Panasonic intellectual property management co., ltd. (20240347766). SOLID ELECTROLYTE MATERIAL AND BATTERY USING SAME simplified abstract

From WikiPatents
Revision as of 02:34, 18 October 2024 by Wikipatents (talk | contribs) (Creating a new page)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search

SOLID ELECTROLYTE MATERIAL AND BATTERY USING SAME

Organization Name

panasonic intellectual property management co., ltd.

Inventor(s)

Kenta Nagamine of Osaka (JP)

Akihiro Sakai of Nara (JP)

SOLID ELECTROLYTE MATERIAL AND BATTERY USING SAME - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240347766 titled 'SOLID ELECTROLYTE MATERIAL AND BATTERY USING SAME

The abstract of the patent application describes a solid electrolyte material composed of Li, M, and X, where M is a metal element other than Li and metalloids, and X is a halogen element such as F, Cl, Br, or I. The material must meet a specific criterion related to the half width of an x-ray diffraction peak.

  • The solid electrolyte material contains Li, M (metal element), and X (halogen element).
  • The material must meet a specific criterion related to the half width of an x-ray diffraction peak.
  • X-ray diffraction measurement is performed using Cu-Kα radiation.
  • The material must have a diffraction peak with the highest intensity within a specific range of diffraction angles.
  • The technology aims to improve the performance of solid electrolyte materials for various applications.

Potential Applications: - Solid-state batteries - Energy storage devices - Electronics industry

Problems Solved: - Enhancing the conductivity of solid electrolyte materials - Improving the efficiency and stability of energy storage devices

Benefits: - Increased energy storage capacity - Longer lifespan of batteries - Enhanced safety features in electronic devices

Commercial Applications: Title: Advanced Solid Electrolyte Materials for Next-Generation Batteries This technology can be utilized in the development of high-performance batteries for electric vehicles, portable electronics, and renewable energy storage systems. The market implications include increased demand for efficient and safe energy storage solutions.

Questions about Solid Electrolyte Materials: 1. How does the specific criterion related to the half width of an x-ray diffraction peak impact the performance of the solid electrolyte material? The criterion ensures the material's structural integrity and conductivity, leading to improved overall performance in energy storage applications.

2. What are the potential challenges in scaling up the production of solid electrolyte materials for commercial use? Scaling up production may involve optimizing manufacturing processes, ensuring consistent quality control, and meeting regulatory standards for safety and performance.


Original Abstract Submitted

a solid electrolyte material is composed of li, m, and x. m is at least one selected from the group consisting of metal elements other than li and metalloids. x is at least one selected from the group consisting of f, cl, br, and i. fwhm/2�≤0.015 is satisfied, wherein fwhm represents a half width of an x-ray diffraction peak in an x-ray diffraction pattern obtained by performing x-ray diffraction measurement on the solid electrolyte material by using cu—k� radiation, the x-ray diffraction peak having the highest intensity within a range of diffraction angles 2� greater than or equal to 25� and less than or equal to 35�, and 2�represents a diffraction angle at a center of the x-ray diffraction peak.