日本地球惑星科学連合2018年大会

講演情報

[EE] ポスター発表

セッション記号 S (固体地球科学) » S-IT 地球内部科学・地球惑星テクトニクス

[S-IT27] 地球内部での液体の特性とその役割

2018年5月22日(火) 10:45 〜 12:15 ポスター会場 (幕張メッセ国際展示場 7ホール)

コンビーナ:坂巻 竜也(東北大学大学院理学研究科)、中島 陽一(熊本大学大学院先導機構)

[SIT27-P03] Sound velocity of liquid Fe under high pressure

*中島 陽一1,2桑山 靖弘3廣瀬 敬3,4石川 大介5Baron Alfred2 (1.熊本大学大学院先導機構、2.理化学研究所放射光科学研究センター物質ダイナミクス研究グループ、3.東京大学地球惑星科学専攻、4.東京工業大学地球生命研究所、5.高輝度光科学研究センター)

キーワード:惑星金属核、液体鉄の音速、高圧

The Earth has liquid outer and solid inner cores, which are composed predominantly of iron. Other terrestrial planets such as Mercury, Venus, and Mars also have metallic iron cores. Those planetary cores can be at least partially molten, as well as Earth’s core. Therefore, the physical property of liquid Fe is fundamental to understand the nature and dynamics of the cores in terrestrial planets. However, our knowledge of its physical properties such as its density, sound wave velocity, and elasticity are still poor especially under high-pressure conditions relevant to inside of those planets. Previously reported equation of state (EoS) on liquid Fe was constructed based on limited density and velocity data at 1 bar and only above 260 GPa by shock compression experiments (e.g. [1]). Recently, sound wave velocity measurements on liquid Fe were performed using a large volume press, however, the pressure range was still limited at below 6 GPa [2,3]. Here, we report new experimental data on P-wave velocity of liquid Fe under high pressures based on inelastic X-ray scattering (IXS) measurements with a laser-heated diamond-anvil cell (LH-DAC) at the beamline BL43LXU [4] of the RIKEN SPring-8 Center in Japan. We measured the dispersion relation of longitudinal acoustic phonon mode of liquid Fe, and then determined the P-wave velocity up to 45 GPa. The obtained pressure and velocity data show a good consistency with an EoS previously reported by Anderson and Ahrens [1].

References
[1] Anderson and Ahrens (1994) J. Geophys. Res. 99, 4273-4284.
[2] Jing et al. (2014) Earth Planet. Sci. Lett. 396, 78-87.
[3] Nishida et al. (2016) Phys. Earth Planet. Inter. 257, 230-239.
[4] Baron (2010) SPring-8 Inf. Newsl. 15, 14-19.