Publications

A. 論文（査読付き）

A-21. Nishiyama, N., Ujiie, K., Noro, K., Mori, Y., & Masuyama, H. in press

Megathrust slip enhanced by metasomatic actinolite in the source region of deep slow slip.
Lithos.

A-20. Yokoyama, T., Shintaku, S., & Nishiyama, N. in press

Change in size distribution of porewater and entrapped air with progression of water infiltration in sandstone.

Journal of Mineralogical and Petrological Sciences.

A-19. Yokoyama, T., Nomura, R., & Nishiyama, N. in press

Size distributions of water and air in rock pores induced by capillary rise: experiments and modeling

Transport in Porous Media.

A-18. Ando, R., Ujiie, K., Nishiyama, N., & Mori, Y. (2023) 

Depth-dependent slow earthquakes controlled by temperature dependence of brittle-ductile transitional rheology. 

Geophysical Research Letters, 50, e2022GL101388. https://doi.org/10.1029/2022GL101388

A-17. Nishiyama, N. (2023)

Reply to comment by Williams on "spatial changes in inclusion band spacing as an indicator of temporal changes in slow slip and tremor recurrence intervals" 

Earth, Planets and Space. 75:3. https://doi.org/10.1186/s40623-022-01750-y

A-16. Ujiie, K., Noro, K., Shigematsu, N., Fagereng, A., Nishiyama, N., Tulley, C.J., Masuyama, H., Mori, Y. & Kagi, H. (2022)
Megathrust Shear Modulated by Albite Metasomatism in Subduction Mélanges.

Geochemistry, Geophysics, Geosystems. 23, e2022GC010569. https://doi.org/10.1029/2022GC010569

A-15. Nishiyama N., Ujiie K., & Kano M. (2021)
Spatial changes in inclusion band spacing as an indicator of temporal changes in slow slip and tremor recurrence intervals.
Earth, Planets and Space. 73:126. https://doi.org/10.1186/s40623-021-01448-7

A-14. Nishiyama, N. & Yokoyama T. (2021)
Water Film Thickness in Unsaturated Porous Media: Effect of Pore Size, Pore Solution Chemistry, and Mineral Type.
Water Resources Research, 57, e2020WR029257. doi:10.1029/2020WR029257.

A-13. Yokoyama, T., Yorimoto, M., & Nishiyama, N. (2020)

Flow Path Selection During Capillary Rise in Rock: Effects of Pore Branching and Pore Radius Variation.

Transport in Porous Media, 135: 79-99. https://doi.org/10.1007/s11242-020-01470-5

A-12. Yokoyama, T. & Nishiyama, N. (2020)

Dissolution of Minerals Driven by the Wetting Film in Rock Pores: Comparison of Silicates and Carbonates.

ACS Earth and Space Chemistry. https://dx.doi.org/10.1021/acsearthspacechem.0c00100

A-11. Nishiyama, N., Sumino, H., Ujiie, K. (2020)

Fluid overpressure in subduction plate boundary caused by mantle-derived fluids.

Earth and Planetary Science Letters, 538.

A-10. Sakuma, H., Sorensen, H.O., Kawano, J., Bovet, N., Fukushi K., Nishiyama, N., and Nakao, H. (2018)

Structure of Calcite-Aqueous NaCl solution Interfaces from Room to Elevated Temperatures.

Journal of Mineralogical and Petrological Science.

A-9. Ujiie, K., Saishu H., Fagereng, A., Nishiyama, N., Otsubo, M., Masuyama, H, and Kagi, H. (2018)
An explanation of episodic tremor and slow slip constrained by crack-seal veins and viscous shear in subduction mélange.

Geophysical Research Letters

A-8. Nishiyama N. and Yokoyama T. (2017)

Permeability of porous media: role of the critical pore size,

Journal of Geophysical Research Solid Earth

A-7. Umezawa R., Nishiyama N., Katsura M. and Nakashima S. (2017)

Electrical conductance of a sandstone partially saturated with varying concentrations of NaCl solutions,

Geophysical Journal International, 209(2), 1287-1295.

A-6. 横山正，西山直毅 (2017)

露頭スケールからナノスケールまでの反応-輸送過程,

地学雑誌, 126(3), 297.

A-5. 西山直毅，横山正 (2017)

岩石内部の水の分布-露頭スケールからナノスケールまで-,

地学雑誌, 126(3), 311.

A-4. Tsunazawa Y., Yokoyama T. and Nishiyama N. (2016)

An experimental study on the rate and mechanism of capillary rise in sandstone.

Progress in Earth and Planetary Science, 3:8.

A-3. Nishiyama N. and Yokoyama T. (2014)
Estimation of permeability of sedimentary rocks by applying water-expulsion porosimetry to Katz and Thompson model.
Engineering Geology, 177, 75–82.

A-2. Nishiyama N. and Yokoyama T. (2013)
Does the reactive surface area of sandstone depend on water saturation?––The role of reactive-transport in water film.
Geochimica et Cosmochimica Acta, 122, 153–169.

A-1. Nishiyama N., Yokoyama T. and Takeuchi S. (2012)
Size distributions of pore water and entrapped air during drying-infiltration processes of sandstone characterized by water-expulsion porosimetry.
Water Resources Research, 48, W09556.
 

B. Proceedings（査読付き）

B-4. Hamamoto M., Katsura K., Nishiyama N., Tonoue R., and Nakashima N. (2015)
Transmission IR micro-spectroscopy of interfacial water between colloidal silica particles.
e-Journal of Surface Science and Nanotechnology.
 

B-3. Nakashima S., Bessho H., Tomizawa R., Kirino Y., Nishiyama N., Tonoue R., Yokoyama T. and Sasamoto H. (2014)
Calcium Silicate Hydrate Formation Rates during Alkaline Alteration of Rocks as revealed by Infrared Spectroscopy. 
Proceedings of The 8th Asian Rock Mechanics Symposium 2014 (ARMS8)
 

B-2. Nishiyama N. and Yokoyama T. (2013)
Estimation of water film thickness in geological media under the occurrence of gas entrapment.
Procedia Earth and Planetary Science, 7, 620–623.
 

B-1. Yokoyama T. and Nishiyama N. (2013)
Role of water film in weathering of porous rhyolite under water unsaturated condition.
Procedia Earth and Planetary Science, 7, 916–919.

C. その他