Air-cathode interface-engineered electrocatalyst for solid-state rechargeable zinc-air batteries
Title | Air-cathode interface-engineered electrocatalyst for solid-state rechargeable zinc-air batteries |
Publication Type | Journal Article |
Year of Publication | 2022 |
Authors | Manna, N, Singh, SK, Kurian, M, Torris, A, Kurungot, S |
Journal | ACS Applied Energy Materials |
Volume | 5 |
Issue | 7 |
Pagination | 8756-8768 |
Date Published | JUL |
Type of Article | Article |
ISSN | 2574-0962 |
Keywords | air-cathode interface, bifunctional oxygen catalyst, N-doped entangled graphene, solid-state zinc-air battery, spinel oxides |
Abstract | Solid-state rechargeable zinc-air batteries (ZABs) are gaining interest as a class of portable clean energy technology due to their advantages such as high theoretical energy density, intrinsic safety, and low cost. It is expected that an appropriately triple-phase boundary (TPB) engineered, bifunctional oxygen reaction (OER and ORR) electrocatalyst at the air- electrode of ZABs can redefine the performance characteristics of these systems. To explore this possibility, an electrode material consisting of manganese- cobalt-based bimetallic spinel oxide (MnCo2O4)-supported nitrogen-doped entangled graphene (MnCo2O4/NEGF) with multiple active sites responsible for facilitating both OER and ORR has been prepared. The porous 3D graphitic support significantly affects the bifunctional oxygen reaction kinetics and helps the system display a remarkable catalytic performance. The air electrode consisting of the MnCo2O4/NEGF catalyst coated over the gas diffusion layer (GDL) ensures the effective TPB, and this feature works in favor of the rechargeable ZAB system under the charging and discharging modes. As an important structural and functional attribute of the electrocatalyst, the porosity and nitrogen doping in the 3D conducting support play a decisive aspect in controlling the surface wettability (hydrophilicity/hydrophobicity) of the air electrode. The fabricated solid-state rechargeable ZAB device with the developed electrode displayed a maximum peak power density of 202 mW cm(-2), which is significantly improved as compared to the one based on the Pt/C + RuO2 standard catalyst pair (124 mW cm(-2)). The solid-state device which displayed an initial charge-discharge voltage gap of only 0.7 V at 10 mA cm(-2) showed only a small increment of 86 mV after 50 h. |
DOI | 10.1021/acsaem.2c01266 |
Type of Journal (Indian or Foreign) | Foreign |
Impact Factor (IF) | 6.959 |
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