Megha Goyal
10 Papers
Megha Goyal is an academic researcher. The author has contributed to research in topics: Chemistry & Thermoelectric materials. The author has an hindex of 1, co-authored 5 publications.
Chat about Author
Papers
A review on self‐healing polymers for applications in spacecraft and construction of roads
TL;DR: In this article , the authors highlight the key points on extrinsic self-healing polymer and intrinsic selfhealing polymers by comparing their healing efficiency, advantages, disadvantages, and challenges in the prospect of their future development as well as their possible applications in space industry and construction of roads.
32
Conductive polymers: A multipurpose material for protecting coating
Megha Goyal,Kulwant Singh,Nitu Bhatnagar +2 more
TL;DR: Conductive polymers offer a versatile material for protective coatings, combining electrical conductivity, optical, and mechanical capabilities with ease of synthesis and manufacturing, and superior durability, enabling bespoke solutions for various applications with enhanced performance and sustainability.
25
Conductive polymer‐based coating layer on copper current collector for enhanced performance of Li‐ion battery
Megha Goyal,Nitu Bhatnagar +1 more
TL;DR: In this paper , the idea underlying its use, as well as the process and foundation of cell fabrications based on various types of conducting polymer systems are discussed in a review, which shows that the modified copper current collector can be regarded as an effective protective layer against solid electrolyte interface (SEI) film, electrode particle cracking, cathode electrolyte formation (CEI), dendrite formation/lithium plating, electrolyte decomposition, etc.
4
Different metal precursor based rapid synthesis of α-Ni(OH)2-type Ni-Co-Mn layered double hydroxides and its use as electrodes for high performance energy storage devices
TL;DR: Researchers develop a rapid synthesis method for α-Ni(OH)2-type Ni-Co-Mn layered double hydroxides, achieving high specific capacity (978 C g−1) and capacity retention (90%) for energy storage devices, outperforming similar metal hydroxides in literature.
4