Conveners
[CM3-1] Journey for the Next Generation of Energy Storage Systems: The Rise of a Membrane-Free Alkali Metal-Iodide Battery with a Molten Salt Electrolyte
- Juhan Lee (Project Manager, Heraeus Battery Technology GmbH)
[CM3-1] Journey for the Next Generation of Energy Storage Systems: Fine Particle Separation Methods for the Recycling of Lithium Ion Batteries and Water Electrolyzers
- Sohyun Ahn (Helmholtz-Zentrum Dresden-Rossendorf)
[CM3-1] Journey for the Next Generation of Energy Storage Systems: Mechanical Analysis of Recycled Carbon Fiber Composites from Waste Hydrogen Tanks
- Sangjun Jeon (Kongju National University)
[CM3-1] Journey for the Next Generation of Energy Storage Systems: General framework of discovering the origin of catalyst degradation for electrochemical CO2 reduction
- Ung Lee (Korea Institute of Science and Technology)
Description
The advancement of technology has brought about a revolution in how we store and use energy. With the growing demand for portable electronic devices and the increasing need for sustainable energy solutions, the development of energy storage systems has become crucial. In this session, we will delve into the journey of secondary batteries, from lead-acid to lithium-ion and beyond, exploring their evolution and current state-of-the-art technology. We will also examine the industry's current challenges and opportunities for improvement. This session aims to provide a comprehensive understanding of the current and future trends in energy storage systems, highlighting the need for further research and development in this field. Whether you are an industry professional, researcher, or just interested in the topic, this session will provide valuable insights into the current state of the industry and future trends. Join us on this journey to discover the next generation of energy storage systems and how they will shape our future.
Liquid metal electrode batteries are a promising solution for sustainable energy storage due to their low manufacturing costs and high recyclability.[1] However, to improve their viability, they need to operate at lower temperatures, higher voltages, and be membrane-free.[2,3] In this study, we present a novel membrane-free battery design based on liquid alkali metals and iodide. The battery...
Due to human-induced climate change, the world is calling for a technological revolution centered on the decarbonization of industry and the energy transition. A key component of this effort is the ability to store energy from fluctuating renewable sources. Emerging technologies such as lithium-ion batteries and water electrolyzers for the hydrogen economy have a high demand for critical...
As environmental regulations tighten and the demand for lightweight materials increases, the utilization of carbon fiber reinforced plastics (CFRP) in high value-added industries such as automotive, aviation, and space is on the rise. However, there is a lack of recycling systems to cope with the growing use of CFRP, resulting in a significant amount of waste. Specifically, the recycling of...
Degradation of catalysts presents a considerable obstacle in the path to the commercialisation of CO2 electrochemical reduction. This is primarily due to the reduction in activity and selectivity it incurs. Despite this, the high costs associated with catalyst characterisation experiments make it difficult to produce adequate and significant data on catalyst deterioration. Machine learning...
