NEGATIVE ELECTRODE ACTIVE MATERIAL AND BATTERY

Organization Name

Toyota Jidosha Kabushiki Kaisha

Inventor(s)

Hiroki Yabe of Osaka (JP)

Masaki Hirase of Hyogo (JP)

Yusuke Ito of Nara (JP)

Takamasa Ohtomo of Okazaki-shi (JP)

NEGATIVE ELECTRODE ACTIVE MATERIAL AND BATTERY - A simplified explanation of the abstract

This abstract first appeared for US patent application 18415144 titled 'NEGATIVE ELECTRODE ACTIVE MATERIAL AND BATTERY

Simplified Explanation

The abstract describes a negative electrode active material consisting of a porous silicon particle with a solid electrolyte in the form of a thin film covering the inner surface of the pores, with an average thickness of less than 30 nm.

• Porous silicon particle with multiple pores
• Solid electrolyte in the form of a thin film covering inner surface of pores
• Thin film has an average thickness of less than 30 nm

Potential Applications

This technology could be applied in:

• Lithium-ion batteries
• Energy storage systems
• Portable electronic devices

Problems Solved

This innovation addresses:

• Enhanced battery performance
• Improved energy storage capacity
• Increased battery lifespan

Benefits

The benefits of this technology include:

• Higher energy density
• Faster charging capabilities
• Longer battery life

Potential Commercial Applications

The potential commercial applications of this technology could be seen in:

• Battery manufacturing industry
• Electric vehicle sector
• Consumer electronics market

Possible Prior Art

One possible prior art could be the use of solid electrolytes in battery technology to enhance performance and longevity.

Unanswered Questions

How does this technology compare to traditional lithium-ion battery materials?

This technology offers improved performance and longevity compared to traditional lithium-ion battery materials due to the use of porous silicon particles and solid electrolytes.

What are the scalability and cost implications of implementing this technology in commercial products?

The scalability and cost implications of implementing this technology in commercial products would depend on the manufacturing processes and materials used, which would need to be optimized for mass production and cost-effectiveness.

Original Abstract Submitted

A negative electrode active material according to one aspect of the present disclosure includes: a porous silicon particle; and a solid electrolyte, wherein the porous silicon particle has a plurality of pores, the solid electrolyte has a shape of a thin film that covers at least a part of an inner surface of each of the pores, and the thin film has an average thickness of less than 30 nm.