A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Energy Storage Coatings
Classification and Its Applications
As the energy crisis has worsened in recent years, energy storage has become a significant research sector for both industry and academia. To store different forms of energy such as chemical, mechanical, electrochemical, electrical, and thermal, surface coatings play an important role. Surface coatings are fabricated barriers, mainly made of electrochemically active or inactive coating materials, that are applied on cathode material surfaces to limit harmful side reactions by preventing direct contact between the cathode and the electrolyte. These surface coatings are well known for increasing liquid electrolyte wettability and decreasing interfacial charge transfer resistance. An essential consideration is the choice of proper coating material and thickness for improved electrochemical performance. As modern battery materials with some surface coatings are increasingly developed, a careful and thorough examination of their role in mitigating cathode material cycle life issues is critical. Coatings also help boost the efficiency of storage systems by increasing the surface area. Coating materials can be directly introduced into the substrates without adding morphological deformations. In this chapter, we will discuss the classifications of energy storage systems (ESSs), different methods of surface modifications, application, and role of energy storage coatings.
Energy Storage Coatings
Classification and Its Applications
As the energy crisis has worsened in recent years, energy storage has become a significant research sector for both industry and academia. To store different forms of energy such as chemical, mechanical, electrochemical, electrical, and thermal, surface coatings play an important role. Surface coatings are fabricated barriers, mainly made of electrochemically active or inactive coating materials, that are applied on cathode material surfaces to limit harmful side reactions by preventing direct contact between the cathode and the electrolyte. These surface coatings are well known for increasing liquid electrolyte wettability and decreasing interfacial charge transfer resistance. An essential consideration is the choice of proper coating material and thickness for improved electrochemical performance. As modern battery materials with some surface coatings are increasingly developed, a careful and thorough examination of their role in mitigating cathode material cycle life issues is critical. Coatings also help boost the efficiency of storage systems by increasing the surface area. Coating materials can be directly introduced into the substrates without adding morphological deformations. In this chapter, we will discuss the classifications of energy storage systems (ESSs), different methods of surface modifications, application, and role of energy storage coatings.
Energy Storage Coatings
Classification and Its Applications
Arya, Raj K. (editor) / Verros, George D. (editor) / Davim, J. Paulo (editor) / Sachdev, Devyanshu (author) / Sharma, Pragati (author) / Kashyap, Vinod (author) / Tadepalli, Srinivas (author) / Sharma, Rahul (author) / Chankit (author) / Sharma, Ashok K. (author)
2024-10-04
18 pages
Article/Chapter (Book)
Electronic Resource
English
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