DOI: https://doi.org/10.36347/sjpms.2025.v12i05.005

Pages: 188-198

The need for effective, scalable, and sustainable energy storage solutions has increased due to the quick spread of electric cars, portable gadgets, and renewable energy sources. Because of their extended cycle life, high energy density, and established manufacturing infrastructure, lithium-ion (Li-ion) batteries have long dominated the energy storage market. However, the hunt for substitute technologies, especially sodium-ion (Na-ion) batteries, which take advantage of the cheap and plentiful sodium, has accelerated due to the limited supply and growing expense of lithium resources. This paper thoroughly analyzes Li-ion and Na-ion electrochemical systems, emphasizing the fundamental ideas, current developments, and new difficulties related to these technologies. Important elements, including electrolytes, separators, cathode and anode materials, and electrode/electrolyte interactions, are thoroughly investigated. Innovative material advancements that improve battery performance and safety are highlighted, such as layered oxide cathodes, alloy and conversion-type anodes, solid-state and gel polymer electrolytes, and surface modification methods. The energy density, rate capability, cycle stability, environmental effect, and cost-efficiency of Li-ion and Na-ion systems are compared. The analysis also examines the commercialization and scaling prospects of next-generation batteries, emphasizing initiatives in recycling, green synthesis, and smart grid integration. The environmental and techno-economic effects of switching from lithium to sodium-based chemistry are specifically discussed. This review's main goals are to summarize existing knowledge, pinpoint technological gaps, and delineate future research goals that might propel the creation of sustainable, high-performance electrochemical energy storage systems suited for a variety of cutting-edge applications.