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Multiscale design of tailored cathode materials for extended-capacity Li-O2 batteries

Khizar Hayat, Daniel Bahamón, Lourdes F. Vega, Ahmed AlHajaj

2025Journal of Energy Storage8 citationsDOIOpen Access PDF

Abstract

In advancing clean energy storage, lithium‑oxygen (Li-O 2 ) batteries face challenges like lithium peroxide (Li 2 O 2 ) buildup, limiting their discharge capacity and energy density . We introduce an integrated and experimentally validated multiscale computational methodology, employing reactive forcefield molecular dynamics (reaxFF-MD) and a 2-D continuum model to design and assess novel carbon-based cathode materials . Our focus on the system performance of four hierarchical zeolite-templated carbons (h-ZTCs), h-RHO-ZTC, h-FAU-ZTC, h-MFI-ZTC, and h-BEA-ZTC, demonstrates that the h-RHO-ZTC cathode notably excels, achieving a discharge capacity of 2523 mAh·g c −1 , and the highest energy (∼7001 Wh·kg c −1 ) and power densities (∼1300 W·kg c −1 ) at a current density of 0.1 mA·cm −2 . Moreover, the parametric study of the h-RHO-ZTC electrode exhibited that lower mass loading and discharge current density, and high oxygen pressure lead to superior discharge capacity, representing that battery performance can be manipulated by adjusting such parameters.

Topics & Concepts

CathodeMaterials scienceEngineering physicsNuclear engineeringElectrical engineeringEngineeringAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesExtraction and Separation Processes
Multiscale design of tailored cathode materials for extended-capacity Li-O2 batteries | Litcius