Papers (refereed) :
**Graduate advisee, *Undegraduate advisee
**Shibuya, F. and I. Sumita, 2022, Experiments on seepage-triggered cliff landslides using cohesive wet sand, Prog. Earth Planet. Sci., 9:43 PDF (open access)
**Hashimoto, K. and I. Sumita, 2021, Excitation of airwaves by bubble bursting in suspensions : regime transitions and implications for basaltic volcanic eruptions, Earth, Planets and Space, 73, 143 PDF (open access)
Patrick, M. R., Dietterich, H. R., Lyons, J. J., Diefenbach, A. K., Parcheta, C., Anderson, K. R., Namiki, A., Sumita, I., Shiro, B., J.P. Kauhikaua, 2019, Cyclic lava effusion during the 2018 eruption of Kilauea Volcano, Science, 366. eaay9070
**Hayashi, K. and I. Sumita, 2017, Low-velocity impact cratering experiments in granular slopes, Icarus, 291, 160-175. PDF
**Yasuda, N., and I. Sumita,, 2016, Effect of viscosity on the shaking-induced fluidization in a liquid-immersed granular medium, Phys. Rev. E., 93, 022901. PDF
Sumita, I, and M. I. Bergman, 2015. Inner-Core Dynamics, in Schubert, G. (ed.) Treatise on Geophysics (second edition), Oxford: Elsevier Ltd.
**Yasuda, N. and I. Sumita, 2014. Shaking conditions required for flame structure formation in a water-immersed granular medium, Progress Earth Planet Sci, 1:13 doi:10.1186/2197-4284-1-13, Springer Open : JpGU 2013 Convener recommended article PDF (open access)
Namiki, A., Yamaguchi, T.,Sumita, I., Suzuki, T., and S. Ide,, 2014. Earthquake model experiments in a viscoelastic fluid: A scaling of decreasing magnitudes of earthquakes with depth, J. Geophys. Res. DOI:10.1002/2014JB011135 PDF
**Takita, H. and I. Sumita,, 2013. Low-velocity impact cratering experiments in a wet sand target, Phys. Rev. E., 88, 022203. PDF
**Shibano, Y., Sumita, I., and A. Namiki, 2013, A laboratory model for melting erosion of a magma chamber roof and the generation of a rhythmic layering, J. Geophys. Res. 118, 4101-4116, DOI:10.1002/jgrb.50295. PDF
**Shibano, Y., Namiki, A., and I. Sumita, 2012, Experiments on upward migration of a liquid-rich layer in a granular medium: Implications for a crystalline magma chamber, Geochem. Geophys. Geosys., Q03007, doi:10.1029/2011GC003994 PDF
Sumita, I. and *Y. Ota, 2011, Experiments on buoyancy-driven crack around the brittle-ductile transition, Earth Planet. Sci. Lett, 304, 337-346, .doi:10.1016/j.epsl.2011.01.032 PDF
**Kitamura, S. and I. Sumita, 2011, Experiments on a turbulent plume: shape analyses, J. Geophys. Res., 116, B03208, DOI:10.1029/2010JB007633 PDF
**Kobayashi, T., Namiki, A., and I. Sumita, 2010, Excitation of airwaves caused by bubble bursting in a cylindrical conduit: Experiments and a model, J. Geophys. Res., 115, B10201, doi:10.1029/2009JB006828. PDF
**Higashi, N. and I. Sumita, 2009, Experiments on granular rheology: effects of particle size and fluid viscosity, J. Geophys. Res., 114, B04413, DOI.10.1029/2008JB005999. PDF
Sumita, I. and M. Manga, 2008, Suspension rheology under oscillatory shear and its geophysical implications, Earth Planet Sci. Lett. 269, 467-476, PDF
**Sato, M. and I. Sumita, 2007, Experiments on gravitational phase separation of binary immiscible fluids, J. Fluid Mech., 591, 289-319, PDF
Sumita, I, and M. I. Bergman, 2007, Inner-Core Dynamics, Schubert, G. (ed.) inTreatise on Geophysics, vol 8.10 pp.299-318. Oxford: Elsevier Ltd. PDF
**Matsumoto, N., Namiki, A. and I. Sumita, 2006, Influence of basal thermal anomaly on mantle convection, Phys. Earth Planet. Inter. , 157, 208-222, PDF
**Okamoto, T., Sumita, I., Nakakuki, T. and S. Yoshida, 2005, Deformation of partially molten D" layer by small-scale convection and the resulting seismic anisotropy and ultralow velocity zone, Phys. Earth Planet. Inter.,153, 32-48, PDF
**Michioka, H. and I. Sumita, 2005, Rayleigh-Taylor instability of a particle packed viscous fluid: Implications for a solidifying magma, Geophys. Res. Lett. , 32, doi:10.1029/2004GL021827. PDF, * AGU Editor's Choice (Surface Processes)
Sumita,I. and P. Olson, 2003, Experiments on highly supercritical thermal convection in a rapidly rotating hemispherical shell, J. Fluid Mech., 492, 271-287. PDF
Namiki, A., Hatakeyama, T., Toramaru, A., Kurita, K. and I. Sumita, 2003, Bubble size distributions in a convecting layer, Geophys. Res. Lett.., 30, 10.1029/2003GL017156. PDF
Sumita, I. and S. Yoshida, 2003, Thermal interactions between the mantle, outer and inner cores, and the resulting structural evolution of the core, in Earth's Core: Dynamics, Structure, Rotation, Ed. Dehant, V. et al., AGU Geodynamics series, 31. pp. 213- 231. 10.1029/031GD14. PDF
Olson, P., Sumita, I., and J. Aurnou, 2002, Diffusive Magnetic Images of Upwelling Patterns in the Core, J. Geophys. Res., 107, 10.1029/2001JB000384. PDF
Sumita, I. and P. Olson, 2002, Rotating thermal convection experiments in a hemispherical shell with heterogeneous boundary heat flux: Implications for the Earth's core, J . Geophys. Res., 107, 10.1029/2001JB000548. PDF
Sumita, I., Hatakeyama, T., Yoshihara, A., and Y. Hamano, 2001, Paleomagnetism of Archean rocks of Hamersley basin, Western Australia and the paleointensity in the early Proterozoic, Phys. Earth Planet. Inter. , 128, 223-241. PDF
Sumita, I. and J. Aurnou, 2000, Thermal convection experiments in rotating systems and their applications to planetary cores, Recent Research Developments in Geophysics, 3, 169-180. PDF
Sumita, I. and P. Olson, 2000, Laboratory experiments on high Rayleigh number thermal convection in a rapidly rotating hemispherical shell, Phys. Earth Planet. Inter., 117, 153-170. PDF
Sumita, I. and P. Olson, 1999, A Laboratory model for convection in Earth's core driven by a thermally heterogeneous mantle, Science, 286, 1547-1549. PDF
* Headlines@Hopkins : "Earth's Core May Contain Cold Front of Molten Iron"
Yoshida, S., Sumita, I., and M. Kumazawa, 1998, Models of the anisotropy of the Earth's inner core, J. Phys. Condens. Matter, 10, 1-12. PDF
Yoshida, S., Sumita, I., and M. Kumazawa, 1996, Growth Model of the Inner Core Coupled with Outer Core Dynamics and the Resulting Elastic Anisotropy, J. Geophys. Res., 101, B12, 28085-28103. PDF
Sumita, I., Yoshida, S., Kumazawa, M., and Y. Hamano, 1996, A model for sedimentary compaction of a viscous medium and its application to inner-core growth, Geophys. J. Int.,124, 502-524. PDF
Sumita, I., Yoshida, S., Hamano, Y., and M. Kumazawa, 1995, A Model for the Structural Evolution of the Earth's Core and its relation to the observations, in The Earth's Central Part: Its Structure and Dynamics, pp.231-261, ed. Yukutake, T., Terra Scientific Publishing Company, Tokyo, Japan. PDF
Papers(unrefereed)
並木、山口、隅田、鈴木、井出、2017、粘弾性体がおこす地震のモデル実験、ながれ (特集:注目研究 i n 年会 2017) 36 (3) 387-390 PDF
隅田、**安田、**柴野、**道岡、並木、2014、液体中における密に詰まった粉粒体の重力不安定、混相流 特集:粒子の流れ(1)、28 (3) 304-311(及び巻頭口絵) 本文 口絵
**柴野、隅田、並木、2011、溶融により粒子が上部から供給される場の熱対流実験、ながれ、(特集:注目研究 in 年会2011、表紙の上から2列目)、30、451-454
吉田、隅田、2001、 内核の異方性と差動回転が意味するもの、日本地震学会ニュースレター、13 (2), 45-49.
浜野、隅田、1998、固体中心核の成長と地球磁場の振る舞い、岩波 科学、68, 814-820.
畠山、中野、隅田、浜野、1995、BIF の岩石磁気学的研究、月刊地球号外、17 (3), 183 -186.
隅田、吉田、浜野、熊沢、1995、成長によってつくられる内核の部分溶融構造、月刊地球、17 (3), 153-158. PDF
隅田、吉田、浜野、熊沢、1994、内核の構造と進化、月刊地球号外、10, 163-166.
Chapter in Books
隅田、吉田、2002, (5.2) 内核の成長と核の進化、全地球史解読、333-345、東京大学出版会.
吉原、畠山、隅田、浜野、2002, (5.4) 地球史と地球磁場-特に太古代の地球磁場、全地球史解読, 363-381、東京大学出版会 .
For general public
原子力なあるほど教室、地球の中はどうなっている、あともす、(財)能登原子力センター
2008年1月号:「マントルは流れる」、3月号:「火山はどうして噴火する?」、5月号:「地球はまわる」、7月号:「地球は何で出来ている?」、
9月号:「地球は磁石」