Research and Development Status of Solid-State Batteries
DOI:
https://doi.org/10.54097/m59d2s84Keywords:
Solid-State battery, solid-state electrolyte, sulfide electrolyte, oxide electrolyte, polymers electrolyte.Abstract
Batteries, as a widely used energy storage device, have become an important component in the development of modern society. However, traditional liquid batteries face a number of security challenges, energy density and lifespan, and the development of new battery technologies is urgently needed. As an emerging battery technology with high energy density, safety advantages and long lifespan, solid-state batteries (SSB) have obtained much attention worldwide. This paper first introduces the basic working principle of batteries. Batteries use chemical reactions to convert chemical energy into electrical energy, and realize the energy output by the flow of electrons through the movement of ions in the electrolyte. SSB differ from conventional liquid batteries in that they use solid-state materials, such as ceramics or polymers, for the electrolyte, which provide high ionic conductivity. Second, this paper will examine the current SSB development, in which domestic and foreign research institutions and enterprises have conducted extensive and continued to research SSB. They are committed to improving the battery preparation process, optimizing the battery assembly structure, and developing new solid-state electrolyte (SSE) materials. This paper then explores the fundamental technologies related to SSE, which are a critical aspect in the advancement of SSB. Recently, scientists have suggested a range of solid-state electrolyte materials possessing elevated levels of ionic conductivity, including oxides, sulfides, and polymers. Lastly, the advantages and challenges of SSB are analyzed in this paper. Greater safety, higher energy density, and longer lifespan are offered by SSB in comparison to traditional liquid batteries. Nonetheless, challenges regarding the conductivity of the solid-state electrolyte, selection of electrode material, and battery manufacturing costs still need to be addressed by SSB. In summary, SSB as an innovative energy storage solution have great development potential and broad application prospects. Future research and technological innovation will further promote the application and commercialization of SSB in energy storage.
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