Superconductivity of lanthanum hydride synthesized using AlH3 as a hydrogen source

Masafumi Sakata; Mari Einaga; Meng Dezhong; Toyoto Sato; Shin Ichi Orimo; Katsuya Shimizu

doi:10.1088/1361-6668/abb204

Superconductivity of lanthanum hydride synthesized using AlH3 as a hydrogen source

Masafumi Sakata, Mari Einaga, Meng Dezhong, Toyoto Sato, Shin Ichi Orimo, Katsuya Shimizu

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Hydrogen-rich compounds show high-Tc superconductivity related to dense hydrogen under extremely high pressure (above 100 GPa). A recent investigation to search for high-Tc superconductive hydrides has advanced a synthesis technique using infrared laser heating of a hydrogen source material under conditions of extremely high pressure and temperature. In order to find a suitable synthesis route for high-Tc superconductive hydrides, the selection of a hydrogen source material has to be considered. In this study, the synthesis of hydrogen-rich lanthanum hydrides (LaHx) was performed using aluminium trihydride (AlH3) as the hydrogen source. Simple lanthanum on AlH3 was pressurized at 150 GPa and heated by infrared laser irradiation. After the laser heating, superconductivity at Tc ∼ 70 K was observed at 170 GPa. This indicates that LaHx (x < 10) was synthesized using AlH3 as the hydrogen source under conditions of extremely high pressure.

Original language	English
Article number	abb204
Journal	Superconductor Science and Technology
Volume	33
Issue number	11
DOIs	https://doi.org/10.1088/1361-6668/abb204
Publication status	Published - 2020 Nov
Externally published	Yes

ASJC Scopus subject areas

Ceramics and Composites
Condensed Matter Physics
Metals and Alloys
Electrical and Electronic Engineering
Materials Chemistry

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10.1088/1361-6668/abb204

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title = "Superconductivity of lanthanum hydride synthesized using AlH3 as a hydrogen source",

abstract = "Hydrogen-rich compounds show high-Tc superconductivity related to dense hydrogen under extremely high pressure (above 100 GPa). A recent investigation to search for high-Tc superconductive hydrides has advanced a synthesis technique using infrared laser heating of a hydrogen source material under conditions of extremely high pressure and temperature. In order to find a suitable synthesis route for high-Tc superconductive hydrides, the selection of a hydrogen source material has to be considered. In this study, the synthesis of hydrogen-rich lanthanum hydrides (LaHx) was performed using aluminium trihydride (AlH3) as the hydrogen source. Simple lanthanum on AlH3 was pressurized at 150 GPa and heated by infrared laser irradiation. After the laser heating, superconductivity at Tc ∼ 70 K was observed at 170 GPa. This indicates that LaHx (x < 10) was synthesized using AlH3 as the hydrogen source under conditions of extremely high pressure.",

author = "Masafumi Sakata and Mari Einaga and Meng Dezhong and Toyoto Sato and Orimo, {Shin Ichi} and Katsuya Shimizu",

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AU - Sakata, Masafumi

AU - Einaga, Mari

AU - Dezhong, Meng

AU - Sato, Toyoto

AU - Orimo, Shin Ichi

AU - Shimizu, Katsuya

PY - 2020/11

Y1 - 2020/11

N2 - Hydrogen-rich compounds show high-Tc superconductivity related to dense hydrogen under extremely high pressure (above 100 GPa). A recent investigation to search for high-Tc superconductive hydrides has advanced a synthesis technique using infrared laser heating of a hydrogen source material under conditions of extremely high pressure and temperature. In order to find a suitable synthesis route for high-Tc superconductive hydrides, the selection of a hydrogen source material has to be considered. In this study, the synthesis of hydrogen-rich lanthanum hydrides (LaHx) was performed using aluminium trihydride (AlH3) as the hydrogen source. Simple lanthanum on AlH3 was pressurized at 150 GPa and heated by infrared laser irradiation. After the laser heating, superconductivity at Tc ∼ 70 K was observed at 170 GPa. This indicates that LaHx (x < 10) was synthesized using AlH3 as the hydrogen source under conditions of extremely high pressure.

AB - Hydrogen-rich compounds show high-Tc superconductivity related to dense hydrogen under extremely high pressure (above 100 GPa). A recent investigation to search for high-Tc superconductive hydrides has advanced a synthesis technique using infrared laser heating of a hydrogen source material under conditions of extremely high pressure and temperature. In order to find a suitable synthesis route for high-Tc superconductive hydrides, the selection of a hydrogen source material has to be considered. In this study, the synthesis of hydrogen-rich lanthanum hydrides (LaHx) was performed using aluminium trihydride (AlH3) as the hydrogen source. Simple lanthanum on AlH3 was pressurized at 150 GPa and heated by infrared laser irradiation. After the laser heating, superconductivity at Tc ∼ 70 K was observed at 170 GPa. This indicates that LaHx (x < 10) was synthesized using AlH3 as the hydrogen source under conditions of extremely high pressure.

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Superconductivity of lanthanum hydride synthesized using AlH3 as a hydrogen source

Abstract

ASJC Scopus subject areas

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