Taiki Karahashi scite author profile

Solid state lithium conductors are attracting much attention for their potential applications to solid-state batteries and supercapacitors of high energy density to overcome safety issues and irreversible capacity loss of the currently commercialized ones. Recently, we discovered a new class of lithium super ionic conductors based on lithium borohydride (LiBH(4)). LiBH(4) was found to have conductivity as high as 10(-2) Scm(-1) accompanied by orthorhombic to hexagonal phase transition above 115 degrees C. Polarization to the lithium metal electrode was shown to be extremely low, providing a versatile anode interface for the battery application. However, the high transition temperature of the superionic phase has limited its applications. Here we show that a chemical modification of LiBH(4) can stabilize the superionic phase even below room temperature. By doping of lithium halides, high conductivity can be obtained at room temperature. Both XRD and NMR confirmed room-temperature stabilization of superionic phase for LiI-doped LiBH(4). The electrochemical measurements showed a great advantage of this material as an extremely lightweight lithium electrolyte for batteries of high energy density. This material will open alternative opportunities for the development of solid ionic conductors other than previously known lithium conductors.

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Room temperature lithium fast-ion conduction and phase relationship of LiI stabilized LiBH4

Miyazaki

Karahashi

Kumatani

et al. 2011

Solid State Ionics

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Low-Temperature Purification of Silicon by Dissolution and Solution Growth in Sodium Solvent

Morito

Karahashi

Uchikoshi

et al. 2012

Silicon

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Synthesis of an AlN Polycrystalline Bulk Layer and Nanotubes by Using NH₃ and Bi

Morito¹,

Ide²,

Karahashi³

et al. 2009

Journal of the American Ceramic Society

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A bulk layer of aluminum nitride (AlN) polycrystals was synthesized on a boron nitride crucible surface by heating Al chunks with 5 mol% of bismuth at 1273 K for 3 h under NH3 gas flow. The fragments of the layer were characterized by X‐ray diffraction, scanning electron microscopy, and transmission electron microscopy. The platelet grains of AlN with a size of 0.1–1.0 μm and having preferred orientation of the c‐axis perpendicular to the layer were formed at the crucible side. Nanotubes 6–15 μm long and about 20–100 nm thick grew on the gas phase side of the layer.

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Condition of Si crystal formation by vaporizing Na from NaSi

Morito

Karahashi

Yamane

2012

Journal of Crystal Growth

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Taiki Karahashi

Halide-Stabilized LiBH₄, a Room-Temperature Lithium Fast-Ion Conductor

Room temperature lithium fast-ion conduction and phase relationship of LiI stabilized LiBH4

Low-Temperature Purification of Silicon by Dissolution and Solution Growth in Sodium Solvent

Synthesis of an AlN Polycrystalline Bulk Layer and Nanotubes by Using NH₃ and Bi

Condition of Si crystal formation by vaporizing Na from NaSi

Contact Info

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Resources

About

Taiki Karahashi

Halide-Stabilized LiBH4, a Room-Temperature Lithium Fast-Ion Conductor

Room temperature lithium fast-ion conduction and phase relationship of LiI stabilized LiBH4

Low-Temperature Purification of Silicon by Dissolution and Solution Growth in Sodium Solvent

Synthesis of an AlN Polycrystalline Bulk Layer and Nanotubes by Using NH3 and Bi

Condition of Si crystal formation by vaporizing Na from NaSi

Contact Info

Product

Resources

About

Halide-Stabilized LiBH₄, a Room-Temperature Lithium Fast-Ion Conductor

Synthesis of an AlN Polycrystalline Bulk Layer and Nanotubes by Using NH₃ and Bi