Institutional Repository, Rajeev Gandhi Govt. Post Graduate College Ambikapur, Distt. Surguja, Chhattisgarh(India), Pin Code - 497001-Dr.Mahendra Kumar Maurya
Dr.Mahendra Kumar Maurya , Institutional Repository, Rajeev Gandhi Govt. Post Graduate College Ambikapur, Distt. Surguja, Chhattisgarh(India), Pin Code - 497001-Md. Javed Akaram
Md. Javed Akaram , Institutional Repository, Rajeev Gandhi Govt. Post Graduate College Ambikapur, Distt. Surguja, Chhattisgarh(India), Pin Code - 497001-Smt. Kiran Minj
Smt. Kiran Minj , Institutional Repository, Rajeev Gandhi Govt. Post Graduate College Ambikapur, Distt. Surguja, Chhattisgarh(India), Pin Code - 497001-Sahil K. Kushwaha
Sahil K. Kushwaha
Title
TEMPERATURE-DEPENDENT EFFICIENCY OF SOLID-STATE BATTERIES: A COMPARATIVE STUDY OF LITHIUM SULFIDE, GARNET, AND POLYMER ELECTROLYTES
Author(s)
, Dr.Mahendra Kumar Maurya , Md. Javed Akaram , Smt. Kiran Minj , Sahil K. Kushwaha
Issue Date
17-09-2024
Citation
-
Document Abstract
In this paper we have studied the in-depth comparative examination of the temperature-dependent efficiency of solid-state batteries, concentrating on three primary electrolyte materials: Lithium Sulfide (LiS), Garnet-based electrolytes, and Polymer electrolytes. Solid-state batteries are recognized for their superior safety and energy density; however, their performance is notably affected by the operating temperature. The research models the efficiency of these materials over a temperature spectrum of -10°C to 100°C, employing a parabolic degradation model to accurately reflect the behaviour specific to each material. It is found that Lithium Sulfide maintains the highest efficiency retention at elevated temperatures, rendering it particularly suitable for high-temperature applications. It has also been observed that the Garnet-based electrolytes exhibit moderate stability and efficiency within mid-range temperatures, whereas Polymer electrolytes experience a rapid decline in efficiency when operating outside their optimal temperature range, thus making them more appropriate for low-temperature settings. The paper further explores the practical implications for battery applications, potential design enhancements, and the environmental consequences of temperature-induced degradation. Future research avenues include improving electrolyte stability across broader temperature ranges and investigating hybrid electrolyte systems to enhance thermal performance.
Language
English
Document Year
2024
Subject Name
Physics
Publisher Name
I. J. of Innovative Research in Electrical, Electronics, Instrumentation and Control Engineering
Rights :
International Journal of Innovative Research in Electrical, Electronics, Instrumentation and Control Engineering