Efficient Electrochemical CO2 Reduction Reaction over Cu-decorated Biphenylene

Abstract

Developing efficient electrocatalysts for CO2 reduction into value-added products is crucial for the green economy. Inspired by the recent synthesis of Biphenylene (BPH), we have systematically investigated pristine, defective, and Cu-decorated BPH as an electrocatalyst for the CO2 reduction reactions (CRR). Our first-principles calculations show the CO2 molecules weakly interact with the pristine BPH surface while defective BPH facilitates the CO2 adsorption with a binding energy (Eb) of -3.22 eV, indicating the detrimental process for the CRR on the surface of both systems. Furthermore, we have investigated the binding energy and kinetic stability of Cu-decorated BPH as a single-atom-catalyst (SAC). The molecular dynamics simulations confirm the kinetic stability, revealing that the Cu-atom avoids agglomeration under low metal dispersal conditions. The CO2 molecule gets adsorbed horizontally on the Cu-BPH surface with Eb of -0.52 eV. The CRR mechanism is investigated using two pathways beginning with two different initial intermediate states, formate (*OCOH) and the carboxylic (*COOH) pathways. The formate pathway confirms the conversion of *OCOH to *HCOOH with the rate-limiting potential (UL) of 0.57 eV for the production of HCOOH, while for the carboxylic pathway, the conversion of *COH to *CHOH has UL of 0.49 eV for the production of CH3OH. We have also investigated the effect of protons using charged hydrogen pseudopotential, which hints towards the possible formation of CH3OH as fuel. Our findings propose Cu-BPH as an efficient single-atom catalyst for CO2 conversion compared to the well-known Cu metal.

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