Nanoscale Wrinkled Cu as a Current Collector for High-Loading Graphite Anode in Solid-State Lithium Batteries

Abstract: Solid-state lithium batteries have been intensively studied as part of research activities to develop energy storage systems with high safety and stability characteristics. Despite the advantages of solid-state lithium batteries, their application is currently limited by poor reversible capacity arising from their high resistance. In this study, we significantly improve the reversible capacity of solid-state lithium batteries by lowering the resistance through the introduction of a graphene and wrinkle structu… Show more

“…Under our new approach, we used the Cu film generated after CVD graphene growth as an electrocatalyst. From the viewpoint of the Cu structure and morphology, after the graphene layer forms on the Cu film by nucleation of a carbon source generated from methane, the thermal expansion energy difference between Cu and graphene results in both expansion and compression of the Cu top surface during the cooling process. − This leads to the formation of a periodic hill-and-valley wrinkle morphology.…”

High Facets on Nanowrinkled Cu via Chemical Vapor Deposition Graphene Growth for Efficient CO₂ Reduction into Ethanol

“…Under our new approach, we used the Cu film generated after CVD graphene growth as an electrocatalyst. From the viewpoint of the Cu structure and morphology, after the graphene layer forms on the Cu film by nucleation of a carbon source generated from methane, the thermal expansion energy difference between Cu and graphene results in both expansion and compression of the Cu top surface during the cooling process. − This leads to the formation of a periodic hill-and-valley wrinkle morphology.…”

High Facets on Nanowrinkled Cu via Chemical Vapor Deposition Graphene Growth for Efficient CO₂ Reduction into Ethanol

“…A high index surface facet structure was obtained by forming nano-wrinkle structures on the bCu. 23,24 At an elevated temperature of 1000 C, a graphene layer was formed on the bCu by owing CH 4 gas. During the cooling process, the copper current collector with high index surface facets (hCu) evolves due to the mismatch in thermal expansion between the graphene and copper surface.…”

Insights on the work function of the current collector surface in anode-free lithium metal batteries

“…However, ASSB exhibits high anode/electrolyte interfacial resistance, the uneven distribution of interfacial current accelerates the dendrite growth, and anode current collector engineering is an efficient approach to solve these problems. Wu M. et al (2021 ) introduced a graphene and periodic wrinkled structure on the surface of Cu by CVD to improve adhesion, reduce interfacial resistance, and improve the reversibility. Au- or Ni-coated current collectors with microsized pores, which facilitate uniform current distribution, were reported to deposit Li in the engineered pores and obtain stable lithium plating/stripping in ASSB ( Shinzo et al, 2020 ).…”

Rational Engineering of Anode Current Collector for Dendrite-Free Lithium Deposition: Strategy, Application, and Perspective