A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
ION CONDUCTOR, ION-CONDUCTIVE SINTERED BODY, PRECURSOR SOLUTION, PRECURSOR POWDER AND METHOD FOR PRODUCING THEM
To provide an ion conductor comprising oxides based on the β-Li3PO4 type crystal structure, featuring improved lithium ion conductivity.SOLUTION: An ion conductor comprises, in its main phase, a crystal phase of the β-Li3PO4 type crystal structure, which comprises Li, Si, and P in the crystal lattice, with the Si/(Si+P) atomic ratio of 0.05 or more and 0.40 or less. The ion conductor is obtained by firing, at e.g., 150-550°C, a precursor derived from a colloidal solution that is prepared by mixing a water-soluble lithium compound with the Li, Si, and P composition ratio adjusted within a predetermined range, silicon alkoxide, and a water-soluble phosphorus compound in an aqueous solvent.SELECTED DRAWING: Figure 1
【課題】β-Li3PO4型の結晶構造を基本とする酸化物において、リチウムイオン伝導性を改善したイオン伝導体を提供する。【解決手段】Li、Si、Pを結晶格子中に含むβ-Li3PO4型構造の結晶相を主相に持ち、Si/(Si+P)原子比が0.05以上0.40以下である、イオン伝導体。このイオン伝導体は、水系溶媒中で、Li、Si、P組成比が所定範囲に調整された水溶性リチウム化合物、ケイ素アルコキシド、および水溶性リン化合物を混合して得られるコロイド溶液に由来する前駆体を、例えば150~550℃で焼成することによって得ることができる。【選択図】図1
ION CONDUCTOR, ION-CONDUCTIVE SINTERED BODY, PRECURSOR SOLUTION, PRECURSOR POWDER AND METHOD FOR PRODUCING THEM
To provide an ion conductor comprising oxides based on the β-Li3PO4 type crystal structure, featuring improved lithium ion conductivity.SOLUTION: An ion conductor comprises, in its main phase, a crystal phase of the β-Li3PO4 type crystal structure, which comprises Li, Si, and P in the crystal lattice, with the Si/(Si+P) atomic ratio of 0.05 or more and 0.40 or less. The ion conductor is obtained by firing, at e.g., 150-550°C, a precursor derived from a colloidal solution that is prepared by mixing a water-soluble lithium compound with the Li, Si, and P composition ratio adjusted within a predetermined range, silicon alkoxide, and a water-soluble phosphorus compound in an aqueous solvent.SELECTED DRAWING: Figure 1
【課題】β-Li3PO4型の結晶構造を基本とする酸化物において、リチウムイオン伝導性を改善したイオン伝導体を提供する。【解決手段】Li、Si、Pを結晶格子中に含むβ-Li3PO4型構造の結晶相を主相に持ち、Si/(Si+P)原子比が0.05以上0.40以下である、イオン伝導体。このイオン伝導体は、水系溶媒中で、Li、Si、P組成比が所定範囲に調整された水溶性リチウム化合物、ケイ素アルコキシド、および水溶性リン化合物を混合して得られるコロイド溶液に由来する前駆体を、例えば150~550℃で焼成することによって得ることができる。【選択図】図1
ION CONDUCTOR, ION-CONDUCTIVE SINTERED BODY, PRECURSOR SOLUTION, PRECURSOR POWDER AND METHOD FOR PRODUCING THEM
イオン伝導体、イオン伝導性焼結体、前駆体溶液、前駆体粉体およびそれらの製造方法
AKIMOTO JUNJI (author) / KATAOKA KUNIMITSU (author) / FUJITA RIKUTO (author) / SUGII KAORI (author) / TAGAMI KOJI (author) / FUJITA HIDEFUMI (author) / AIZAWA MICHIO (author)
2024-04-25
Patent
Electronic Resource
Japanese
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