This review will delve into the inherent connections and distinctions of CO2-directed conversion in ECO2RR and CO2 batteries, in terms of product types, catalyst selection, catalytic mechanisms, and electrochemical performances, while proposing a benchmarking framework for the evaluation of CO2 batteries and innovative CO2 battery configurations for practical applications.
ABSTRACT
Renewable electricity storage coupled with CO2 conversion (power-to-X) has emerged as a fantastic means for reconciling energy demand and CO2 mitigation issues. To successfully implement such approaches, directional CO2 conversion is a crucial prerequisite, making it a pivotal research area. Thereinto, direct electrolysis of CO2 (power-to-chemicals), while far from being commercially successful, has achieved substantial progress in selectivity and conversion rate for certain chemicals. Metal–CO2 (M-CO2) batteries can integrate several energy conversion pathways (power-to-metal paired with metal-to-power and/or metal-to-chemicals); however, their progress remains limited, particularly for directional generation of valuable chemicals. Meanwhile, the lack of understanding and benchmarking across materials and performances hinders rational evaluation and technology advancement of M-CO2 batteries. Herein, we explore the critical elements required to achieve directional CO2 conversion in M-CO2 battery by comparing with direct electrocatalytic CO2 reduction technology, building from fundamental chemistry concepts and issues, basis of materials design and product selectivity, to device-level considerations that facilitate high practical energy and power density, as well as long-duration conversion and storage. The emphasis lies on how to rationally design a precise catalyst and configuration for M-CO2 batteries, with the expectation that forward-looking insights will inspire top-notch investigations and engage various sectors of society.