (2018), Complete agreement of the post-spinel transition with the 660-km seismic discontinuity, Scientific Reports, 8, 6358, DOI: 10.1038/s41598-018-24832-y.
[37] Y. Nishihara, T. Ohuchi, T. Kawazoe, Y. Seto, G. Maruyama, Y. Higo, K. Funakoshi, Y. Tange, and T. Irifune (2018), Deformation-induced crystallographic-preferred orientation of hcp-iron: An experimental study using a deformation-DIA apparatus, Earth and Planetary Science Letters, 490, 151-160, DOI: 10.1016/j.epsl.2018.03.029.

y2017”Nz
[36] J. Buchen, H. Marquardt, T. Boffa Ballaran, T. Kawazoe, and C. McCammon (2017), The equation of state of wadsleyite solid solutions: Constraining the effects of anisotropy and crystal chemistry, American Mineralogist, 102, 2494-2504, DOI: 10.2138/am-2017-6162.
[35] T. Ishii, D. Yamazaki, N. Tsujino, X. Fang, Z. Liu, T. Kawazoe, T. Yamamoto, D. Druzhbin, L. Wang, Y. Higo, Y. Tange, T. Yoshino, and T. Katsura (2017), Pressure generation to 65 GPa in Kawai]type multi]anvil apparatus with tungsten carbide anvils, High Pressure Research, 37, 507-515, DOI: 10.1080/08957959.2017.1375491.
[34] R. Farla, A. Rosenthal, C. Bollinger, S. Petitgirard, J. Guignard, N. Miyajima, T. Kawazoe, W. Crichton, and D. Frost (2017), High-pressure, high-temperature deformation of dunite, eclogite, clinopyroxenite and garnetite using in situ X-ray diffraction, Earth and Planetary Science Letters, 473, 291-302, DOI: 10.1016/j.epsl.2017.06.019.
[33] T. Kawazoe, I. Ohira, T. Ishii, T. Boffa Ballaran, C. McCammon, A. Suzuki, and E. Ohtani (2017), Single crystal synthesis of ƒÂ-(Al,Fe)OOH, American Mineralogist, 102, 1953-1956, DOI: 10.2138/am-2017-6153.
[32] T. Ishii, R. Sinmyo, T. Komabayashi, T. Boffa Ballaran, T. Kawazoe, N. Miyajima, K. Hirose, and T. Katsura (2017), Synthesis and crystal structure of LiNbO3-type Mg3Al2Si3O12: A possible indicator of shock conditions of meteorites, American Mineralogist, 102, 1947-1952, DOI: 10.2138/am-2017-6027.
[31] T. Ohuchi, T. Kawazoe, Y. Higo, and A. Suzuki (2017), Flow behavior and microstructures of hydrous olivine aggregates at upper mantle pressures and temperatures, Contributions to Mineralogy and Petrology, 172, 65, DOI: 10.1007/s00410-017-1375-8.
[30] L. Wang, S. Blaha, T. Kawazoe, N. Miyajima, and T. Katsura (2017), Identical activation volumes of dislocation mobility in the [100](010) and [001](010) slip systems in natural olivine, Geophysical Research Letters, 44, 2687-2692, DOI: 10.1002/2017GL073070.

y2016”Nz
[29] T. Kawazoe, Y. Nishihara, T. Ohuchi, N. Miyajima, G. Maruyama, Y. Higo, K. Funakoshi, and T. Irifune (2016), Creep strength of ringwoodite measured at pressure-temperature conditions of the lower part of the mantle transition zone using a deformation-DIA apparatus, Earth and Planetary Science Letters, 454, 10-19, DOI: 10.1016/j.epsl.2016.08.011.
[28] L. Zhang, J.R. Smyth, J. Allaz, T. Kawazoe, S.D. Jacobsen, and Z. Jin (2016), Transition metals in the transition zone: crystal chemistry of minor element substitution in wadsleyite, American Mineralogist, 101, 2322-2330, DOI: 10.2138/am-2016-5681.
[27] L. Wang, S. Blaha, Z. Pinter, R. Farla, T. Kawazoe, N. Miyajima, K. Michibayashi, and T. Katsura (2016), Temperature dependence of [100](010) and [001](010) dislocation mobility in natural olivine, Earth and Planetary Science Letters, 441, 81-90, DOI: 10.1016/j.epsl.2016.02.029.
[26] T. Kawazoe, A. Chaudhari, J.R. Smyth, and C. McCammon (2016), Coupled substitution of Fe3+ and H+ for Si in wadsleyite: a study by polarized infrared and Moessbauer spectroscopies and single-crystal X-ray diffraction, American Mineralogist (Letter), 101 (5), 1236-1239, DOI: 10.2138/am-2016-5625.
[25] T. Ishii, L. Shi, R. Huang, N. Tsujino, D. Druzhbin, R. Myhill, Y. Li, L. Wang, T. Yamamoto, N. Miyajima, T. Kawazoe, N. Nishiyama, Y. Higo, Y. Tange, and T. Katsura (2016), Generation of pressures over 40 GPa using Kawai-type multi-anvil press with tungsten carbide anvils, Review of Scientific Instruments, 87 (2), 024501, DOI: 10.1063/1.4941716.

y2015”Nz
[24] N. Miyajima, and T. Kawazoe (2015), Dislocation microstructures in simple-shear-deformed wadsleyite at transition-zone conditions: Weak-beam dark-field TEM characterization of dislocations on the (010) plane, American Mineralogist (Letter), 100 (11-12), 2749-2752, DOI: 10.2138/am-2015-5481.
[23] T. Ohuchi, T. Kawazoe, Y. Higo, K. Funakoshi, A. Suzuki, T. Kikegawa, and T. Irifune (2015), Dislocation-accommodated grain boundary sliding as the major deformation mechanism of olivine in the Earth's upper mantle, Science Advances, 1 (9), e1500360, DOI: 10.1126/sciadv.1500360.
[22] T. Kawazoe, J. Buchen, and H. Marquardt (2015), Synthesis of large wadsleyite single crystals by solid-state recrystallization, American Mineralogist (Letter), 100 (10), 2336-2339, DOI: 10.2138/am-2015-5400.
[21] T. Ohuchi, Y. Nishihara, Y. Seto, T. Kawazoe, M. Nishi, G. Maruyama, M. Hashimoto, Y. Higo, K. Funakoshi, A. Suzuki, T. Kikegawa, and T. Irifune (2015), In situ observation of crystallographic preferred orientation of deforming olivine at high pressure and high temperature, Physics of the Earth and Planetary Interiors, 243, 1-21, DOI: 10.1016/j.pepi.2015.04.004.

y2013-2014”Nz
[20] ì“Y‹MÍ (2014), ƒ}ƒ“ƒgƒ‹[•”ƒŒƒIƒƒW[Œ¤‹†‚ÌÅ‹ß‚Ìi•à, ‚ˆ³—͂̉Ȋw‚Æ‹Zp, 24 (2), 88-99, DOI: 10.4131/jshpreview.24.88.
[19] T. Ohuchi, K. Fujino, T. Kawazoe, and T. Irifune (2014), Crystallographic preferred orientation of wadsleyite and ringwoodite: effects of phase transformation and water on seismic anisotropy in the mantle transition zone, Earth and Planetary Science Letters, 397, 133-144, DOI: 10.1016/j.epsl.2014.03.066.
[18] Y. Nishihara, T. Ohuchi, T. Kawazoe, D. Spengler, M. Tasaka, T. Kikegawa, A. Suzuki, and E. Ohtani (2014), Rheology of fine-grained forsterite aggregate at deep upper mantle conditions, Journal of Geophysical Research, 119 (1), 253-273, DOI: 10.1002/2013JB010473.
[17] T. Kawazoe, T. Ohuchi, Y. Nishihara, N. Nishiyama, K. Fujino, and T. Irifune (2013), Seismic anisotropy in the mantle transition zone induced by shear deformation of wadsleyite, Physics of the Earth and Planetary Interiors, 216, 91-98, DOI: 10.1016/j.pepi.2012.12.005.

y2011-2012”Nz
[16] T. Kawazoe, and I. Yamada (2012), High-pressure synthesis at 10 GPa and 1400 K using a small cubic anvil apparatus with a multi-anvil 6-6 system, High Pressure Research, 32 (3), 347-353, DOI: 10.1080/08957959.2012.697900.
[15] T. Ohuchi, Y. Nishihara, T. Kawazoe, D. Spengler, R. Shiraishi, A. Suzuki, T. Kikegawa, and E. Ohtani (2012), Superplasticity in hydrous melt-bearing dunite: Implications for shear localization in Earth's upper mantle, Earth and Planetary Science Letters, 335-336, 59-71, DOI:10.1016/j.epsl.2012.04.032.
[14] T. Kawazoe (2012), A miniature cubic anvil apparatus for optical measurement under high pressure, Review of Scientific Instruments, 83 (3), 035111, DOI: 10.1063/1.3698206.
[13] T. Ohuchi, T. Kawazoe, Y. Nishihara, and T. Irifune (2012), Change of olivine a-axis alignment induced by water: origin of seismic anisotropy in subduction zones, Earth and Planetary Science Letters, 317-318, 111-119, DOI: 10.1016/j.epsl.2011.11.022.
[12] T. Kawazoe, Y. Nishihara, T. Ohuchi, N. Nishiyama, Y. Higo, K. Funakoshi, and T. Irifune (2011), In situ stress-strain measurements in a deformation-DIA apparatus at P-T conditions of the upper part of the mantle transition zone, American Mineralogist, 96 (11-12), 1665-1672, DOI: 10.2138/am.2011.3818.
[11] T. Ohuchi, T. Kawazoe, Y. Nishihara, N. Nishiyama, and T. Irifune (2011), High pressure and temperature fabric transitions in olivine and variations in upper mantle seismic anisotropy, Earth and Planetary Science Letters, 304 (1-2), 55-63, DOI: 10.1016/j.epsl.2011.01.015.

y2010”Nz
[10] T. Kawazoe, N. Nishiyama, Y. Nishihara, and T. Irifune (2010), Deformation experiment at P-T conditions of the mantle transition zone using D-DIA apparatus, Physics of the Earth and Planetary Interiors, 183 (1-2), 190-195, DOI: 10.1016/j.pepi.2010.07.004.
[9] Y. Nishihara, K. Funakoshi, Y. Higo, N. Tsujino, T. Kawazoe, T. Kubo, A. Shimojuku, H. Terasaki, and N. Nishiyama (2010), Stress relaxation experiments of olivine under conditions of subducted slab in Earthfs deep upper mantle, Physics of the Earth and Planetary Interiors, 183 (1-2), 164-174, DOI: 10.1016/j.pepi.2010.07.006.
[8] T. Kawazoe, T. Ohuchi, N. Nishiyama, Y. Nishihara and T. Irifune (2010), Preliminary deformation experiment of ringwoodite at 20 GPa and 1700 K using a D-DIA apparatus, Journal of Earth Science, 21 (5), 517-522, DOI 10.1007/s12583-010-0120-2.
[7] T. Ohuchi, T. Kawazoe, N. Nishiyama, Y. Nishihara, and T. Irifune (2010), Technical development of simple shear deformation experiments using a deformation-DIA apparatus, Journal of Earth Science, 21 (5), 523-531, DOI 10.1007/s12583-010-0110-4.
[6] T. Kawazoe, S. Karato, J. Ando, Z. Jing, K. Otsuka, and J. Hustoft (2010), Shear deformation of polycrystalline wadsleyite up to 2100 K at 14-17 GPa using a rotational Drickamer apparatus (RDA), Journal of Geophysical Research, 115 (B8), B08208, DOI: 10.1029/2009JB007096.
[5] T. Kawazoe, N. Nishiyama, Y. Nishihara, and T. Irifune (2010), Pressure generation to 25 GPa using a cubic anvil apparatus with a multi-anvil 6-6 assembly, High Pressure Research, 30 (1), 167-174, DOI: 10.1080/08957950903503912.

y2004-2009”Nz
[4] T. Kawazoe, S. Karato, K. Otsuka, Z. Jing, and M. Mookherjee (2009), Shear deformation of dry polycrystalline olivine under deep mantle conditions using a rotational Drickamer apparatus (RDA), Physics of the Earth and Planetary Interiors, 174 (1-4), 128-137, DOI: 10.1016/j.pepi.2008.06.027.
[3] Y. Nishihara, D. Tinker, T. Kawazoe, Y. Xu, Z. Jing, K. Matsukage, and S. Karato (2008), Plastic deformation of wadsleyite and olivine at high-pressure and high-temperature using a rotational Drickamer apparatus (RDA), Physics of the Earth and Planetary Interiors, 170 (3-4), 156-169, DOI: 10.1016/j.pepi.2008.03.003.
[2] T. Kawazoe, and E. Ohtani (2006), Reaction between liquid iron and (Mg,Fe)SiO3-perovskite and solubilities of Si and O in molten iron at 27 GPa, Physics and Chemistry of Minerals, 33 (3), 227-234, DOI: 10.1007/s00269-006-0071-4.
[1] K. Litasov, E. Ohtani, A. Suzuki, T. Kawazoe, and K. Funakoshi (2004), Absence of density crossover between basalt and peridotite in the cold slab passing through 660 km discontinuity, Geophysical Research Letters, 31 (24), L24607, DOI: 10.1029/2004GL021306.


‚QDµ‘Òu‰‰


y2016-2018”Nz
[16] J. Buchen, H. Marquardt, K. Schulze, A. Kurnosov, T. Boffa Ballaran, S. Speziale, and T. Kawazoe, Tracing water in the transition zone: from wadsleyite single-crystal elasticity to seismic observables, European Geosciences Union General Assembly 2018, ƒI[ƒXƒgƒŠƒAEƒrƒGƒiŽs, 2018”N4ŒŽ8-13“ú.
[15] I. Ohira, J.M. Jackson, W. Sturhahn, G.J. Finkelstein, S. Kamada, T. Kawazoe, F. Maeda, N. Hirao, S. Nakano, A. Suzuki, and E. Ohtani, Sound velocity and elasticity of ƒÂ-(Al, Fe)OOH to lower mantle pressures, 55th European High Pressure Research Group (EHPRG) meeting, ƒ|[ƒ‰ƒ“ƒhEPoznan, 2017”N9ŒŽ3-8“ú.
[14] H. Marquardt, K. Schulze, A. Kurnosov, T. Boffa Ballaran, T. Kawazoe, and M. Koch-Mueller, Is water seismically invisible in Earthfs transition zone?, 27th Goldschmidt conference 2017, ƒtƒ‰ƒ“ƒXEƒpƒŠ, 2017”N8ŒŽ13-18“ú.
[13] H. Marquardt, K. Schulze, A. Kurnosov, J. Buchen, D. Frost, T. Boffa Ballaran, K. Marquardt, and T. Kawazoe, Understanding the Earth's mantle through advanced elasticity measurements, European Geosciences Union General Assembly 2017, ƒI[ƒXƒgƒŠƒAEƒrƒGƒiŽs, 2017”N4ŒŽ23-28“ú.
[12] T. Kawazoe, Advantages of large multi-anvil presses in BGI and GRC, CETUS Working Group: Rise of the HERATICs working group meeing, ƒAƒƒŠƒJ‡O‘ƒqƒ…[ƒXƒgƒ“Žs Lunar and Planetary Institute, 2017”N1ŒŽ23-24“ú.
[11] H. Marquardt, A. Kurnosov, T. Boffa Ballaran, D. Frost, T. Kawazoe, J. Buchen, and K. Schulze, Constraints on Earth's deep volatile cycles from elasticity measurements on mantle minerals, International WorkshopFNew Challenges in Volatile Cycling in the Deep Earth, ‹{錧å‘äŽs“Œ–k‘åŠw—tŽRƒLƒƒƒ“ƒpƒX, 2016”N7ŒŽ3-6“ú.

y2010-2015”Nz
[10] T. Ohuchi, Y. Nishihara, Y. Seto, T. Kawazoe, M. Nishi, G. Maruyama, M. Hashimoto, Y. Higo, K. Funakoshi, A. Suzuki, T. Kikegawa, and T. Irifune, In situ observation of crystallographic preferred orientation of deforming olivine at high pressure and high temperature, American Geophysical Union Fall Meeting 2015, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2015”N12ŒŽ14-18“ú.
[9] ‘å“à’q”Ž, ì“Y‹MÍ, ”ìŒã—SŽi, M‰zŒ«ˆê, —é–غ•v, ‹TŒTì‘ì”ü, “üät“O’j, ƒJƒ“ƒ‰ƒ“΂̓]ˆÊˆÚ“®—¥‘¬Œ^—±ŠE‚·‚ׂèFã•”ƒ}ƒ“ƒgƒ‹‚Ì—¬“®‚ðŽx”z‚·‚é•ÏŒ`ƒƒJƒjƒYƒ€, “ú–{’nŽ¿Šw‰ï‘æ122”NŠwp‘å‰ï, ’·–쌧’·–ìŽsMB‘åŠw’·–ìƒLƒƒƒ“ƒpƒX, 2015”N9ŒŽ11-13“ú.
[8] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ŠÛŽRŒº‘¾, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, In situ creep strength measurement on ringwoodite up to 1700 K at 17-18 GPa using a deformation-DIA apparatus, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2015”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2015”N5ŒŽ24-28“ú.
[7] R. Farla, A. Rosenthal, S. Petitgirard, C. Bollinger, T. Kawazoe, and D. Frost, In situ deformation of eclogite at high pressure and temperature, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2015”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2015”N5ŒŽ24-28“ú.
[6] T. Kawazoe, Y. Nishihara, T. Ohuchi, M. Nishi, N. Nishiyama, Y. Higo, K. Funakoshi, and T. Irifune, In situ stress-strain measurements in a deformation-DIA apparatus at P-T conditions of the upper part of the mantle transition zone, American Geophysical Union Fall Meeting 2011, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2011”N12ŒŽ6“ú.
[5] ì“Y‹MÍ, ¼ŽRé³, ¼Œ´—V, ‘å“à’q”Ž, “üät“O’j, DIAŒ^•ÏŒ`‘•’u‚ð—p‚¢‚½ƒ}ƒ“ƒgƒ‹‘JˆÚ‘w‰·“xˆ³—ÍðŒ‰º‚ł̃EƒHƒYƒŠƒAƒCƒgEƒŠƒ“ƒOƒEƒbƒ_ƒCƒg‚Ì•ÏŒ`ŽÀŒ±, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2010”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2010”N5ŒŽ23-28“ú.

y2003-2008”Nz
[4] “‚ŒËrˆê˜Y, ì“Y‹MÍ, ‚‰·E‚ˆ³‰º‚Å‚Ìz•¨‚Ì‘Y«—¬“®‚ÌŽÀŒ±“IŒ¤‹†,“ú–{’n‹…˜f¯‰ÈŠw˜A‡2008”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2008”N5ŒŽ.
[3] T. Kawazoe, K. Otsuka, D. Tinker, S. Karato, Y. Nishihara, Z. Jing, and M. Mookherjee, Deformation of dry olivine up to 11 GPa and 2100 K using a rotational Drickamer apparatus, American Geophysical Union Fall Meeting 2007, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2007”N12ŒŽ10-14“ú.
[2] E. Ohtani, T. Sakai, T. Kawazoe, and T. Kondo, Metal-silicate fractionation in the deep magma ocean and light elements in the core, 16th Annual V.M. Goldschmidt Conference 2006, ƒI[ƒXƒgƒ‰ƒŠƒA˜A–Mƒƒ‹ƒ{ƒ‹ƒ“Žs, 2006”N8ŒŽ28“ú-9ŒŽ1“ú.
[1] E. Ohtani, T. Kawazoe, Y. Kanbe, and K. Heshiki, Reaction and separation of metal and silicate in the early Earth, and light elements in the core, 13th Annual V.M. Goldschmidt Conference 2003, ‰ªŽRŒ§‘q•~Žs‚­‚炵‚«ì—z‘åŠw, 2003”N9ŒŽ7-12“ú.


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[4] –¼Ì ‰ÈŠwŒ¤‹†”ï•â•‹à
  Œ¤‹†Ží–Ú Šî”ÕŒ¤‹†iBj
  ‰Û‘è–¼ ’´‚ˆ³‚‰·•ÏŒ`ŽÀŒ±‚É‚æ‚éƒ}ƒ“ƒgƒ‹‘JˆÚ‘wz•¨‚Ì”S«—¦‘ª’è
  ‰Û‘è”Ô† 18H01315 [‰ÈŠwŒ¤‹†”Ž–‹Æƒf[ƒ^ƒx[ƒX]
  •¬ŠúŠÔ 2018-2020”N“x
  •¬Šz 1768–œ‰~i’¼ÚŒo”ïEŠÔÚŒo”ï‚Ì‘Šzj
     
[3]  •â•Ž–‹Æ–¼ ‰ÈŠw‹Zplވ笔ï•â•‹à ‘ì‰zŒ¤‹†ˆõŽ–‹Æ
  –¼Ì ‘ì‰zŒ¤‹†ˆõ‚ÌŒ¤‹†”ïAŒ¤‹†ŠÂ‹«®”õ”ï
  ‰Û‘è–¼ •úŽËŒõ‚‰·‚ˆ³•ÏŒ`ŽÀŒ±‚É‚æ‚éƒ}ƒ“ƒgƒ‹‘JˆÚ‘wE‰º•”ƒ}ƒ“ƒgƒ‹‚Ì”S«—¦‚ÌŒˆ’è
  ŠúŠÔ 2017-2021 ”N“x
  ‹àŠz 2400–œ‰~i’¼ÚŒo”ïj
     
[2] –¼Ì ‰ÈŠwŒ¤‹†”ï•â•‹à
Œ¤‹†Ží–Ú Šî”ÕŒ¤‹†iCj
‰Û‘è–¼ •úŽËŒõ‚ð—p‚¢‚½’´‚ˆ³‚‰·•ÏŒ`ŽÀŒ±‚É‚æ‚éƒ}ƒ“ƒgƒ‹‘JˆÚ‘w‘S—̈æ‚Ì”S«—¦\‘¢‚̉ð–¾
‰Û‘è”Ô† 24540515 [‰ÈŠwŒ¤‹†”Ž–‹Æƒf[ƒ^ƒx[ƒX]
•¬ŠúŠÔ 2012”N“xi2013-2014”N“x‚ɂ‚¢‚Ä‚ÍŠCŠO“]o‚É‚æ‚鎑Ši‘rŽ¸‚Ì‚½‚ߎ–‹Æ”pŽ~j
•¬Šz 182–œ‰~i’¼ÚŒo”ïEŠÔÚŒo”ï‚Ì‘Šzj
     
[1] –¼Ì ‰ÈŠwŒ¤‹†”ï•â•‹à
Œ¤‹†Ží–Ú ŽáŽèŒ¤‹†iBj
‰Û‘è–¼ ƒEƒHƒYƒŠƒAƒCƒg‚Ì•úŽËŒõ•ÏŒ`ŽÀŒ±‚É‚æ‚éƒ}ƒ“ƒgƒ‹‘JˆÚ‘w‚Ì”S«—¦‚ÉŠÖ‚·‚錤‹†
‰Û‘è”Ô† 22740346 [‰ÈŠwŒ¤‹†”Ž–‹Æƒf[ƒ^ƒx[ƒX]
•¬ŠúŠÔ 2010-2011”N“x
•¬Šz 429–œ‰~i’¼ÚŒo”ïEŠÔÚŒo”ï‚Ì‘Šzj
     
(2) Œ¤‹†•ª’SŽÒ
[1] –¼Ì ‰ÈŠwŒ¤‹†”ï•â•‹à
  Œ¤‹†Ží–Ú ‘Û‹¤“¯Œ¤‹†‹­‰»iBj
  ‰Û‘è–¼ æi“I‚‰·‚ˆ³ŽÀŒ±‹Zp‚Æ’e«”g‘¬“x‘ª’è‹Zp‚ð‘g‚݇‚킹‚½’n‹…[•”•¨Ž¿’Tõ
  ‰Û‘è”Ô† N/A
  ‘ã•\ŽÒ ˆäã“O
  •¬ŠúŠÔ 2019-2023”N“x
  •¬Šz 40–œ‰~i2019”N“x‚Ì•ª’S‹àj
[2] –¼Ì ‰ÈŠwŒ¤‹†”ï•â•‹à
Œ¤‹†Ží–Ú Šî”ÕŒ¤‹†iBj
‰Û‘è–¼ ƒ}ƒ“ƒgƒ‹660km•s˜A‘±‚̃ŒƒIƒƒW[“I\‘¢
‰Û‘è”Ô† 22340161 [‰ÈŠwŒ¤‹†”Ž–‹Æƒf[ƒ^ƒx[ƒX]
‘ã•\ŽÒ ¼Œ´—V
•¬ŠúŠÔ 2010-2013”N“xi2013”N“x‚ɂ‚¢‚Ä‚ÍŠCŠO“]o‚É‚æ‚鎑Ši‘rŽ¸‚Ì‚½‚ß•ª’S‚ðŽ«‘Þj
•¬Šz 245–œ‰~i2010-2012”N“x‚Ì•ª’S‹à‚Ì‘Šzj

‚SD‚»‚Ì‘¼‚ÌŠwp˜_•¶


(1) ‰p•¶

y2018z
[51] T. Ishii, R. Huang, H. Fei, I. Koemets, Z. Liu, F. Maeda, L. Yuan, L. Wang, D. Druzhbin, T. Takafumi, S. Bhat, R. Farla, T. Kawazoe, N. Tsujino, E. Kulik, Y. Higo, Y. Tange, and T. Katsura (2018), The post-spinel transition in the system Mg2SiO4-Fe2SiO4: Complete agreement with the 660-km discontinuity depth and the zero-pressure interval explaining the sharp discontinuity, Bayerisches Geoinstitut Annual Report 2017, 29-31.
[50] D.M. Vasiukov, J. van Driel, C.A. McCammon, E. Bykova, M. Bykov, G. Aprilis, V. Cerantola, I. Kupenko, T. Kawazoe, R. Myhill, V. Prakapenka, H.-P. Liermann, M. Hanfland, A.I. Chumakov, L.S. Dubrovinsky, and N.A. Dubrovinskaia (2018), Iron behaviour in Fe,Al-bearing bridgmanite between 35-80 GPa, Bayerisches Geoinstitut Annual Report 2017, 85-86.
[49] D. Simonova, E. Bykova, M. Bykov, T. Kawazoe, and L.S. Dubrovinsky (2018), High-pressure behaviour of ƒÂ-AlOOH and magnesium silicate Phase D, Bayerisches Geoinstitut Annual Report 2017, 95-96.
[48] J. Buchen, H. Marquardt, S. Speziale, T. Kawazoe, T. Boffa Ballaran, and A. Kurnosov (2018), High-pressure single-crystal elasticity of iron-bearing wadsleyite and the reflectivity of the 410-km discontinuity, Bayerisches Geoinstitut Annual Report 2017, 107-108.
[47] K. Schulze, H. Marquardt, A. Kurnosov, T. Boffa Ballaran, C.A. McCammon, K. Marquardt, T. Kawazoe, and M. Koch-Mueller (2018), The effect of hydration on the elastic wave velocities of ringwoodite at pressures of Earth's transition zone, Bayerisches Geoinstitut Annual Report 2017, 108-110.
[46] N. Satta, H. Marquardt, A. Kurnosov, T. Kawazoe, and T. Boffa Ballaran (2018), Elasticity of phase E single crystals, Bayerisches Geoinstitut Annual Report 2017, 110-111.
[45] L. Wang, T. Kawazoe, N. Miyajima, and T. Katsura (2018), Small water dependence of the dislocation mobility in the olivine [001](100) slip system, Bayerisches Geoinstitut Annual Report 2017, 162-163.
[44] L. Wang, T. Kawazoe, N. Miyajima, and T. Katsura (2018), Activation of the [100](001) slip system by water incorporation in olivine, Bayerisches Geoinstitut Annual Report 2017, 164-165.

y2017z
[43] T. Ishii, R. Sinmyo, T. Komabayashi, T. Boffa Ballaran, T. Kawazoe, N. Miyajima, and T. Katsura (2017), Synthesis of LiNbO3-type Mg3Al2Si3O12 at 45 GPa and 2000 K with a large volume press and subsequent Rietveld refinement, Bayerisches Geoinstitut Annual Report 2016, 69.
[42] T. Kawazoe, I. Ohira, T. Ishii, T. Boffa Ballaran, C. McCammon, A. Suzuki, and E. Ohtani (2017), Single crystal synthesis of ƒÂ-(Al,Fe)OOH, Bayerisches Geoinstitut Annual Report 2016, 70.
[41] D. Simonova, E. Bykova, M. Bykov, T. Kawazoe, and L.S. Dubrovinsky (2017), High-pressure behaviour of ƒÂ-AlOOH and Phase D, Bayerisches Geoinstitut Annual Report 2016, 71-72.
[40] T. Ishii, H. Fei, Z.D. Liu, T. Kawazoe, N. Tsujino, T. Yamamoto, L. Wang, D. Druzhbin, E. Kulik, F. Maeda, Y. Higo, Y. Tange, and T. Katsura (2017), Precise determination of the post-spinel transition binary loop in the MgO-FeO-SiO2 system by in situ X-ray diffraction, Bayerisches Geoinstitut Annual Report 2016, 76-77.
[39] J.R. Smyth, L. Zhang, and T. Kawazoe (2017), Stability, composition, and crystal structure of DHMS phase E in transition zone, Bayerisches Geoinstitut Annual Report 2016, 84-85.
[38] J. Buchen, H. Marquardt, T. Kawazoe, and T. Boffa Ballaran (2017), Anisotropic compression of (Mg0.89Fe0.1)2SiO4 wadsleyite reveals the stress conditions inside a diamond anvil cell, Bayerisches Geoinstitut Annual Report 2016, 92.
[37] J. Buchen, H. Marquardt, T. Kawazoe, A. Kurnosov, S. Speziale, and T. Boffa Ballaran (2017), Internally consistent elasticity measurements of single-crystals of (Mg0.9Fe0.1)2SiO4 wadsleyite at high pressures and high temperatures: Hydrous transition zone or non-pyrolitic mantle?, Bayerisches Geoinstitut Annual Report 2016, 93.
[36] K. Schulze, H. Marquardt, A. Kurnosov, T. Kawazoe, T. Boffa Ballaran, and M. Koch-Mueller (2017), Direct determination of the chemical effects on the high-pressure singlecrystal elasticity of ringwoodite, Bayerisches Geoinstitut Annual Report 2016, 97.
[35] R. Farla, A. Rosenthal, C. Bollinger, S. Petitgirard, J. Guignard, W. Crichton, N. Miyajima, T. Kawazoe, and D.J. Frost (2017), Deformation of bimineralic eclogite in comparison with garnetite and clinopyroxenite, Bayerisches Geoinstitut Annual Report 2016, 121-122.
[34] D. Druzhbin, T. Kawazoe, H. Fei, D. Frost, and T. Katsura (2017), Silicon self-diffusion coefficient in wadsleyite as a function of water content, Bayerisches Geoinstitut Annual Report 2016, 134.
[33] L. Wang, T. Kawazoe, N. Miyajima, and T. Katsura (2017), Negative water-content dependence of the dislocation mobility in the olivine [001](100) slip system, Bayerisches Geoinstitut Annual Report 2016, 135-137.
[32] T. Ishii, N. Tsujino, T. Yamamoto, Z. Liu, T. Kawazoe, L. Wang, D. Druzhbin, F. Maeda, Y. Higo, Y. Tange, and T. Katsura (2017), Pressure generations over 60 GPa using large volume press with tungsten carbide anvils, Bayerisches Geoinstitut Annual Report 2016, 154.

y2016z
[31] T. Kawazoe, A. Chaudhari, J.R. Smyth, and C. McCammon (2016), Coupled substitution of Fe3+ and H+ for Si in wadsleyite, Bayerisches Geoinstitut Annual Report 2015, 73-74.
[30] N. Miyajima, and T. Kawazoe (2016), Weak-beam dark-field TEM characterization of dislocations on the (010) plane in simple-shear-deformed wadsleyite, Bayerisches Geoinstitut Annual Report 2015, 141-142.
[29] D. Druzhbin, T. Kawazoe, H. Fei, D.J. Frost, and T. Katsura (2016), Si self-diffusion coefficient in wadsleyite as a function of water and iron content, Bayerisches Geoinstitut Annual Report 2015, 131-132.
[28] C. McCammon, J. van Driel, T. Kawazoe, R. Myhill, L. Dubrovinsky (2016), Strong affinity of Al-containing bridgmanite for ferric iron, Bayerisches Geoinstitut Annual Report 2015, 61-62.
[27] J. Buchen, H. Marquardt, T. Kawazoe, A. Kurnosov, S. Speziale, and T. Boffa Ballaran (2016), Internally consistent high-pressure high-temperature single-crystal elasticity of wadsleyite, ƒÀ-(Mg0.9,Fe0.1)2SiO4, Bayerisches Geoinstitut Annual Report 2015, 91-93.
[26] K. Schulze, H. Marquardt, A. Kurnosov, T. Kawazoe, T. Boffa Ballaran, and M. Koch-Mueller (2016), Comparative single-crystal elasticity measurements of ringwoodite at simultaneous high-pressure and high-temperature, Bayerisches Geoinstitut Annual Report 2015, 93-94.
[25] L. Zhang, J.R. Smyth, J. Allaz, E. Ellison, T. Kawazoe, and S.D. Jacobsen (2016), Transition metals in the transition zone: crystal chemistry of minor element substitution in wadsleyite, Bayerisches Geoinstitut Annual Report 2015, 71-73.
[24] R. Farla, A. Rosenthal, C. Bollinger, S. Petitgirard, J. Guignard, T. Kawazoe, and D. Frost (2016), Deformation of bimineralic eclogite and olivine polycrystals at high pressures and temperatures, Bayerisches Geoinstitut Annual Report 2015, 125-128.
[23] T. Ishii, L. Shi, R. Huang, N. Tsujino, D. Druzhbin, R. Myhill, Y. Li, L. Wang, T. Yamamoto, N. Miyajima, T. Kawazoe, N. Nishiyama, Y. Higo, Y. Tange, and T. Katsura (2016), Generation of pressures over 40 GPa using a Kawai-type multianvil apparatus with tungsten carbide anvils, Bayerisches Geoinstitut Annual Report 2015, 164-165.

y2015”Nz
[22] T. Kawazoe (2015), High-pressure synthesis of single-crystal (Mg0.1,Fe0.9)2SiO4 wadsleyite, Bayerisches Geoinstitut Annual Report 2014, 84.
[21] J. Buchen, H. Marquardt, T. Kawazoe, A. Kurnosov, and T. Boffa Ballaran (2015), Single-crystal elasticity of wadsleyite, ƒÀ-(Mg0.1,Fe0.9)2SiO4, at combined high pressure and high temperature, Bayerisches Geoinstitut Annual Report 2014, 90-92.
[20] K. Schulze, H. Marquardt, A. Kurnosov, T. Kawazoe, and T. Boffa Ballaran (2015), High-pressure/high-temperature measurements of the elastic properties of single-crystal ringwoodite, Bayerisches Geoinstitut Annual Report 2014, 92-93.
[19] L. Wang, Z. Pinter, S. Blaha, R. Farla, T. Kawazoe, and T. Katsura (2015), Pressure dependence of [100](010) and [001](010) dislocation mobility in natural olivine, Bayerisches Geoinstitut Annual Report 2014, 138-140.
[18] L. Shi, T. Katsura, T. Kawazoe, R. Farla, and M. Petri (2015), Adjustment of the high-pressure volume in the new DIA-type multianvil apparatus 'IRIS-15', Bayerisches Geoinstitut Annual Report 2014, 161-162.

y2011-2014”Nz
[17] T. Kawazoe (2014), Pressure-temperature generation to 19 GPa and 1800 K in a deformation mode using a six hydraulic-ram multi-anvil apparatus, Bayerisches Geoinstitut Annual Report 2013, 143-144.
[16] R. Myhill, T. Kawazoe, and T. Katsura (2014), Ultrahigh pressure generation in the multianvil cell, Bayerisches Geoinstitut Annual Report 2013, 142-143.
[15] L. Wang, S. Blaha, H. Fei, R. Farla, T. Kawazoe, H. Mohseni, and T. Katsura (2014), Temperature dependence of [100](010) and [001](010) dislocation mobility in natural olivine, Bayerisches Geoinstitut Annual Report 2013, 125-127.
[14] J. Chen, M. Pamato, Y. Lin, T. Katsura, T. Kawazoe, and L. Ziberna (2014), Water solubility in (Mg,Fe)(Si,Al)O3 perovskite, Bayerisches Geoinstitut Annual Report 2013, 71-72.
[13] T. Ohuchi, Y. Nishihara, T. Kawazoe, D. Spengler, R. Shiraishi, A. Suzuki, T. Kikegawa, and E. Ohtani (2013), Superplasticity in hydrous melt-bearing dunite and its implications for shear localization in the Earth's upper mantle, Photon Factory Activity Report 2012 highlights, 46-47.
[12] Y. Nishihara, T. Ohuchi, T. Kawazoe, D. Spengler, M. Tasaka, T. Hiraga, T. Kikegawa, A. Suzuki, and E. Ohtani (2011), Rheology of fine-grained forsterite at high-pressure, Photon Factory Activity Report 2010, 236.
[11] T. Inoue, A. Yamada, T. Kawazoe, N. Nishiyama, C. Yang, and T. Kikegawa (2011), Application of 6-6 type multi-anvil system for MAX-80 and MAX-III, Photon Factory Activity Report 2010, 228.

y2003-2006”Nz
[10] R. Secco, E. Ohtani, K. Litasov, A. Suzuki, H. Terasaki, T. Kawazoe, K. Nishida, and T. Sakamaki (2006), Viscosity of liquid Fe and Fe-Si at high pressures, SPring-8 User Experiment Report (2005B).
[9] E. Ohtani, T. Kawazoe, A. Suzuki, H. Terasaki, K. Litasov, and K. Nishida (2006), In situ determination of phase and melting relations of Fe-FeS-FeO system at high pressure and temperature and applications to the Martian core, SPring-8 User Experiment Report (2005B).
[8] E. Ohtani, T. Sakai, T. Kawazoe, and T. Kondo (2006), Metal-silicate fractionation in the deep magma ocean and light elements in the core, Geochimica et Cosmochimica Acta, 70(18), A455.
[7] K. Litasov, E. Ohtani, A. Suzuki, H. Terasaki, A. Sano, T. Kawazoe, and S. Ghosh (2005), In situ X-ray determination of the decomposition boundary of superhydrous phase B and phase D in natural peridotite, SPring-8 User Experiment Report (2005A).
[6] E. Ohtani, T. Kawazoe, A. Sano, H. Terasaki, K. Litasov, A. Suzuki, Y. Tange, and K.-i. Funakoshi (2005), In situ X-ray observation of melting relations in iron-light element systems at high pressure and temperature, SPring-8 User Experiment Report (2005A).
[5] S. Ghosh, A. Sano, A. Shimojuku, T. Kawazoe, and K. Litasov (2005), 2nd International Workshop on Water Dynamics, Gondwana Research, 8(2), 291-292.
[4] A. Sano, E. Ohtani, A. Suzuki, H. Terasaki, T. Kawazoe, R. Ando, and J. Allwardt (2005), Post-garnet transformation in hydrous MORB system, SPring-8 User Experiment Report (2004B).
[3] T. Kawazoe, and E. Ohtani (2005), Solubility of silicon and oxygen in liquid iron coexisting with (Mg,Fe)SiO3-perovskite and implications for core formation, Proceedings of AIRAPT-20, E. Dinjus, N. Dahmen, Eds., Forschungszentrum Karlsruhe GmbH.
[2] E. Ohtani, K. Litasov, A. Sano, T. Kawazoe, A. Suzuki, and K.-i. Funakoshi (2004), Precise determination of the phase boundary of the garnet-perovskite transformation in the MORB layer of the descending slabs, SPring-8 User Experiment Report (2004A).
[1] E. Ohtani, T. Kawazoe, Y. Kanbe, and K. Heshiki (2003), Reaction and separation of metal and silicate in the early Earth, and light elements in the core. Geochimica et Cosmochimica Acta, suppl. 1, 67(18), A355.

(2) ˜a•¶
y2012-2013”Nz
[13] “üät“O’j, ¼Œ´—V, ’O‰ºŒc”Í, S. Greaux, ì“Y‹MÍ, ‘å“à’q”Ž, ”ìŒã—SŽi, š –{Œ’L, C. Zhou, —L–{ŠxŽj, ”’Î’qŽq, ŠÛŽRŒº‘¾, ŽR–{^—R”ü, ˆÉ‰ê•¶r (2013), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹ŽÀŒ±‹Zp‚Ì‚“x‰»‚Ɖº•”ƒ}ƒ“ƒgƒ‹ðŒ‰º‚ł̃ŒƒIƒƒW[E’e«”g‘¬“xE‘ŠŠÖŒW‚̸–§Œˆ’èF’n‹…[•”‚̃_ƒCƒiƒ~ƒNƒX‚Æi‰»‰ß’ö‚̉𖾂Ɍü‚¯‚Ä, SPring-8 User Experiment Report (2012B).
[12] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, D. Spengler (2013), ‚ˆ³‰º‚ł̃tƒHƒ‹ƒXƒeƒ‰ƒCƒg‚Ì—±ŒaˆË‘¶ƒNƒŠ[ƒv, Photon Factory Activity Report 2012, 2013.
[11] “üät“O’j, ¼Œ´—V, ’O‰ºŒc”Í, S. Greaux, ì“Y‹MÍ, ‘å“à’q”Ž, ”ìŒã—SŽi, F. Wang, Y. Zou, C. Zhou, —L–{ŠxŽj, ”’Î’qŽq, ŠÛŽRŒº‘¾ (2012), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹ŽÀŒ±‹Zp‚Ì‚“x‰»‚Ɖº•”ƒ}ƒ“ƒgƒ‹ðŒ‰º‚ł̃ŒƒIƒƒW[E’e«”g‘¬“xE‘ŠŠÖŒW‚̸–§Œˆ’èF’n‹…[•”‚̃_ƒCƒiƒ~ƒNƒX‚Æi‰»‰ß’ö‚̉𖾂Ɍü‚¯‚Ä, SPring-8 User Experiment Report (2012A).
[10] “üät“O’j, ¼ŽRé³, ¼Œ´—V, ’O‰ºŒc”Í, S. Greaux, ì“Y‹MÍ, ‘å“à’q”Ž, ¼^”V, ªŠÝ—ä, –؉º–², F. Wang, Y. Zou, C. Zhou (2012), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹ŽÀŒ±‹Zp‚Ì‚“x‰»‚Ɖº•”ƒ}ƒ“ƒgƒ‹ðŒ‰º‚ł̃ŒƒIƒƒW[E’e«”g‘¬“xE‘ŠŠÖŒW‚̸–§Œˆ’èF’n‹…[•”‚̃_ƒCƒiƒ~ƒNƒX‚Æi‰»‰ß’ö‚̉𖾂Ɍü‚¯‚Ä, SPring-8 User Experiment Report (2011B).
[9] ‘å“à’q”Ž, ¼Œ´—V, ì“Y‹MÍ, ¼^”V (2012), ‚ˆ³‰º‚ł̃Jƒ“ƒ‰ƒ“΂̗¬“®“Á«‚Ö‚Ì…‚̉e‹¿, Photon Factory Activity Report 2011, 285.

y2009-2011”Nz
[8] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, D. Spengler, “cã”üŽ÷, •½‰êŠx•F, ‹TŒTì‘ì”ü, —é–غ•v, ‘å’J‰hŽ¡ (2011), ×—±ƒJƒ“ƒ‰ƒ“΂̂ˆ³‰º‚ł̃ŒƒIƒƒW[, KEK Proceedings 2011u•úŽËŒõ‚ˆ³Œ¤‹†‚É‚¨‚¯‚éŽÀŒ±‹Zp‚Ìe“WŠJ‡U-ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹Œ^‚ˆ³”­¶‘•’u‚ð’†S‚É-v, 10, 11-14.
[7] “üät“O’j, ¼ŽRé³, ¼Œ´—V, ’O‰ºŒc”Í, ŽR“cŠô–ç, M. Whitaker, S. Greaux, ì“Y‹MÍ, ‘å“à’q”Ž, ¼^”V, ªŠÝ—ä, –؉º–², F. Wang, Y. Zou, C. Zhou (2011), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹ŽÀŒ±‹Zp‚Ì‚“x‰»‚Ɖº•”ƒ}ƒ“ƒgƒ‹ðŒ‰º‚ł̃ŒƒIƒƒW[E’e«”g‘¬“xE‘ŠŠÖŒW‚̸–§Œˆ’èF’n‹…[•”‚̃_ƒCƒiƒ~ƒNƒX‚Æi‰»‰ß’ö‚̉𖾂Ɍü‚¯‚Ä, SPring-8 User Experiment Report (2011A).
[6] “üät“O’j, ¼ŽRé³, ¼Œ´—V, ’O‰ºŒc”Í, ŽR“cŠô–ç, M. Whitaker, S. Greaux, ì“Y‹MÍ, ‘å“à’q”Ž, ¼^”V, ªŠÝ—ä, –؉º–², F. Wang, Y. Zou, C. Zhou (2011), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹ŽÀŒ±‹Zp‚Ì‚“x‰»‚Ɖº•”ƒ}ƒ“ƒgƒ‹ðŒ‰º‚ł̃ŒƒIƒƒW[E’e«”g‘¬“xE‘ŠŠÖŒW‚̸–§Œˆ’èF’n‹…[•”‚̃_ƒCƒiƒ~ƒNƒX‚Æi‰»‰ß’ö‚̉𖾂Ɍü‚¯‚Ä, SPring-8 User Experiment Report (2011A).
[5] “üät“O’j, ¼ŽRé³, ’O‰ºŒc”Í, ŽR“cŠô–ç, ‰Í–ì‹`¶, M. Whitaker, S. Greaux, ì“Y‹MÍ, ¼Œ´—V (2011), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹ŽÀŒ±‹Zp‚Ì‚“x‰»‚Ɖº•”ƒ}ƒ“ƒgƒ‹ðŒ‰º‚ł̃ŒƒIƒƒW[E’e«”g‘¬“xE‘ŠŠÖŒW‚̸–§Œˆ’èF’n‹…[•”‚̃_ƒCƒiƒ~ƒNƒX‚Æi‰»‰ß’ö‚̉𖾂Ɍü‚¯‚Ä, SPring-8 User Experiment Report (2010B).
[4] “üät“O’j, ¼ŽRé³, ’O‰ºŒc”Í, ŽR“cŠô–ç, ¼Œ´—V, ‰Í–ì‹`¶, M. Whitaker, S. Greaux, ì“Y‹MÍ (2010), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹ŽÀŒ±‹Zp‚Ì‚“x‰»‚Ɖº•”ƒ}ƒ“ƒgƒ‹ðŒ‰º‚ł̃ŒƒIƒƒW[E’e«”g‘¬“xE‘ŠŠÖŒW‚̸–§Œˆ’èF’n‹…[•”‚̃_ƒCƒiƒ~ƒNƒX‚Æi‰»‰ß’ö‚̉𖾂Ɍü‚¯‚Ä, SPring-8 User Experiment Report (2010A).
[3] ¼Œ´—V, M‰zŒ«ˆê, ”ìŒã—SŽi, ì“Y‹MÍ, ‘å“à’q”Ž (2009), ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹‘•’u‚ð—p‚¢‚½‚ˆ³‚¹‚ñ’f•ÏŒ`‚É‚¨‚¯‚鉞—Í‘ª’è, SPring-8 User Experiment Report (2009A).
[2] ¼ŽRé³, “üät“O’j, ˜a“cŒõ•½, ’O‰ºŒc”Í, ì“Y‹MÍ, ¼Œ´—V, Y. Wang, S. Greaux (2009), ƒwƒ}ƒ^ƒCƒg‚ˆ³‘Š‚ÌŒ‹»\‘¢‚ÌŒˆ’è|ƒyƒƒuƒXƒJƒCƒgŒ^\‘¢‚©A‚ ‚é‚¢‚ÍARh2O3-IIŒ^\‘¢‚©|, SPring-8 User Experiment Report (2009A).
[1] ¼Œ´—V, M‰zŒ«ˆê, ”ìŒã—SŽi, ’Ò–ì“TG, ì“Y‹MÍ, ¼ŽRé³, ‹v•Û—F–¾, ‰ºh², Ž›è‰p‹I (2009), “ñŽŸŒ³Xü‰ñÜ‘•’u‚ð—p‚¢‚½‚ˆ³‰º‚ł̃Jƒ“ƒ‰ƒ“΂̉ž—͊ɘaŽŽŒ±, SPring-8 User Experiment Report (2008B).


‚TDŠw‰ïEƒ[ƒNƒVƒ‡ƒbƒv‚Å‚Ì”­•\


y¡Œã‚Ì—\’èz
[176] N. Miyajima, J. Buchen, and T. Kawazoe, Twinning in wadsleyite, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2020”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2020”N7ŒŽ16“ú (12-16“ú).
 
y2019”Nz
[175] ì“Y‹MÍ, ”’ÎŒ\, ˆäã“O, •Ÿ‰ªG, ’O‰ºŒc”Í, 1273 K‚É‚¨‚¯‚éƒJƒ“ƒ‰ƒ“Î|ƒEƒHƒYƒŠƒAƒCƒg|ƒŠƒ“ƒOƒEƒbƒ_ƒCƒg‘ŠŠÖŒW‚ÌÄŒŸ“¢, ‘æ60‰ñ‚ˆ³“¢˜_‰ï, –kŠC“¹ŽD–yŽsE‚©‚Å‚é2E7–kŠC“¹—§“¹–¯Šˆ“®ƒZƒ“ƒ^[, 2019”N10ŒŽ25“ú (23-25“ú).
[174] ì“Y‹MÍ, ‘啽Ši, Έä‹M”V, —é–غ•v, ‘å’J‰hŽ¡, ƒÂ-(Al,Fe)OOH’PŒ‹»‚Ì‚ˆ³‡¬, “ú–{z•¨‰ÈŠw‰ï2019”N”N‰ï, •Ÿ‰ªŒ§•Ÿ‰ªŽsE‹ãB‘åŠwˆÉ“sƒLƒƒƒ“ƒpƒX, 2019”N9ŒŽ22“ú (20-22“ú).
[173] T. Kawazoe, F. Heidelbach, N. Miyajima, and T. Ishii, Cool lower mantle transition zone inferred from seismic anisotropy of deformed ringwoodite, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2019”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2019”N5ŒŽ26“ú (26-30“ú).
[172] S. Kimura, K. Ohta, T. Kawazoe, K. Hirose, H. Kagi, and T. Yagi, Lattice thermal conductivity of wadsleyite and ringwoodite at the mantle transition zone pressures, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2019”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2019”N5ŒŽ27“ú (26-30“ú).
[171] N. Satta, H. Marquardt, A. Kurnosov, T. Boffa Ballaran, J. Buchen, C. McCammon, and T. Kawazoe, Single crystal elasticity of Fe-bearing phase E by Brillouin spectroscopy, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2019”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2019”N5ŒŽ30“ú (26-30“ú).
[170] T. Komabayashi, G. Pesce, R. Sinmyo, T. Kawazoe, H. Breton, Y. Shimoyama, K. Glazyrin, Z. Konopkova, and M. Mezouar, Phase relations in the system Fe-Ni-Si to 200 GPa and 3900 K and implications for Earthfs core, EGU General Assembly 2019, ƒI[ƒXƒgƒŠƒAEƒrƒGƒiŽs, 2019”N4ŒŽ8“ú (7-12“ú).

y2018”Nz
[169] L. Wang, T. Kawazoe, N. Miyajima, and T. Katsura, Activation of [100](001) slip system by water incorporation in olivine, American Geophysical Union Fall Meeting 2018, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2018”N12ŒŽ10-14“ú.
[168] ì“Y‹MÍ, Š`àVãÄ, ˆäã“O, L“‡‘åŠw—ŠwŒ¤‹†‰È’n‹…˜f¯ƒVƒXƒeƒ€ŠwêU‚É‚¨‚¯‚éƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹‘•’u—pŽÀŒ±€”õŽº‚Ì—§‚¿ã‚°, ‘æ59‰ñ‚ˆ³“¢˜_‰ï, ‰ªŽRŒ§‰ªŽRŽsE‰ªŽR—‰È‘åŠw, 2018”N11ŒŽ26-28“ú.
[167] –Ø‘º´“ñ, ‘¾“cŒ’“ñ, ì“Y‹MÍ, œA£Œh, Œ®—T”V, ”ª–Ø‹MŽu, ‚ˆ³‰º‚É‚¨‚¯‚éƒEƒHƒYƒŒƒAƒCƒgEƒŠƒ“ƒOƒEƒbƒ_ƒCƒg‚ÌŠiŽq”M“`“±—¦‘ª’è, ‘æ59‰ñ‚ˆ³“¢˜_‰ï, ‰ªŽRŒ§‰ªŽRŽsE‰ªŽR—‰È‘åŠw, 2018”N11ŒŽ26-28“ú.
[166] J. Buchen, K. Schulze, A. Kurnosov, T. Boffa Ballaran, S. Speziale, T. Kawazoe, M. Koch-Mueller, and H. Marquardt, Tracing water in the transition zone: from single-crystal elasticity to seismic observables, GeoBonn 2018, ƒhƒCƒcEƒ{ƒ“, 2018”N9ŒŽ2-6“ú.
[165] N. Satta, H. Marquardt, A. Kurnosov, T. Boffa Ballaran, J. Buchen, C. McCammon, and T. Kawazoe, Single-crystal elasticity of iron-bearing phase E by Brillouin spectroscopy and seismic detection of water in Earth's upper mantle, GeoBonn 2018, ƒhƒCƒcEƒ{ƒ“, 2018”N9ŒŽ2-6“ú.
[164] A. Nakajima, T. Sakamaki, T. Kawazoe, and A. Suzuki, Water effect on the mantle melting at the top of the lower mantle, 56th European High Pressure Research Group (EHPRG) meeting, ƒ|ƒ‹ƒgƒKƒ‹EAveiro, 2018”N9ŒŽ2-7“ú.
[163] N. Satta, H. Marquardt, A. Kurnosov, T. Boffa Ballaran, J. Buchen, C. McCammon, and T. Kawazoe, Single-crystal elasticity of iron-rich phase E, Sixteenth International Symposium on Experimental Mineralogy, Petrology and Geochemistry (EMPG-XVI), ƒtƒ‰ƒ“ƒX‹¤˜a‘ƒNƒŒƒ‹ƒ‚ƒ“ƒtƒFƒ‰ƒ“, 2018”N6ŒŽ17-21“ú.
[162] T. Kawazoe, Coupled substitution of Fe3+ and H+ for Si in wadsleyite, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2018”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2018”N5ŒŽ20-24“ú.
[161] T. Ishii, I. Ohira, T. Kawazoe, T. Boffa Ballaran, A. Suzuki, and E. Ohtani, Single crystal X-ray structure study of ƒÂ-phase AlOOH-FeOOH-MgSiO2(OH)2, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2018”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2018”N5ŒŽ20-24“ú.
[160] A. Nakajima, T. Sakamaki, T. Kawazoe, and A. Suzuki, Melting phenomenon at the top of the lower mantle, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2018”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2018”N5ŒŽ20-24“ú.
[159] J. Buchen, H. Marquardt, K. Schulze, A. Kurnosov, T. Boffa Ballaran, Sergio Speziale, and T. Kawazoe, Tracing water in the transition zone: from wadsleyite single-crystal elasticity to seismic observables, European Geosciences Union General Assembly 2018, ƒI[ƒXƒgƒŠƒAEƒrƒGƒiŽs, 2018”N4ŒŽ8-13“úiµ‘Òu‰‰j.
[158] T. Ishii, R. Huang, H. Fei, I. Koemets, Z. Liu, F. Maeda, L. Yuan, L. Wang, D. Druzhbin, T. Yamamoto, S. Bhat, R. Farla, T. Kawazoe, N. Tsujino, E. Kulik, Y. Higo, Y. Tange, and T. Katsura, The pressure and thickness of the post-spinel transition in (Mg,Fe)2SiO4 explaining the sharp 660-km discontinuity, European Geosciences Union General Assembly 2018, ƒI[ƒXƒgƒŠƒAEƒrƒGƒiŽs, 2018”N4ŒŽ8-13“ú.
[157] Y. Sakoda, T. Kawazoe, J. Ando, N. Tomioka, H. Ohfuji, and Y. Kodama, Microstructures of experimentally deformed carbon steels, VŠwp—̈挤‹†uŠj|ƒ}ƒ“ƒgƒ‹‹¤i‰»v•½¬29”N“x‘ÛƒVƒ“ƒ|ƒWƒEƒ€, ˆ¤•QŒ§¼ŽRŽsˆ¤•Q‘åŠw“ì‰Á‹L”Oƒz[ƒ‹, 2018”N3ŒŽ26-29“ú.
[156] A. Nakajima, T. Sakamaki, T. Kawazoe, and A. Suzuki, Melting experiments of hydrous peridotite under the top of the lower mantle conditions, VŠwp—̈挤‹†uŠj|ƒ}ƒ“ƒgƒ‹‹¤i‰»v•½¬29”N“x‘ÛƒVƒ“ƒ|ƒWƒEƒ€, ˆ¤•QŒ§¼ŽRŽsˆ¤•Q‘åŠw“ì‰Á‹L”Oƒz[ƒ‹, 2018”N3ŒŽ26-29“ú.
[155] ì“Y‹MÍ, Creep strength of ringwoodite measured using a D-DIA apparatus, ‘æ5‰ñˆ¤•Q‘åŠwæi’´‚ˆ³‰ÈŠwŒ¤‹†‹’“_iPRIUSjƒVƒ“ƒ|ƒWƒEƒ€, ˆ¤•Q‘åŠw‘‡Œ¤‹†“1 ’n‹…[•”ƒ_ƒCƒiƒ~ƒNƒXŒ¤‹†ƒZƒ“ƒ^[, 2018”N2ŒŽ27-28“ú.
[154] T. Kawazoe, Creep strength of ringwoodite, First HiPeR International Symposium, L“‡‘åŠw“ŒL“‡ƒLƒƒƒ“ƒpƒX, 2018”N1ŒŽ26“ú.

y2017”Nz



ƒ‰ƒCƒX‘åŠw‚É‚Ä
’Ö싆¬‚³‚ñ‚Æ
i2017”N1ŒŽAƒAƒƒŠƒJ‡O‘ƒeƒLƒTƒXBƒqƒ…[ƒXƒgƒ“Žsj
[153] J. Buchen, H. Marquardt, T. Boffa Ballaran, T. Kawazoe, S. Speziale, and A. Kurnosov, How the 410-km discontinuity reflects mantle water content: Constraints from high-pressure experiments on wadsleyite single-crystal Elasticity, American Geophysical Union Fall Meeting 2017, ƒAƒƒŠƒJ‡O‘ƒjƒ…[ƒI[ƒŠƒ“ƒYŽs, 2017”N12ŒŽ11-15“ú.
[152] T. Ishii, R. Huang, H. Fei, I. Koemets, Z. Liu, F. Maeda, L. Yuan, L. Wang, D. Druzhbin, T. Yamamoto, S. Bhat, R. Farla, T. Kawazoe, N. Tsujino, E. Kulik, Y. Higo, Y. Tange, and T. Katsura, New results of the post-spinel transition pressure in Mg2SiO4 by means of in-situ X-ray diffraction in a multi-anvil press: complete agreement with the 660-km discontinuity depth, American Geophysical Union Fall Meeting 2017, ƒAƒƒŠƒJ‡O‘ƒjƒ…[ƒI[ƒŠƒ“ƒYŽs, 2017”N12ŒŽ11-15“ú.
[151] T. Katsura, T. Ishii, R. Huang, F. Maeda, L. Yuan, S. Bhat, R. Farla, T. Kawazoe, N. Tsujino, Z. Liu, H. Fei, L. Wang, D. Druzhbin, T. Yamamoto, E. Kulik, I. Koemets, Y. Higo, and Y. Tange, Geometry and width of the ringwoodite - bridgmanite+ferropericlase binary loop in the system (Mg,Fe)2SiO4: Interpretation of the sharpness of the 660-km discontinuity, American Geophysical Union Fall Meeting 2017, ƒAƒƒŠƒJ‡O‘ƒjƒ…[ƒI[ƒŠƒ“ƒYŽs, 2017”N12ŒŽ11-15“ú.
[150] K. Schulze, H. Marquardt, T. Boffa Ballaran, A. Kurnosov, T. Kawazoe, and M. Koch-Mueller, Small effect of hydration on elastic wave velocities of ringwoodite in Earth's transition zone, American Geophysical Union Fall Meeting 2017, ƒAƒƒŠƒJ‡O‘ƒjƒ…[ƒI[ƒŠƒ“ƒYŽs, 2017”N12ŒŽ11-15“ú.
[149] ì“Y‹MÍ, ŒÅ‘Š‘Š“]ˆÚ‚É‚æ‚éƒEƒHƒYƒŠƒAƒCƒg‘åŒ^’PŒ‹»‡¬, ‘æ58‰ñ‚ˆ³“¢˜_‰ï, ˆ¤’mŒ§–¼ŒÃ‰®Žs–¼ŒÃ‰®‘åŠw, 2017”N11ŒŽ8-10“ú.
[148] I. Ohira, S. Kamada, J.M. Jackson, W. Sturhahn, G.J. Finkelstein, T. Kawazoe, F. Maeda, N. Hirao, S. Nakano, E. Ohtani, and A. Suzuki, Compressional behavior of ƒÂ-(Al, Fe)OOH to lower mantle pressures, 9th High Pressure Mineral Physics Seminar (HPMPS-9), ƒtƒ‰ƒ“ƒXESaint Malo, 2017”N9ŒŽ24-28“ú.
[147] J. Buchen, H. Marquardt, S. Speziale, T. Kawazoe, T. Boffa Ballaran, and A. Kurnosov, High-pressure high-temperature single-crystal elasticity of iron-bearing wadsleyite: Reappraising the water sensitivity of seismic observables, 9th High Pressure Mineral Physics Seminar (HPMPS-9), ƒtƒ‰ƒ“ƒXESaint Malo, 2017”N9ŒŽ24-28“úiBest Poster Awardj.
[146] K. Schulze, H. Marquardt, A. Kurnosov, T. Kawazoe, and T. Boffa Ballaran, The effect of hydration on the elastic properties of ringwoodite at transition zone pressures, 9th High Pressure Mineral Physics Seminar (HPMPS-9), ƒtƒ‰ƒ“ƒXESaint Malo, 2017”N9ŒŽ24-28“ú.
[145] I. Ohira, J.M. Jackson, W. Sturhahn, G.J. Finkelstein, S. Kamada, T. Kawazoe, F. Maeda, N. Hirao, S. Nakano, A. Suzuki, and E. Ohtani, Sound velocity and elasticity of ƒÂ-(Al, Fe)OOH to lower mantle pressures, 55th European High Pressure Research Group (EHPRG) meeting, ƒ|[ƒ‰ƒ“ƒhEPoznan, 2017”N9ŒŽ3-8“úiµ‘Òu‰‰j.
[144] J.R. Smyth, T. Kawazoe, and Li Zhang, The elusive fourth polymorph of olivine, 27th Goldschmidt conference 2017, ƒtƒ‰ƒ“ƒXEƒpƒŠ, 2017”N8ŒŽ13-18“ú.
[143] H. Marquardt, K. Schulze, A. Kurnosov, T. Boffa Ballaran, T. Kawazoe, and M. Koch-Mueller, Is water seismically invisible in Earthfs transition zone?, 27th Goldschmidt conference 2017, ƒtƒ‰ƒ“ƒXEƒpƒŠ, 2017”N8ŒŽ13-18“úiµ‘Òu‰‰j.
[142] I. Ohira, T. Kawazoe, T. Ishii, T. Boffa Ballaran, C. McCammon, A. Suzuki, and E. Ohtani, Single crystal synthesis of ƒÂ-(Al,Fe)OOH using multi-anvil apparatus, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2017”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2017”N5ŒŽ20-25“úiŠw¶—DG”­•\Üj.
[141] H. Marquardt, K. Schulze, A. Kurnosov, J. Buchen, D. Frost, T. Boffa Ballaran, K. Marquardt, and T. Kawazoe, Understanding the Earthfs Mantle Through Advanced Elasticity Measurements, European Geosciences Union General Assembly 2017, ƒI[ƒXƒgƒŠƒAEƒrƒGƒiŽs, 2017”N4ŒŽ23-28“úiµ‘Òu‰‰j.
[140] T. Kawazoe, Advantages of large multi-anvil presses in BGI and GRC, CETUS Working Group: Rise of the HERATICs working group meeing, ƒAƒƒŠƒJ‡O‘ƒqƒ…[ƒXƒgƒ“Žs, 2017”N1ŒŽ23-24iµ‘Òu‰‰j.

y2016”Nz


“Œ–k‘åŠw3000ƒgƒ“ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹‘•’uÕ’n‚É‚Ä
‹«‹B‚³‚ñ‚Æ
i2016”N3ŒŽA‹{錧å‘äŽsj
[139] L. Wang, S. Blaha, T. Kawazoe, N. Miyajima, and T. Katsura, Negative water-content dependence of the dislocation mobility in the olivine [001](100) slip system, American Geophysical Union Fall Meeting 2016, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2016”N12ŒŽ12-16“ú.
[138] J. Buchen, H. Marquardt, A. Kurnosov, T. Boffa Ballaran, S. Speziale, and T. Kawazoe, Internally consistent single-crystal elasticity of (Mg0.89Fe0.11)2SiO4 wadsleyite at high pressures and high temperatures, American Geophysical Union Fall Meeting 2016, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2016”N12ŒŽ12-16“ú.
[137] J.R. Smyth, Li Zhang, and T. Kawazoe , Stability, composition, and crystal structure of DHMS phase E in the transition zone, American Geophysical Union Fall Meeting 2016, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2016”N12ŒŽ12-16“ú.
[136] J. Buchen, H. Marquardt, A. Kurnosov, S. Speziale, T. Kawazoe, and T. Boffa Ballaran, Internally consistent single-crystal elasticity of iron-bearing wadsleyite at high pressures and high temperatures, Second European Mineralogical Conference, ƒCƒ^ƒŠƒA‹¤˜a‘Rimini Žs, 2016”N9ŒŽ11-15“ú.
[135] T. Kawazoe, A. Chaudhari, J.R. Smyth, and C. McCammon, Coupled substitution of Fe3+ and H+ for Si in wadsleyite: a study by polarized infrared and Moessbauer spectroscopies and single-crystal X-ray diffraction, The 54th European High Pressure Research Group (EHPRG) International Meeting on High Pressure Science and Technology, ƒhƒCƒc˜A–M‹¤˜a‘ƒoƒCƒƒCƒgŽs, 2016”N9ŒŽ4-9“ú.
[134] K. Schulze, H. Marquardt, T. Kawazoe, A. Kurnosov, M. Koch-Mueller, and T. Boffa Ballaran, The effect of iron content and hydration state on the elastic moduli of single-crystal ringwoodite at high pressure, The 54th European High Pressure Research Group (EHPRG) International Meeting on High Pressure Science and Technology, ƒhƒCƒc˜A–M‹¤˜a‘ƒoƒCƒƒCƒgŽs, 2016”N9ŒŽ4-9“ú.
[133] J. Buchen, H. Marquardt, A. Kurnosov, S. Speziale, T. Kawazoe, and T. Boffa Ballaran, Internally consistent single-crystal elasticity of (Mg,Fe)2SiO4 wadsleyite at high pressures and high temperatures, The 54th European High Pressure Research Group (EHPRG) International Meeting on High Pressure Science and Technology, ƒhƒCƒc˜A–M‹¤˜a‘ƒoƒCƒƒCƒgŽs, 2016”N9ŒŽ4-9“ú.
[132] T. Ishii, N. Miyajima, T. Kawazoe, T. Katsura, Y. Higo, Y. Tange, and N. Tsujino, Generation of pressures over 40 GPa using Kawai-type multi-anvil apparatus with tungsten carbide anvils, The 54th European High Pressure Research Group (EHPRG) International Meeting on High Pressure Science and Technology, ƒhƒCƒc˜A–M‹¤˜a‘ƒoƒCƒƒCƒgŽs, 2016”N9ŒŽ4-9“ú.
[131] T. Kawazoe, A. Chaudhari, J.R. Smyth, and C. McCammon, Coupled substitution of Fe3+ and H+ for Si in wadsleyite, International WorkshopFNew Challenges in Volatile Cycling in the Deep Earth, ‹{錧å‘äŽs“Œ–k‘åŠw—tŽRƒLƒƒƒ“ƒpƒX, 2016”N7ŒŽ3-6“ú.
[130] H. Marquardt, A. Kurnosov, T. Boffa Ballaran, D. Frost, T. Kawazoe, J. Buchen, and K. Schulze, Constraints on Earth's deep volatile cycles from elasticity measurements on mantle minerals, International WorkshopFNew Challenges in Volatile Cycling in the Deep Earth, ‹{錧å‘äŽs“Œ–k‘åŠw—tŽRƒLƒƒƒ“ƒpƒX, 2016”N7ŒŽ3-6“ú.iµ‘Òu‰‰j
[129] J. Buchen, H. Marquardt, T. Boffa Ballaran, S. Speziale, T. Kawazoe, and A. Kurnosov, Internally consistent high-pressure single-crystal elasticity of (Mg,Fe)2SiO4 wadsleyite, International WorkshopFNew Challenges in Volatile Cycling in the Deep Earth, ‹{錧å‘äŽs“Œ–k‘åŠw—tŽRƒLƒƒƒ“ƒpƒX, 2016”N7ŒŽ3-6“ú.
[128] L. Wang, S. Blaha, T. Kawazoe, R. Farla, N. Miyajima, and T. Katsura, Water content dependence of dislocation mobility in olivine [100](010) and [001](100) slip system, International WorkshopFNew Challenges in Volatile Cycling in the Deep Earth, ‹{錧å‘äŽs“Œ–k‘åŠw—tŽRƒLƒƒƒ“ƒpƒX, 2016”N7ŒŽ3-6“ú.
[127] T. Kawazoe, Y. Nishihara, T. Ohuchi, N. Miyajima, G. Maruyama, Y. Higo, K. Funakoshi, and T. Irifune, Creep strength of ringwoodite measured up to 1700 K at 17-18 GPa using a deformation-DIA apparatus, 26th Goldschmidt Conference 2016, _“Þ쌧‰¡•lŽsƒpƒVƒtƒBƒR‰¡•l, 2016”N6ŒŽ26“ú-7ŒŽ1“ú.
[126] C. McCammon, J. van Driel, T. Kawazoe, R. Myhill, L. Dubrovinsky, Strong affinity of Al-containing bridgmanite for ferric iron, 26th Goldschmidt Conference 2016, _“Þ쌧‰¡•lŽsƒpƒVƒtƒBƒR‰¡•l, 2016”N6ŒŽ26“ú-7ŒŽ1“ú.
[125] Y. Nishihara, T. Ohuchi, T. Kawazoe, G. Maruyama, Y. Seto, Y. Higo, K. Funakoshi, and Y. Tange, Lattice-preferred-orientation of hcp metals studied by high-pressure deformation, 26th Goldschmidt Conference 2016, _“Þ쌧‰¡•lŽsƒpƒVƒtƒBƒR‰¡•l, 2016”N6ŒŽ26“ú-7ŒŽ1“ú.
[124] J. Chen, M.G. Pamato, T. Inoue, S. Kakizawa, B. Yang, Y. Lin, T. Katsura, T. Kawazoe, and B. Liu, Water reservior in Earth's lower mantle, 26th Goldschmidt Conference 2016, _“Þ쌧‰¡•lŽsƒpƒVƒtƒBƒR‰¡•l, 2016”N6ŒŽ26“ú-7ŒŽ1“ú.
[123] J. Buchen, H. Marquardt, T. Boffa Ballaran, S. Speziale, T. Kawazoe, and A. Kurnosov, Internally consistent high-pressure single-crystal elasticity of (Mg,Fe)2SiO4 wadsleyite, Fifteenth International Symposium on Experimental Mineralogy, Petrology and Geochemistry (EMPG-XV), ƒXƒCƒX˜A–Mƒ`ƒ…[ƒŠƒbƒqŽsETH, 2016”N6ŒŽ5-8“ú.
[122] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, ŠÛŽRŒº‘¾, £ŒË—Y‰î, ”ìŒã—SŽi, M‰zŒ«ˆê, ’O‰ºŒc”Í, ‚ˆ³•ÏŒ`‚»‚ÌêŠÏŽ@ŽÀŒ±‚É‚æ‚éhcp‹à‘®‚ÌŠiŽq‘I‘ð”zŒü‚ÌŒ¤‹†, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2016”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2016”N5ŒŽ22-26“ú.

y2015”Nz
 


’n‹…˜f¯‰ÈŠw˜A‡2015”N‘å‰ï‚É‚Ä
i2015”N5ŒŽAç—tŒ§ç—tŽsj
[121] Y. Nishihara, T. Ohuchi, T. Kawazoe, G. Maruyama, Y. Higo, K. Funakoshi, and Y. Seto, Lattice preferred orientation of hcp-iron induced by shear deformation, American Geophysical Union Fall Meeting 2015, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2015”N12ŒŽ16“ú.
[120] T. Ohuchi, Y. Nishihara, Y. Seto, T. Kawazoe, M. Nishi, G. Maruyama, M. Hashimoto, Y. Higo, K. Funakoshi, A. Suzuki, T. Kikegawa, and T. Irifune, In situ observation of crystallographic preferred orientation of deforming olivine at high pressure and high temperature, American Geophysical Union Fall Meeting 2015, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2015”N12ŒŽ16“ú.iµ‘Òu‰‰j
[119] T. Ishii, L. Shi, N. Miyajima, T. Boffa Ballaran, R. Sinmyo, T. Kawazoe, and T. Katsura, High-pressure high temperature generation over 40 GPa using Kawai-type multianvil apparatus with carbide anvils, American Geophysical Union Fall Meeting 2015, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2015”N12ŒŽ14“ú.
[118] Έä‹M”V, Shi Lanlan, ‹{“‡‰„‹g, ì“Y‹MÍ, Œj’q’j, ’´dƒAƒ“ƒrƒ‹‚ð—p‚¢‚½ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹‘•’u‚É‚æ‚é’´‚ˆ³”­¶, ‘æ56‰ñ‚ˆ³“¢˜_‰ï, L“‡Œ§L“‡ŽsƒAƒXƒe[ƒ‹ƒvƒ‰ƒU, 2015”N11ŒŽ10-12“ú.
[117] Y. Nishihara, T. Ohuchi, T. Kawazoe, G. Maruyama, Y. Higo, K. Funakoshi, and Y. Seto, Lattice preferred orientation of hcp-iron induced by shear deformation, ELSI Workshop; The Earth's Mantle and Core: Structure, Composition, Evolution, ˆ¤•QŒ§¼ŽRŽs, 2015”N11ŒŽ4-7“ú.
[116] J. Buchen, H. Marquardt, T. Kawazoe, A. Kurnosov, and T. Boffa Ballaran, High-pressure single-crystal elasticity of wadsleyite: Constraints on seismic anisotropy in the transition zone, GeoBerlin 2015, ƒhƒCƒc˜A–M‹¤˜a‘ƒxƒ‹ƒŠƒ“Žs, 2015”N10ŒŽ4-7“ú.
[115] K. Schulze, H. Marquardt, T. Kawazoe, M. Koch-Mueller, A. Kurnosov, and T. Boffa Ballaran, The effect of iron content and hydrationon the high-pressure single-crystal elasticity of ringwoodite derived from an internally consistent approach, GeoBerlin 2015, ƒhƒCƒc˜A–M‹¤˜a‘ƒxƒ‹ƒŠƒ“Žs, 2015”N10ŒŽ4-7“ú.
[114] R. Farla, A. Rosenthal, C. Bollinger, S. Petitgirard, T. Kawazoe, J. Guignard, and D. Frost, In situ deformation of eclogite and depleted peridotite compositions at high pressure and temperature, GeoBerlin 2015, ƒhƒCƒc˜A–M‹¤˜a‘ƒxƒ‹ƒŠƒ“Žs, 2015”N10ŒŽ4-7“ú.
[113] ‘å“à’q”Ž, ì“Y‹MÍ, ”ìŒã—SŽi, M‰zŒ«ˆê, —é–غ•v, ‹TŒTì‘ì”ü, “üät“O’j, ƒJƒ“ƒ‰ƒ“΂̓]ˆÊˆÚ“®—¥‘¬Œ^—±ŠE‚·‚ׂèFã•”ƒ}ƒ“ƒgƒ‹‚Ì—¬“®‚ðŽx”z‚·‚é•ÏŒ`ƒƒJƒjƒYƒ€, “ú–{’nŽ¿Šw‰ï‘æ122”NŠwp‘å‰ï, ’·–쌧’·–ìŽsMB‘åŠw’·–ìƒLƒƒƒ“ƒpƒX, 2015”N9ŒŽ11-13“ú.iµ‘Òu‰‰j
[112] J.R. Smyth, T. Kawazoe, and S.D. Jacobsen, Transition metals in the transition zone: Crystal chemistry of Fe, Ti, Cr, V, Co, Ni, and Zn in wadsleyite, Goldschmidt conference 2015, ƒ`ƒFƒR‹¤˜a‘ƒvƒ‰ƒnŽs, 2015”N8ŒŽ16-21“ú.
[111] J. Buchen, H. Marquardt, T. Kawazoe, A. Kurnosov, and T. Boffa Ballaran, Internally consistent high-pressure elasticity of single-crystal (Mg,Fe)2SiO4 wadsleyite, Goldschmidt conference 2015, ƒ`ƒFƒR‹¤˜a‘ƒvƒ‰ƒnŽs, 2015”N8ŒŽ16-21“ú.
[110] K. Schulze, H. Marquardt, T. Kawazoe, M. Koch-Mueller, A. Kurnosov, and T. Boffa Ballaran, Direct quantification of the effects of iron content and hydration on the high-pressure elasticity of single-crystal ringwoodite, Goldschmidt conference 2015, ƒ`ƒFƒR‹¤˜a‘ƒvƒ‰ƒnŽs, 2015”N8ŒŽ16-21“ú.
[109] L. Wang, S. Blaha, Z. Pinter, S. Chariton, R. Farla, T. Kawazoe, N. Miyajima, and T. Katsura, Pressure and temperature dependence of dislocation mobility in the [100](010) and [001](010) slip systems in olivine, 26th General Assembly of the International Union of Geodesy and Geophysics (IUGG), ƒ`ƒFƒR‹¤˜a‘ƒvƒ‰ƒnŽs, 2015”N6ŒŽ22“ú-7ŒŽ2“ú.
[108] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ŠÛŽRŒº‘¾, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, In situ creep strength measurement on ringwoodite up to 1700 K at 17-18 GPa using a deformation-DIA apparatus, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2015”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2015”N5ŒŽ24-28“ú.iµ‘Òu‰‰j
[107] ì“Y‹MÍ, ‹{“‡‰„‹g, Weak-beam dark-field TEM characterization of dislocations in wadsleyite deformed in simple shear at 18 GPa and 1800 K, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2015”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2015”N5ŒŽ24-28“ú.
[106] ‘å“à’q”Ž, ì“Y‹MÍ, ”ìŒã—SŽi, M‰zŒ«ˆê, —é–غ•v, ‹TŒTì‘ì”ü, “üät“O’j, Grain boundary sliding as the major deformation mechanism of olivine in Earthfs upper mantle, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2015”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2015”N5ŒŽ24-28“ú.
[105] R. Farla, A. Rosenthal, S. Petitgirard, C. Bollinger, T. Kawazoe, and D. Frost, In situ deformation of eclogite at high pressure and temperature, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2015”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2015”N5ŒŽ24-28“ú.iµ‘Òu‰‰j
[104] N. Miyajima, and T. Kawazoe, Iron partitioning between ringwoodite lamella and the host wadsleyite in the transformation, 6th Mineral Sciences in the Carpathians Conference, ƒnƒ“ƒKƒŠ[‹¤˜a‘ƒ”ƒFƒXƒvƒŒ[ƒ€Žs, 2015”N5ŒŽ16-19“ú.

y2014”Nz


American Geophysical Union Fall Meeting 2014 ‚É‚Ä
ƒpƒgƒŠƒbƒNEƒR[ƒfƒBƒG‚³‚ñ‚Æ
i2014”N12ŒŽAƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽsj
[103] T. Kawazoe, and N. Miyajima, Weak-Beam Dark-Field TEM Characterization of Dislocations and Slip Systems in Wadsleyite deformed in Simple Shear at Pressure-Temperature Conditions of the Mantle Transition Zone, American Geophysical Union Fall Meeting 2014, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2014”N12ŒŽ15-19“ú.
[102] T. Katsura, L. Wang, S. Blaha, Z. Pinter, S. Chariton, R. Farla, T. Kawazoe, and N. Miyajima, Pressure and temperature dependence of dislocation mobility in the [100](010) and [001](010) slip systems in olivine, American Geophysical Union Fall Meeting 2014, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2014”N12ŒŽ15-19“ú.
[101] J. Chen, M.G. Pamato, T. Inoue, S. Kakizawa, B. Yang, C. Ma, Y. Lin, T. Katsura, T. Kawazoe, and Z. Liu, Effect of pressure on water solubility in aluminous magnesium silicate perovskite, American Geophysical Union Fall Meeting 2014, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2014”N12ŒŽ15-19“ú.
[100] ‘å“à’q”Ž, “¡–ì´Žu, ì“Y‹MÍ, “üät“O’j, ƒƒYƒŒƒAƒCƒgEƒŠƒ“ƒOƒEƒbƒ_ƒCƒg‚ÌŒ‹»•ûˆÊ’èŒü”z—ñ, ‘æ55‰ñ‚ˆ³“¢˜_‰ï, “¿“‡Œ§“¿“‡Žs“¿“‡‘åŠw, 2014”N11ŒŽ22“ú.
[99] ‘å“à’q”Ž, ¼Œ´—V, £ŒË—Y‰î, ì“Y‹MÍ, ¼^”V, ŠÛŽRŒº‘¾, ”ìŒã—SŽi, M‰zŒ«ˆê, —é–غ•v, ‹TŒTì‘ì”ü, “üät“O’j, ƒJƒ“ƒ‰ƒ“΂̌‹»•ûˆÊ’èŒü”z—ñ”­’B‚Ì‚‰·‚ˆ³‰º‚»‚ÌêŠÏŽ@ŽÀŒ±Fã•”ƒ}ƒ“ƒgƒ‹‚Ì’nk”g‘¬“xˆÙ•û«‚Ì‹­“x”­’B, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2014”N‘å‰ï, _“Þ쌧‰¡•lŽsƒpƒVƒtƒBƒR‰¡•l, 2014”N4ŒŽ30“ú.

y2013”Nz



American Geophysical Union Fall Meeting 2013 ‚É‚Ä
V–¼—lj‚ñ‚Æ
i2013”N12ŒŽAƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽsj
[98] T. Kawazoe, Y. Nishihara, T. Ohuchi, G. Maruyama, Y. Higo, K.-i. Funakoshi, and T. Irifune, In Situ Creep Strength Measurements on Ringwoodite at 18 GPa and 1700K Using a Deformation-DIA Apparatus Combined with Synchrotron Radiation, American Geophysical Union Fall Meeting 2013, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2013”N12ŒŽ11“ú.
[97] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, ŠÛŽRŒº‘¾, ”ìŒã—SŽi, M‰zŒ«ˆê, £ŒË—Y‰î, “üät“O’j, hcpFe‚Ì™’’f—U‹NŠiŽq‘I‘ð”zŒü, ‘æ54‰ñ‚ˆ³“¢˜_‰ï, VŠƒŒ§VŠƒŽsŽé냃bƒZ, 2013”N11ŒŽ15“ú.
[96] —L–{ŠxŽj, “üät“O’j, S. Greaux, C. Zhou, V–¼‹œ, ‘å“¡O–¾, ”ìŒã—SŽi, ì“Y‹MÍ, ‚‰·‚ˆ³‰º‚É‚¨‚¯‚éƒAƒ‹ƒ}ƒ“ƒfƒBƒ“ƒK[ƒlƒbƒg‚Ì’e«”g‘ª“x‘ª’è, ‘æ54‰ñ‚ˆ³“¢˜_‰ï, VŠƒŒ§VŠƒŽsŽé냃bƒZ, 2013”N11ŒŽ14“ú.
[95] T. Kawazoe, Y. Nishihara, T. Ohuchi, G. Maruyama, Y. Higo, K. Funakoshi, and T. Irifune, In Situ Stress-Strain Measurements on Ringwoodite at 18 GPa and 1700K Using a Deformation-DIA Apparatus Combined with Synchrotron Radiation, 2013 Workshop of the IUCr Commission on High Pressure "Advances in Static and Dynamic High-Pressure Crystallography", ƒhƒCƒc˜A–M‹¤˜a‘ƒnƒ“ƒuƒ‹ƒNŽsDESY, 2013”N9ŒŽ10“ú.
[94] ‘å“à’q”Ž, ¼Œ´—V, £ŒË—Y‰î, ì“Y‹MÍ, ¼^”V, ŠÛŽRŒº‘¾, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, ƒJƒ“ƒ‰ƒ“΂̌‹»•ûˆÊ’èŒü”z—ñ”­’B‚Ì‚‰·‚ˆ³‰º‚»‚ÌêŠÏŽ@ŽÀŒ±, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2013”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2013”N5ŒŽ23“ú.
[93] ŠÛŽRŒº‘¾, ¼Œ´—V, ¼^”V, ‘å“à’q”Ž, ¼‰eŽq, ì“Y‹MÍ, ‚ˆ³‰º‚É‚¨‚¯‚éƒtƒHƒ‹ƒXƒeƒ‰ƒCƒg”½‰ž‘Ѭ’·ŽÀŒ±, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2013”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2013”N5ŒŽ23“ú.
[92] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, ŠÛŽRŒº‘¾, ”ìŒã—SŽi, M‰zŒ«ˆê, £ŒË—Y‰î, “üät“O’j, ™’’f•ÏŒ`‚É‚æ‚éhcp“S‚ÌŠiŽq‘I‘ð”zŒü, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2013”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2013”N5ŒŽ21“ú.
[91] Y. Nishihara, T. Ohuchi, T. Kawazoe, G. Maruyama, Y. Higo, K.-i. Funakoshi, Y. Seto, and T. Irifune, Lattice preferred orientation of hcp-iron induced by shear deformation, GCOE-TANDEM International Symposium 2013, ˆ¤•QŒ§¼ŽRŽs, 2013”N3ŒŽ5“ú.

y2012”Nz
[90] Y. Nishihara, T. Kawazoe, M. Nishi, T. Ohuchi, Y. Higo, K. Funakoshi, T. Irifune, Strength contrast between majorite and ringwoodite: Implication for the separation of crustal material from slab near 660 km depth, American Geophysical Union Fall Meeting 2012, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2012”N12ŒŽ6“ú.
[89] T. Kawazoe, Y. Nishihara, T. Ohuchi, M. Nishi, G. Maruyama, K. Fujino, Y. Higo, K. Funakoshi, T. Irifune, Creep strength of hydrous wadsleyite: Implication for viscosity at the upper part of the mantle transition zone, American Geophysical Union Fall Meeting 2012, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2012”N12ŒŽ5“ú.
[88] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ŠÛŽRŒº‘¾, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, DIAŒ^•ÏŒ`‘•’u‚Æ•úŽËŒõ‚ð—p‚¢‚½17-18 GPaE1700 K‚É‚¨‚¯‚郊ƒ“ƒOƒEƒbƒ_ƒCƒg‚̃NƒŠ[ƒv‹­“x‘ª’è, ‘æ53‰ñ‚ˆ³“¢˜_‰ï, ‘åã•{–L’†Žs‘åã‘åŠw–L’†ƒLƒƒƒ“ƒpƒX, 2012”N11ŒŽ9“ú.
[87] “üät“O’j, —L–{ŠxŽj, ˆé•”‘¾Žu, V–¼‹œ, ‘å“¡O–¾, ì“Y‹MÍ, ¼Œ´—V, ¼ŽRé³, “§Œõ«‘½Œ‹»ÄŒ‹‘̇¬‚ÌVŽè–@‚Æ‚ˆ³‘Šƒiƒm`ƒ~ƒNƒ‘½Œ‹»‘Ì, ‘æ53‰ñ‚ˆ³“¢˜_‰ï, ‘åã•{–L’†Žs‘åã‘åŠw–L’†ƒLƒƒƒ“ƒpƒX, 2012”N11ŒŽ9“ú.
[86] ì“Y‹MÍ, ‚ˆ³‰º‚É‚¨‚¯‚éŒõŠw“I•¨«‘ª’è‚Ì‚½‚ß‚Ì’´¬Œ^ƒLƒ…[ƒrƒbƒNƒAƒ“ƒrƒ‹‘•’u‚ÌŠJ”­, ‘æ53‰ñ‚ˆ³“¢˜_‰ï, ‘åã•{–L’†Žs‘åã‘åŠw–L’†ƒLƒƒƒ“ƒpƒX, 2012”N11ŒŽ8“ú.
[85] ¼Œ´—V, ì“Y‹MÍ, ¼^”V, ‘å“à’q”Ž, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, ƒŠƒ“ƒOƒEƒbƒ_ƒCƒg-ƒ[ƒWƒƒƒ‰ƒCƒg‚Ì‹­“xƒRƒ“ƒgƒ‰ƒXƒg, ‘æ53‰ñ‚ˆ³“¢˜_‰ï, ‘åã•{–L’†Žs‘åã‘åŠw–L’†ƒLƒƒƒ“ƒpƒX, 2012”N11ŒŽ8“ú.
[84] —L–{ŠxŽj, “üät“O’j, V–¼‹œ, ì“Y‹MÍ, ‘å“¡O–¾, ƒ}ƒ‹ƒ`ƒAƒ“ƒrƒ‹‘•’u‚É‚æ‚铧Œõ«‘½Œ‹»‚´‚­‚ë΂̇¬, ‘æ53‰ñ‚ˆ³“¢˜_‰ï, ‘åã•{–L’†Žs‘åã‘åŠw–L’†ƒLƒƒƒ“ƒpƒX, 2012”N11ŒŽ7“ú.
[83] A. Yamada, N. Nishiyama, T. Kawazoe, T. Inoue, T. Yagi, 6-6-type compression for high-pressure neutron diffraction, IUCr Commission on High Pressure 2012 Meeting "Advances in Crystallography at High Pressures", ˆï錧…ŒËŽs, 2012”N9ŒŽ25“ú.
[82] ¼Œ´—V, ì“Y‹MÍ, ¼^”V, ‘å“à’q”Ž, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, ƒ[ƒWƒƒƒ‰ƒCƒg-ƒŠƒ“ƒOƒEƒbƒ_ƒCƒg‚Ì‘Y«‹­“x·F660km•s˜A‘±‚É‚¨‚¯‚éƒXƒ‰ƒu‚©‚ç‚ÌŠC—m’nŠk‚Ì”—£‚ɂ‚¢‚Ä, “ú–{z•¨‰ÈŠw‰ï2012”N”N‰ï, ‹ž“s•{‹ž“sŽs‹ž“s‘åŠw‹g“cƒLƒƒƒ“ƒpƒX, 2012”N9ŒŽ21“ú.
[81] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ¼^”V, ŠÛŽRŒº‘¾, “¡–ì´Žu, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, ƒEƒHƒYƒŠƒAƒCƒg‚ÌŠÜ…“‚ª‚à‚½‚ç‚·ƒ}ƒ“ƒgƒ‹‘JˆÚ‘wã•”‚É‚¨‚¯‚é”S«—¦‚Ì•s‹ÏŽ¿«, “ú–{z•¨‰ÈŠw‰ï2012”N”N‰ï, ‹ž“s•{‹ž“sŽs‹ž“s‘åŠw‹g“cƒLƒƒƒ“ƒpƒX, 2012”N9ŒŽ20“ú.
[80] T. Irifune, T. Shinmei, T. Arimoto, Y. Zou, C. Zhou, S. Greaux, T. Kawazoe, N. Nishiyama, and H. Ohfuji, Synthesis of High-quality Sintered Bodies of Polycrystalline Minerals at High Pressure for Ultrasonic Sound Velocity Measurements, Asia Oceania Geoscience Society - American Geophysical Union Joint Assembly 2012, ƒVƒ“ƒKƒ|[ƒ‹, 2012”N8ŒŽ16“ú.
[79] T. Ohuchi, Y. Nishihara, T. Kawazoe, D. Spengler, R. Shiraishi, A. Suzuki, T. Kikegawa, and E. Ohtani, Superplasticity in hydrous melt-bearing dunite: Implications for shear localization in Earth's upper mantle, 8th High-Pressure Mineral Physics Seminar, ƒAƒƒŠƒJ‡O‘ƒJƒŠƒtƒHƒ‹ƒjƒABƒ^ƒzŒÎ, 2012”N7ŒŽ10“ú.
[78] ¼Œ´—V, ì“Y‹MÍ, ¼^”V, ‘å“à’q”Ž, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, ƒ[ƒWƒƒƒ‰ƒCƒg-ƒŠƒ“ƒOƒEƒbƒ_ƒCƒg‚Ì‘Y«‹­“x·F660km•s˜A‘±‚É‚¨‚¯‚é’¾‚Ýž‚ÞƒXƒ‰ƒu‚©‚ç‚ÌŠC—m’nŠk¬•ª‚Ì”—£‚ɂ‚¢‚Ä, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2012”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2012”N5ŒŽ22“ú.
[77] ‘å“à’q”Ž, ¼Œ´—V, ì“Y‹MÍ, ƒVƒ…ƒyƒ“ƒOƒ‰[ƒfƒBƒ‹ƒN, ”’Ηß, —é–غ•v, ‹TŒTì‘ì”ü, ‘å’J‰hŽ¡, ŠÜ…ƒƒ‹ƒg‚ðŠÜ‚Þƒ_ƒiƒCƒg‚Ì’´‘Y«Fã•”ƒ}ƒ“ƒgƒ‹‚É‚¨‚¯‚邹‚ñ’fW’†, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2012”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2012”N5ŒŽ22“ú.
[76] ì“Y‹MÍ, ’n‹…[•”•¨Ž¿‚Ì‚ˆ³‰º‚É‚¨‚¯‚éŒõŠw‘ª’è‚Ì‚½‚ß‚Ì’´¬Œ^ƒLƒ…[ƒrƒbƒNƒAƒ“ƒrƒ‹‘•’u‚ÌŠJ”­, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2012”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2012”N5ŒŽ20“ú.
[75] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ¼^”V, “¡–ì´Žu, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, 410-km•s˜A‘±–Ê‹ß–T‚Ì”S«—¦ƒ‚ƒfƒ‹FŽÀŒ±z•¨Šw“IƒAƒvƒ[ƒ`, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2012”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2012”N5ŒŽ20“ú.

y2011”Nz
 



“¹ŒãŒö‰€‚É‚Ä
i2011”N3ŒŽAˆ¤•QŒ§¼ŽRŽsj
[74] L.M. Miyagi, G. Amulele, J. Ando, J.W. Hustoft, T. Irifune, S. Karato, T. Kawazoe, Y. Nishihara, Y. Xu, D. Yamazaki, Development of a rotational Drickamer apparatus: A progress report, American Geophysical Union Fall Meeting 2011, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2011”N12ŒŽ9“ú.
[73] T. Kawazoe, Y. Nishihara, T. Ohuchi, M. Nishi, N. Nishiyama, Y. Higo, K. Funakoshi, T. Irifune, In situ stress-strain measurements in a deformation-DIA apparatus at P-T conditions of the upper part of the mantle transition zone, American Geophysical Union Fall Meeting 2011, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2011”N12ŒŽ6“ú.
[72] Y. Nishihara, T. Ohuchi, T. Kawazoe, D. Spengler, M. Tasaka, T. Hiraga, T. Kikegawa, A. Suzuki, and E. Ohtani, Effect of pressure on rheology of fine-grained forsterite aggregate, American Geophysical Union Fall Meeting 2011, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2011”N12ŒŽ5“ú.
[71] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ¼^”V, ¼ŽRé³, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, DIAŒ^•ÏŒ`‘•’u‚Æ•úŽËŒõ‚ð—p‚¢‚½ƒNƒŠ[ƒv‹­“x‘ª’èðŒ‚Ì15 GPaE1700 K‚Ü‚Å‚ÌŠg‘å, ‘æ52‰ñ‚ˆ³“¢˜_‰ï, ‰«“ꌧ¼Œ´’¬‰«“êƒLƒŠƒXƒg‹³Šw‰@, 2011”N11ŒŽ11“ú.
[70] ‘å“à’q”Ž, ì“Y‹MÍ, ¼Œ´—V, “üät“O’j, ƒAƒZƒmƒXƒtƒFƒAðŒ‰º‚É‚¨‚¯‚é‚©‚ñ‚ç‚ñ΂̌‹»•ûˆÊ’èŒü”z—ñ‚É‚¨‚¯‚é…‚ÌŒø‰Ê, ‘æ52‰ñ‚ˆ³“¢˜_‰ï, ‰«“ꌧ¼Œ´’¬‰«“êƒLƒŠƒXƒg‹³Šw‰@, 2011”N11ŒŽ11“ú.
[69] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, S. Dirk, “cã”üŽ÷, •½‰êŠx•F, ‹TŒTì‘ì”ü, —é–غ•v, ‘å’J‰hŽ¡, ã•”ƒ}ƒ“ƒgƒ‹[•”‚Å‚ÌŽx”z“I•ÏŒ`‹@\, ‘æ52‰ñ‚ˆ³“¢˜_‰ï, ‰«“ꌧ¼Œ´’¬‰«“êƒLƒŠƒXƒg‹³Šw‰@, 2011”N11ŒŽ11“ú.
[68] ‰ºh², ŽRè‘å•ã, –F–ì‹É, š –{Œ’L, ¼Œ´—V, ì“Y‹MÍ, ‘å“à’q”Ž, ¼^”V, ”ìŒã—SŽi, M‰zŒ«ˆê, ‚ˆ³‚‰·•ÏŒ`ê‚ł̃}ƒ“ƒgƒ‹z•¨‚̃‰ƒEƒGƒXƒ|ƒbƒgˆÚ“®‚»‚ÌêŠÏŽ@‚É‚æ‚é‚·‚ׂèŒn‚ÌŒˆ’è, ‘æ52‰ñ‚ˆ³“¢˜_‰ï, ‰«“ꌧ¼Œ´’¬‰«“êƒLƒŠƒXƒg‹³Šw‰@, 2011”N11ŒŽ9“ú.
[67] T. Kawazoe, In situ stress-strain measurements in a deformation-DIA apparatus at P-T conditions of the upper part of the mantle transition zone, GL-GRC Inter-Institution Science Symposium, ƒAƒƒŠƒJ‡O‘ƒƒVƒ“ƒgƒ“D.C., 2011”N9ŒŽ19“ú.
[66] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ¼^”V, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, ƒ}ƒ“ƒgƒ‹‘JˆÚ‘w‰·“xˆ³—ÍðŒ‰º‚Å‚ÌŠÜ…ƒEƒHƒYƒŠƒAƒCƒg‚̃NƒŠ[ƒv‹­“x•úŽËŒõ‚»‚Ìꑪ’èŽÀŒ±, “ú–{’nŽ¿Šw‰ï‘æ118”NŠwp‘å‰ïE“ú–{z•¨‰ÈŠw‰ï2011”N”N‰ï‡“¯Šwp‘å‰ï, ˆï錧…ŒËŽsˆïé‘åŠw, 2011”N9ŒŽ10“ú.
[65] ‘å“à’q”Ž, ¼Œ´—V, ì“Y‹MÍ, D. Spengler, ”’Ηß, —é–غ•v, ‘å’J‰hŽ¡, ‹TŒTì‘ì”ü, ‚©‚ñ‚ç‚ñŠâ‚Ì—¬“®‹­“x‚É‚¨‚¯‚éŠÜ…ƒƒ‹ƒg‚ÌŒø‰Ê, “ú–{’nŽ¿Šw‰ï‘æ118”NŠwp‘å‰ïE“ú–{z•¨‰ÈŠw‰ï2011”N”N‰ï‡“¯Šwp‘å‰ï, ˆï錧…ŒËŽsˆïé‘åŠw, 2011”N9ŒŽ10“ú.
[64] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, D. Spengler, “cã”üŽ÷, •½‰êŠx•F, ‹TŒTì‘ì”ü, —é–غ•v, ‘å’J‰hŽ¡, ã•”ƒ}ƒ“ƒgƒ‹[•”‚ł̃Jƒ“ƒ‰ƒ“΂̃ŒƒIƒƒW[, “ú–{’nŽ¿Šw‰ï‘æ118”NŠwp‘å‰ïE“ú–{z•¨‰ÈŠw‰ï2011”N”N‰ï‡“¯Šwp‘å‰ï, ˆï錧…ŒËŽsˆïé‘åŠw, 2011”N9ŒŽ10“ú.
[63] ŽR“c–¾Š°, ì“Y‹MÍ, ¼ŽRé³, ˆäã“O, ”ª–ØŒ’•F, ‚ˆ³’†«Žq‰ñÜ‚ÉŒü‚¯‚½‘å—e—Ê6-6Œ^‰Áˆ³•ûŽ®‚ÌŠJ”­, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2011”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2011”N5ŒŽ24“ú.
[62] ‘å“à’q”Ž, ì“Y‹MÍ, ¼Œ´—V, “üät“O’j, ƒAƒZƒmƒXƒtƒFƒAðŒ‰º‚Å‚Ì‚©‚ñ‚ç‚ñ΂̌‹»•ûˆÊ’èŒü”z—ñ‚É‚¨‚¯‚é…‚ÌŒø‰Ê, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2011”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2011”N5ŒŽ24“ú.
[61] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, D. Spengler, “cã”üŽ÷, •½‰êŠx•F, ‹TŒTì‘ì”ü, —é–غ•v, ‘å’J‰hŽ¡, ã•”ƒ}ƒ“ƒgƒ‹[•”‚ł̃Jƒ“ƒ‰ƒ“΂̃ŒƒIƒƒW[, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2011”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2011”N5ŒŽ24“ú.
[60] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ¼ŽRé³, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, DIAŒ^•ÏŒ`‘•’u‚ð—p‚¢‚½ƒ}ƒ“ƒgƒ‹‘JˆÚ‘w‰·“xˆ³—ÍðŒ‰º‚ł̃EƒHƒYƒŠƒAƒCƒg‚̃NƒŠ[ƒv‹­“x‚»‚Ìꑪ’è, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2011”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2011”N5ŒŽ23“ú.
[59] ì“Y‹MÍ, ¼Œ´—V, ‘å“à’q”Ž, ¼ŽRé³, ”ìŒã—SŽi, M‰zŒ«ˆê, “üät“O’j, •úŽËŒõ’PFXü‚ÆD-DIAŒ^‚ˆ³•ÏŒ`‘•’u‚ð—p‚¢‚½•ÏŒ`ŽÀŒ±E‰ž—Í‘ª’è‚É‚¨‚¯‚鉷“xˆ³—ÍðŒ‚Ì15 GPaE1700 K‚Ü‚Å‚ÌŠg‘å, SPring-8—˜—pŽÒ§’k‰ï‚ˆ³•¨Ž¿‰ÈŠwŒ¤‹†‰ïE’n‹…˜f¯‰ÈŠwŒ¤‹†‰ï2011”N“x‡“¯Œ¤‹†‰ï‡, •ºŒÉŒ§²—p’¬, 2011”N1ŒŽ5“ú.

y2010”Nz
[58] Y. Nishihara, T. Ohuchi, T. Kawazoe, D. Spengler, M. Tasaka, T. Hiraga, T. Kikegawa, A. Suzuki, and E. Ohtani, Rheology of fine-grained forsterite aggregate under deep upper mantle conditions, American Geophysical Union Fall Meeting 2010, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2010”N12ŒŽ16“ú.
[57] T. Ohuchi, T. Kawazoe, Y. Nishihara, N. Nishiyama, and T. Irifune, High pressure and temperature fabric transitions in olivine and variations in upper mantle seismic anisotropy, American Geophysical Union Fall Meeting 2010, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2010”N12ŒŽ15“ú.
[56] T. Kawazoe, T. Ohuchi, Y. Nishihara, N. Nishiyama, and T. Irifune, Plastic Deformation of Wadsleyite and Seismic Anisotropy in the Mantle Transition Zone, American Geophysical Union Fall Meeting 2010, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2010”N12ŒŽ13“ú.
[55] T. Kawazoe, T. Ohuchi, Y. Nishihara, N. Nishiyama, and T. Irifune, Deformation experiments of wadsleyite and ringwoodite at P-T conditions of the mantle transition zone using a D-DIA apparatus, TANDEM Symposium on Deep Earth Mineralogy 2010, ’†‰Øl–¯‹¤˜a‘•Š¿Žs, 2010”N11ŒŽ6“ú.
[54] T. Ohuchi, T. Kawazoe, Y. Nishihara, N. Nishiyama, and T. Irifune, Simple-shear deformation of olivine using a deformation-DIA apparatus: implications for upper mantle seismic anisotropy, TANDEM Symposium on Deep Earth Mineralogy 2010, ’†‰Øl–¯‹¤˜a‘•Š¿Žs, 2010”N11ŒŽ6“ú.
[53] ì“Y‹MÍ, ‘å“à’q”Ž, ¼Œ´—V, ¼ŽRé³, “üät“O’j, DIAŒ^•ÏŒ`‘•’u‚ð—p‚¢‚½ƒEƒHƒYƒŠƒAƒCƒg‚Ì‚¹‚ñ’f•ÏŒ`ŽÀŒ±, ‘æ51‰ñ‚ˆ³“¢˜_‰ï, ‹{錧å‘äŽsíЕœ‹»‹L”OŠÙ, 2010”N10ŒŽ20“ú.
[52] ¼Œ´—V, ‘å“à’q”Ž, ì“Y‹MÍ, D. Spengler, “cã”üŽ÷, •½‰êŠx•F, ‹TŒTì‘ì”ü, —é–غ•v, ‘å’J‰hŽ¡, ã•”ƒ}ƒ“ƒgƒ‹[•”‚ł̃Jƒ“ƒ‰ƒ“΂̃ŒƒIƒƒW[, ‘æ51‰ñ‚ˆ³“¢˜_‰ï, ‹{錧å‘äŽsíЕœ‹»‹L”OŠÙ, 2010”N10ŒŽ20“ú.
[51] ¼ŽRé³, “üät“O’j, ’O‰ºŒc”Í, ˜a“cŒõ•½, ¼Œ´—V, ì“Y‹MÍ, ‘å“à’q”Ž, ‹{èä—T, “c“n³Žj, “c”¦˜_Žj, M‰zŒ«ˆê, ”ìŒã—SŽi, ‘å—e—ÊDDIA‘•’u "MADONNA" ‚ÌŠT—v, ‘æ51‰ñ‚ˆ³“¢˜_‰ï, ‹{錧å‘äŽsíЕœ‹»‹L”OŠÙ, 2010”N10ŒŽ.
[50] ‘å“à’q”Ž, ì“Y‹MÍ, ¼Œ´—V, ¼ŽRé³, “üät“O’j, ‚©‚ñ‚ç‚ñÎŒ‹»•ûˆÊ’èŒü”z—ñ‚É‚¨‚¯‚鈳—ÍE‰·“x‚ÌŒø‰Ê, “ú–{z•¨‰ÈŠw‰ï2010”N”N‰ï, “‡ªŒ§¼]Žs, 2010”N9ŒŽ25“ú.
[49] ì“Y‹MÍ, ¼ŽRé³, ¼Œ´—V, ‘å“à’q”Ž, “üät“O’j, DIAŒ^•ÏŒ`‘•’u‚ð—p‚¢‚½ƒ}ƒ“ƒgƒ‹‘JˆÚ‘w‰·“xˆ³—ÍðŒ‰º‚ł̃EƒHƒYƒŠƒAƒCƒgEƒŠƒ“ƒOƒEƒbƒ_ƒCƒg‚Ì•ÏŒ`ŽÀŒ±, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2010”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2010”N5ŒŽ27“ú.
[48] ‘å“à’q”Ž, ì“Y‹MÍ, ¼Œ´—V, ¼ŽRé³, “üät“O’j, ‚©‚ñ‚ç‚ñ΂̊iŽq’èŒü”z—ñ‚É‚¨‚¯‚鈳—ÍE…‚ÌŒø‰Ê, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2010”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2010”N5ŒŽ27“ú.
[47] ì“Y‹MÍ, ŽR“c–¾Š°, ¼ŽRé³, ˆäã“O, ”ª–ØŒ’•F, “üät“O’j, J-PARC‚ł̃Lƒ…[ƒrƒbƒNƒAƒ“ƒrƒ‹‘•’u‚ð—p‚¢‚½‚‰·‚ˆ³’†«ŽqŽÀŒ±—p‚ÌŽÀŒ±ƒZƒ‹ŠJ”­, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2010”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2010”N5ŒŽ23“ú.
[46] ˆäã“O, ŽR“c–¾Š°, ì“Y‹MÍ, ¼ŽRé³, C. Yang, ‘]‰ä•”ºl, 6-6‰Áˆ³•ûŽ®‚ð—p‚¢‚½•ûŽËŒõ‚wü‚»‚ÌêŠÏŽ@ŽÀŒ±‚Æ’†«ŽqŽÀŒ±‚Ö‚Ì—L—p«, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2010”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2010”N5ŒŽ23“ú.
[45] ŽR“c–¾Š°, ˆäã“O, ƒ„ƒ“ƒrƒ“ƒƒ“, ƒ`ƒƒƒ“ƒˆƒ“ƒp[ƒN, ƒS[ƒCƒ“ƒVƒFƒ“, ì“Y‹MÍ, ¼ŽRé³, ‘å—e—ʃvƒŒƒX‚ðŽg—p‚µ‚½Œ]Ž_‰–ƒƒ‹ƒg‚Ì‚ˆ³Xü‰ñÜŽÀŒ±, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2010”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2010”N5ŒŽ23“ú.
[44] ì“Y‹MÍ, ¼ŽRé³, ¼Œ´—V, ŽR“c–¾Š°, “üät“O’j, ˆäã“O, 6-6Ž®‰Áˆ³•ûŽ®‚É‚æ‚éƒLƒ…[ƒrƒbƒNƒAƒ“ƒrƒ‹‘•’u‚Ì”­¶ˆ³—Í‚ÌXV‚Æ•úŽËŒõŽÀŒ±‚ւ̉ž—p, SPring-8—˜—pŽÒ§’k‰ï‚ˆ³•¨«‰ÈŠwŒ¤‹†‰ïE’n‹…˜f¯‰ÈŠwŒ¤‹†‰ï2009”N“x‡“¯Œ¤‹†‰ï‡, •ºŒÉŒ§²—pŒS²—p’¬SPring-8, 2010”N1ŒŽ.

y2009”Nz
[43] J. Hustoft, T. Kawazoe, S.Karato, J. Ando, Z. Jing, K. Otsuka, G. Amulele, and Z.Du, Shear Deformation of Wadsleyite in the Rotational Drikamer Apparatus, American Geophysical Union Fall Meeting 2009, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2009”N12ŒŽ.
[42] T. Kawazoe, N. Nishiyama, Y. Nishihara, and T. Irifune, Deformation experiment at P-T conditions of the mantle transition zone using D-DIA apparatus, American Geophysical Union Fall Meeting 2009, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2009”N12ŒŽ.
[41] T. Kawazoe, N. Nishiyama, Y. Nishihara, and T. Irifune, Technical Development for Deformation Experiments at P-T Conditions of the Mantle Transition Zone, Experimental studies on Rheology of Earth's deep interior, ‹ãB‘åŠw, 2009”N11ŒŽ.
[40] ì“Y‹MÍ, ¼ŽRé³, ¼Œ´—V, “üät“O’j, DIAŒ^•ÏŒ`‘•’u‚É‚æ‚éƒ}ƒ“ƒgƒ‹‘JˆÚ‘wðŒ‰º‚ł̃EƒHƒYƒŠƒAƒCƒg‚Ì—\”õ“I•ÏŒ`ŽÀŒ±, “ú–{z•¨‰ÈŠw‰ï2009”N”N‰ï, –kŠC“¹ŽD–yŽs–kŠC“¹‘åŠw, 2009”N9ŒŽ.
[39] ¼Œ´—V, M‰zŒ«ˆê, ”ìŒã—SŽi, ’Ò–ì“TG, ì“Y‹MÍ, ‹v•Û—F–¾, ‰ºh², Ž›è‰p‹I, ¼ŽRé³, Stress relaxation test of olivine under Earthfs deep upper mantle conditions, ‘æ50‰ñ‚ˆ³“¢˜_‰ï-22nd AIRAPT, “Œ‹ž“s`‹æ‚¨‘äê“Œ‹ž‘ی𗬊Ù, 2009”N7ŒŽ.
[38] T. Kawazoe, and S. Karato, Shear Deformation Experiment up to 18 GPa and 2100 K using a Rotational Drickamer Apparatus (RDA), ‘æ50‰ñ‚ˆ³“¢˜_‰ï-22nd AIRAPT, “Œ‹ž“s`‹æ‚¨‘äê“Œ‹ž‘ی𗬊Ù, 2009”N7ŒŽ.
[37] T. Kawazoe, N. Nishiyama, Y. Nishihara, and T. Irifune, Preliminary Experiments using the Deformation-DIA Apparatus gMADONNAh, GRC-BGI Workshop on Deep Earth Mineralogy, ƒhƒCƒc˜A–M‹¤˜a‘ƒoƒCƒƒCƒgŽs, 2009”N6ŒŽ.
[36] ¼Œ´—V, M‰zŒ«ˆê, ”ìŒã—SŽi, ’Ò–ì“TG, ì“Y‹MÍ, ‹v•Û—F–¾, ‰ºh², Ž›è‰p‹I, ¼ŽRé³, Stress relaxation test of olivine under Earthfs deep upper mantle conditions, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2009”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2009”N5ŒŽ.
[35] ì“Y‹MÍ, ¼ŽRé³, ¼Œ´—V, “üät“O’j, Preliminary Experiments using the Deformation-DIA Apparatus gMADONNAh, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2009”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2009”N5ŒŽ.
[34] Y. Nishihara, K. Funakoshi, Y. Higo, N. Tsujino, T. Kawazoe, T. Kubo, A. Shimojuku, H. Terasaki, and N. Nishiyama, High pressure stress measurement using Kawai-type multi-anvil apparatus combined with synchrotron radiation and its application to stress relaxation test of olivine under Earth's deep upper mantle conditions, Final SSP International Symposium on "DEEP SLAB and MANTLE DYNAMICS", 2009”N2ŒŽ.

y2008”Nz
[33] T. Kawazoe, S.-i. Karato, J.-i. Ando, Z. Jing, K. Otsuka, and J.W. Hustoft, Deformation of dry Wadsleyite up to 18 GPa and 2100 K Using a Rotational Drickamer Apparatus, American Geophysical Union Fall Meeting 2008, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2008”N12ŒŽ.
[32] “‚ŒËrˆê˜Y, ì“Y‹MÍ, ‚‰·C‚ˆ³‰º‚Å‚Ìz•¨‚Ì‘Y«—¬“®‚ÌŽÀŒ±“IŒ¤‹†, “ú–{’n‹…˜f¯‰ÈŠw˜A‡2008”N‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2008”N5ŒŽ.

y2007”Nz
[31] T. Kawazoe, K. Otsuka, D. Tinker, S. Karato, Y. Nishihara, Z. Jing, and M. Mookherjee, Deformation of dry Olivine up to 11 GPa and 2100 K Using a Rotational Drickamer Apparatus, American Geophysical Union Fall Meeting 2007, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2007”N12ŒŽ.
[30] T. Kawazoe, and E. Ohtani, Effects of Oxygen Fugacity and Temperature on Partitioning of Ni and Co Between Liquid Metal, Magnesium Silicate Perovskite and Magnesiowustite, American Geophysical Union Fall Meeting 2007, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2007”N12ŒŽ.
[29] ì“Y‹MÍ, ‘å’˘a•F, D. Tinker, “‚ŒËrˆê˜Y, Z. Jing, M. Mookherjee, ¼Œ´—V, ‚‰·‚ˆ³‰º‚É‚¨‚¯‚éƒJƒ“ƒ‰ƒ“΂̕ό`“Á«, ‘æ48‰ñ‚ˆ³“¢˜_‰ï, ’¹ŽæŒ§‘q‹gŽs‘q‹gƒp[ƒNƒXƒNƒGƒA, 2007”N11ŒŽ.
[28] T. Kawazoe, D. Tinker, Y. Nishihara, S. Karato, Z. Jing, M. Mookherjee, and K. Otsuka, Deformation of Olivine Under High Pressure and High Temperature, 7th High-Pressure Mineral Physics Seminar, ‹{錧¼“‡’¬ƒzƒeƒ‹‘åŠÏ‘‘, 2007”N5ŒŽ.
[27] T. Kawazoe, D. Tinker, K. Otuka, Y. Nishihara, S. Karato, Z. Jing, and M. Mookherjee, Deformation of olivine under deep mantle condition using a Rotational Drickamer Apparatus and synchrotron radiation, Study of Matter at Extreme Conditions 2007, ƒAƒƒŠƒJ‡O‘ƒ}ƒCƒAƒ~ƒr[ƒ`Žs, 2007”N4ŒŽ.

y2006”Nz
[26] T. Kawazoe, D. Tinker, S. Karato, Z. Jing, and M. Mookherjee, Deformation of Olivine Under High Pressure and High Temperature Using a Rotational Drickamer Apparatus, American Geophysical Union Fall Meeting 2006, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2006”N12ŒŽ.
[25] ì“Y‹MÍ, ‘å’J‰hŽ¡, Ž›è‰p‹I, —é–غ•v, ’O‰ºŒc”Í, M‰zŒ«ˆê, 23-34 GPa‚É‚¨‚¯‚éFe-FeS-FeOŒn‚Ì‹¤—Z‰·“x‚ƃTƒuƒ\ƒŠƒ_ƒX‘Š, ‘æ47‰ñ‚ˆ³“¢˜_‰ï, ŒF–{Œ§ŒF–{ŽsŽY‹Æ•¶‰»‰ïŠÙ, 2006”N11ŒŽ.
[24] T. Kawazoe, D. Tinker, and S. Karato, Deformation Experiments of Olivine using Rotational Drickamer Apparatus (RDA), MSA Short Course: Water in Nominally Anhydrous Minerals, ƒCƒ^ƒŠƒA‹¤˜a‘ƒ”ƒFƒ‹ƒo[ƒjƒA, 2006”N10ŒŽ.
[23] E. Ohtani, T. Sakai, T. Kawazoe, and T. Kondo, Metal-silicate fractionation in the deep magma ocean and light elements in the core, 16th Annual V.M. Goldschmidt Conference 2006, ƒI[ƒXƒgƒ‰ƒŠƒAƒƒ‹ƒ{ƒ‹ƒ“Žs, 2006”N8ŒŽ.
[22] T. Kawazoe, and E. Ohtani, In situ X-ray observation of eutectic temperatures and subsolidus phases in Fe-FeS-FeO system at 23-34 GPa, 19th General Meeting of the International Mineralogical Association, •ºŒÉŒ§_ŒËŽs_ŒË‘Û‰ï‹cê, 2006”N7ŒŽ.

y2005”Nz
[21] ì“Y‹MÍ, ‘å’J‰hŽ¡, ²–숟¹”ü, Ž›è‰p‹I, K. Litasov, —é–غ•v, ’O‰ºŒc”Í, M‰zŒ«ˆê, Xü‚»‚ÌêŠÏŽ@‚É‚æ‚邈³‰º‚Å‚ÌFe-FeSŒn‚Ì‹¤—Z‰·“x‚ƃTƒuƒ\ƒŠƒ_ƒX‘Š‚ÌŒˆ’è, “ú–{ŠâÎz•¨z°Šw‰ï2005”NŠwpu‰‰‰ï, ˆ¤•QŒ§¼ŽRŽsˆ¤•Q‘åŠw, 2005”N9ŒŽ.
[20] T. Kawazoe, and E. Ohtani, Reaction between liquid iron and magnesium silicate perovskite and solubilities of silicon and oxygen in the liquid iron, Spatial and Temporal Fluctuations in the Solid Earth - Clues to the Future of Our Planet -, ‹{錧å‘äŽs“Œ–k‘åŠw, 2005”N7ŒŽ.
[19] T. Kawazoe, and E. Ohtani, Solubility of silicon and oxygen in liquid iron coexisting with (Mg,Fe)SiO3-perovskite and implications for core formation, International Conference on High Pressure Science and Technology, ƒhƒCƒc˜A–M‹¤˜a‘ƒJ[ƒ‹ƒXƒ‹[ƒGŽs, 2005”N6ŒŽ.
[18] T. Kawazoe, and E. Ohtani, Partitioning of Ni and Co between liquid metal and lower mantle minerals: Implication for a core formation of the Earth, ’n‹…˜f¯‰ÈŠwŠÖ˜AŠw‰ï2005”N‡“¯‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2005”N5ŒŽ.
[17] T. Kawazoe, and E. Ohtani, Silicon and oxygen solubility in liquid iron coexisting with (Mg,Fe)SiO3-perovskite, 21COE workshop on the Earth's core, “Œ‹ž“s–Ú•‹æ‘剪ŽR“Œ‹žH‹Æ‘åŠw, 2005”N3ŒŽ.

y2004”Nz
[16] T. Kawazoe, and E. Ohtani, Reaction between liquid iron and Mg-perovskite and solubility of silicon and oxygen in liquid iron, American Geophysical Union Fall Meeting 2004, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2004”N12ŒŽ.
[15] T. Kawazoe, and E. Ohtani, Solubility of Si and O in liquid iron coexisting magnesium silicate perovskite, 2nd International Workshop on WATER DYNAMICS, ‹{錧å‘äŽs, 2004”N11ŒŽ.
[14] ì“Y‹MÍ, ‘å’J‰hŽ¡, Mg-perovskite‚Æ‹¤‘¶‚·‚é—o—Z“S‚É‚¨‚¯‚éŒ]‘fEŽ_‘f—n‰ð“x‚̉·“xEŽ_‘f•ªˆ³ˆË‘¶«, ‘æ45‰ñ‚ˆ³“¢˜_‰ï, Ž ‰êŒ§‘’ÃŽs—§–½ŠÙ‘åŠw‚т킱E‚­‚³‚ƒLƒƒƒ“ƒpƒX, 2004”N10ŒŽ.
[13] ì“Y‹MÍ, ‘å’J‰hŽ¡, —o—Z‹à‘®“S‚ÆMg-ƒyƒƒ”ƒXƒJƒCƒgAƒ}ƒOƒlƒVƒIƒ”ƒXƒ^ƒCƒgŠÔ‚ÌFeANiACo•ª”z‚ƃ}ƒOƒ}ƒI[ƒVƒƒƒ“‚Ì[‚³, “ú–{ŠâÎz•¨z°Šw‰ï2004”NŠwpu‰‰‰ï, ‰ªŽRŒ§‰ªŽRŽs‰ªŽR‘åŠw, 2004”N9ŒŽ.
[12] ì“Y‹MÍ, ‘å’J‰hŽ¡, —o—Z‹à‘®“S‚ÆMg-perovskite‚Ì”½‰ž‚Æ’n‹…’†SŠj‚É‚¨‚¯‚éŒyŒ³‘f, ’n‹…˜f¯‰ÈŠwŠÖ˜AŠw‰ï2004”N‡“¯‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2004”N5ŒŽ.
[11] T. Kawazoe, and E. Ohtani, Reaction between liquid iron and Mg-perovskite: Implications for core formation and light elements in the core, –k•ûŒ—ŠÂ‹«•Ï“®Œ¤‹†Œv‰æ‚ÉŠÖ‚·‚é‘ÛƒŒƒrƒ…[‰ï‹c, ‹{錧å‘äŽs, 2004”N3ŒŽ.

y2003”Nz
[10] T. Kawazoe, and E. Ohtani, Reaction Between Liquid Iron and Mg-perovskite, American Geophysical Union Fall Meeting 2003, ƒAƒƒŠƒJ‡O‘ƒTƒ“ƒtƒ‰ƒ“ƒVƒXƒRŽs, 2003”N12ŒŽ.
[9] ì“Y‹MÍ, ‘å’J‰hŽ¡, —o—Z‹à‘®“S‚ÆMg-perovskite‚Ì”½‰ž, ‘æ44‰ñ‚ˆ³“¢˜_‰ï, _“Þ쌧‰¡•lŽsŒc‰ž‹`m‘åŠw—HŠw•”, 2003”N11ŒŽ.
[8] ì“Y‹MÍ, ‘å’J‰hŽ¡, —o—Z‹à‘®“S‚ÆMg-ƒyƒƒ”ƒXƒJƒCƒgAƒ}ƒOƒlƒVƒIƒ”ƒXƒ^ƒCƒgŠÔ‚ÌFeANiACo•ª”z, “ú–{ŠâÎz•¨z°Šw‰ï2003”NŠwpu‰‰‰ï, ‹{錧å‘äŽså‘äŽsíЕœ‹»‹L”OŠÙ, 2003”N9ŒŽ.
[7] E. Ohtani, T. Kawazoe, Y. Kanbe, and K. Heshiki, Reaction and separation of metal and silicate in the early Earth, and light elements in the core, 13th Annual V.M. Goldshmidt Conference 2003, ‰ªŽRŒ§‘q•~Žs‚­‚炵‚«ì—z‘åŠw, 2003”N9ŒŽ.
[6] T. Kawazoe, and E. Ohtani, Reaction between Liquid Iron and Mg-Perovskite, International Workshop on High-pressure Mineral Physics and Geochemistry, •ºŒÉŒ§²—pŒS²—p’¬SPring-8, 2003”N9ŒŽ.
[5] ì“Y‹MÍ, ‘å’J‰hŽ¡, —o—Z‹à‘®“S‚Ɖº•”ƒ}ƒ“ƒgƒ‹z•¨ŠÔ‚ÌFeANiACo•ª”z‚ÆSi‚Ì‹““®, ’n‹…˜f¯‰ÈŠwŠÖ˜AŠw‰ï2003”N‡“¯‘å‰ï, ç—tŒ§ç—tŽs–‹’£ƒƒbƒZ, 2003”N5ŒŽ.
[4] ì“Y‹MÍ, ‘å’J‰hŽ¡, —o—Z‹à‘®“S‚Ɖº•”ƒ}ƒ“ƒgƒ‹z•¨ŠÔ‚ÌFeANiACo•ª”z‚ÆSi‚Ì‹““®, “Á’è—̈挤‹†iBju’´‚ˆ³’n‹…‰ÈŠwv•½¬14”N“xƒVƒ“ƒ|ƒWƒEƒ€, ‹{錧å‘äŽs“Œ–k‘åŠw, 2003”N3ŒŽ.

y2002”Nz
[3] ì“Y‹MÍ, ‘å’J‰hŽ¡, ²“¡m, ‹v•Û—F–¾, ‹ß“¡’‰, ‚‰·‚ˆ³‰º‚É‚¨‚¯‚é‹à‘®“S|‰º•”ƒ}ƒ“ƒgƒ‹\¬z•¨ŠÔ‚Ìe“SŒ³‘f•ª”z, ‘æ43‰ñ‚ˆ³“¢˜_‰ï, ˆ¤•QŒ§¼ŽRŽsˆ¤•QŒ§Œ§–¯•¶‰»‰ïŠÙ, 2002”N11ŒŽ.

y2001”Nz
[2] ì“Y‹MÍ, ‘å’J‰hŽ¡, ‚ˆ³‰º‚É‚¨‚¯‚é‹à‘®“S‚ÆŒ]Ž_‰–ƒƒ‹ƒg‚ÌŠÔ‚ÌGaAGe•ª”zŽÀŒ±, ’n‹…˜f¯‰ÈŠwŠÖ˜AŠw‰ï2001”N‡“¯‘å‰ï, “Œ‹ž“sa’J‹æ‘—§ƒIƒŠƒ“ƒsƒbƒN‹L”O­”N‘‡ƒZƒ“ƒ^[, 2001”N6ŒŽ.
[1] ì“Y‹MÍ, ‘å’J‰hŽ¡, ‚ˆ³‰º‚É‚¨‚¯‚é‹à‘®“S‚ÆŒ]Ž_‰–ƒƒ‹ƒg‚ÌŠÔ‚Ìe“SŒ³‘f•ª”zŽÀŒ±, “Á’è—̈æƒVƒ“ƒ|ƒWƒEƒ€, ‹{錧å‘äŽs“Œ–k‘åŠw, 2001”N2ŒŽ.