Sota Arakawa

PUBLICATIONS

Submitted Papers

[—] Sota ARAKAWA,
Root mean square of the distance and geodesic between two constituent particles within fractal aggregates prepared by BCCA, DLA, and GSAW procedures.

[—] Sota ARAKAWA, Misako TATSUUMA, Hidekazu TANAKA, Mikito FURUICHI, and Daisuke NISHIURA,
Interparticle normal force in highly porous granular matter during compression.

[—] Sota ARAKAWA and Shigeru WAKITA,
Survivability of Amorphous Ice in Comets Depends on the Latent Heat of Crystallization of Impure Water Ice.

Articles in Peer Reviewed Journals: Lead-Author Papers

[22] Sota ARAKAWA, Daiki YAMAMOTO, Takayuki USHIKUBO, Hiroaki KANEKO, Hidekazu TANAKA, Shigenobu HIROSE, and Taishi NAKAMOTO,
Oxygen isotope exchange between molten silicate spherules and ambient water vapor with nonzero relative velocity: Implication for chondrule formation environment,
Icarus, 405, 115690 (2023).

[21] Sota ARAKAWA, Satoshi OKUZUMI, Misako TATSUUMA, Hidekazu TANAKA, Eiichiro KOKUBO, Daisuke NISHIURA, Mikito FURUICHI, and Taishi NAKAMOTO,
Size Dependence of the Bouncing Barrier in Protoplanetary Dust Growth,
The Astrophysical Journal Letters, 951, L16 (2023).

[20] Sota ARAKAWA, Daisuke NISHIURA, and Mikito FURUICHI,
Interpebble contact radius in a comet nucleus,
Monthly Notices of the Royal Astronomical Society, 521, 4927 (2023).

[19] Sota ARAKAWA, Hidekazu TANAKA, Eiichiro KOKUBO, Daisuke NISHIURA, and Mikito FURUICHI,
Threshold velocity for the collisional growth of porous dust aggregates consisting of cohesive frictionless spheres,
Astronomy & Astrophysics, 670, L21 (2023).

[18] Sota ARAKAWA and Eiichiro KOKUBO,
Number of stars in the Sun’s birth cluster revisited,
Astronomy & Astrophysics, 670, A105 (2023).

[17] Sota ARAKAWA, Hidekazu TANAKA, and Eiichiro KOKUBO,
Collisional growth efficiency of dust aggregates and its independence of the strength of interparticle rolling friction,
The Astrophysical Journal, 939, 100 (2022).

[16] Sota ARAKAWA, Hidekazu TANAKA, and Eiichiro KOKUBO,
Impacts of viscous dissipation on collisional growth and fragmentation of dust aggregates,
The Astrophysical Journal, 933, 144 (2022).

[15] Sota ARAKAWA, Hiroaki KANEKO, and Taishi NAKAMOTO,
Fine-grained rim formation via kinetic dust aggregation in shock waves around evaporating icy planetesimals,
The Astrophysical Journal, 927, 188 (2022).

[14] Sota ARAKAWA, Ryuki HYODO, Daigo SHOJI, and Hidenori GENDA,
Tidal evolution of the eccentric moon around dwarf planet (225088) Gonggong,
The Astronomical Journal, 162, 226 (2021).

[13] Sota ARAKAWA, Yuji MATSUMOTO, and Mitsuhiko HONDA,
On the crystallinity of silicate dust in evolving protoplanetary disks due to magnetically driven disk winds,
The Astrophysical Journal, 920, 27 (2021).

[12] Sota ARAKAWA and Sebastiaan KRIJT,
On the stickiness of CO2 and H2O ice particles,
The Astrophysical Journal, 910, 130 (2021).

[11] Sota ARAKAWA and Kazumasa OHNO,
Thermal inertias of pebble-pile comet 67P/Churyumov–Gerasimenko,
Monthly Notices of the Royal Astronomical Society, 497, 1166 (2020).

[10] Sota ARAKAWA,
Revisiting sticking property of submillimetre-sized aggregates,
Monthly Notices of the Royal Astronomical Society, 496, 2786 (2020).

[9] Sota ARAKAWA, Masaki TAKEMOTO, and Taishi NAKAMOTO,
Geometrical structure and thermal conductivity of dust aggregates formed via ballistic cluster−cluster aggregation,
Progress of Theoretical and Experimental Physics, 2019, 093E02 (2019).

[8] Sota ARAKAWA and Yuhito SHIBAIKE,
Photophoresis in the circumjovian disk and its impact on the orbital configuration of the Galilean satellites,
Astronomy & Astrophysics, 629, A106 (2019).

[7] Sota ARAKAWA, Ryuki HYODO, and Hidenori GENDA,
Early formation of moons around large trans-Neptunian objects via giant impacts,
Nature Astronomy, 3, 802 (2019).

[6] Sota ARAKAWA and Taishi NAKAMOTO,
Compound chondrule formation in optically thin shock waves,
The Astrophysical Journal, 877, 84 (2019).

[5] Sota ARAKAWA, Misako TATSUUMA, Naoya SAKATANI, and Taishi NAKAMOTO,
Thermal conductivity and coordination number of compressed dust aggregates,
Icarus, 324, 8 (2019).

[4] Sota ARAKAWA, Hidekazu TANAKA, Akimasa KATAOKA, and Taishi NAKAMOTO,
Thermal conductivity of porous aggregates,
Astronomy & Astrophysics, 608, L7 (2017).

[3] Sota ARAKAWA,
Ejection of Chondrules from Fluffy Matrices,
The Astrophysical Journal, 846, 118 (2017).

[2] Sota ARAKAWA and Taishi NAKAMOTO,
Rocky Planetesimal Formation via Fluffy Aggregates of Nanograins,
The Astrophysical Journal Letters, 832, L19 (2016).

[1] Sota ARAKAWA and Taishi NAKAMOTO,
Compound chondrule formation via collision of supercooled droplets,
Icarus, 276, 102 (2016).

Articles in Peer Reviewed Journals: Co-Author Papers

[5] Yuji MATSUMOTO and Sota ARAKAWA,
Igneous Rim Accretion on Chondrules in Low-velocity Shock Waves,
The Astrophysical Journal, 948, 73 (2023).

[4] Doris ARZOUMANIAN, Sota ARAKAWA, Masato I. N. KOBAYASHI, Kazunari IWASAKI, Kohei FUKUDA, Shoji MORI, Yutaka HIRAI, Masanobu KUNITOMO, M. S. Nanda KUMAR, and Eiichiro KOKUBO,
Insights on the Sun Birth Environment in the Context of Star Cluster Formation in Hub–Filament Systems,
The Astrophysical Journal Letters, 947, L29 (2023).

[3] Naoya SAKATANI, Satoshi TANAKA, and Sota ARAKAWA,
Development of a small-sized line heat source apparatus for the thermal conductivity measurement of extraterrestrial soils,
International Journal of Thermophysics, 43, 89 (2022).

[2] Hiroaki KANEKO, Sota ARAKAWA, and Taishi NAKAMOTO,
Dependence of the initial internal structure of chondrule rim on dust size distribution,
Icarus, 374, 114726 (2022).

[1] Ryota FUKAI and Sota ARAKAWA,
Assessment of Cr isotopic heterogeneities of volatile-rich asteroids based on multiple planet formation models,
The Astrophysical Journal, 908, 64 (2021).

Japanese Articles

[2] Sota ARAKAWA, Ryota FUKAI, and Kazuaki A. HOMMA,
Planet Formation History Revealed by the Isotopic Heterogeneity in the Solar Nebula,
Planetary People, 31, 50 (2022).

[1] Sota ARAKAWA, Ryuki HYODO, Daigo SHOJI, and Hidenori GENDA,
Formation and Evolution of Moons around Trans-Neptunian Objects,
Planetary People, 29, 104 (2020).