Synergistic Niobium Doped Two-Dimensional Zirconium Diselenide: An Efficient Electrocatalyst for O$_2$ Reduction Reaction

TL;DR

This study uses DFT calculations to show that Nb-doped ZrSe2 monolayers are highly effective, low-cost catalysts for oxygen reduction in fuel cells, offering a promising alternative to platinum.

Contribution

The paper demonstrates that Nb doping transforms ZrSe2 into a conductive catalyst with favorable ORR pathways, providing new insights into 2D material electrocatalysis.

Findings

Nb doping eliminates the band gap, making ZrSe2 conductive.

The 4-electron associative pathway is thermodynamically favorable for ORR on Nb-ZrSe2.

All intermediate steps are stable and energetically favorable for ORR.

Abstract

The development of high-activity and low-price cathodic catalysts to facilitate the electrochemical sluggish O$_2$ reduction reaction (ORR) is very important to achieve the commercial application of fuel cells. Here, we have investigated the electrocatalytic activity of two-dimensional single-layer Nb-doped zirconium diselenide (2D Nb-ZrSe$_2$) towards ORR by employing the dispersion corrected Density Functional Theory (DFT-D) method. Through our study, we computed structural properties, electronic properties, and energetics of the 2D Nb-ZrSe$_2$ and ORR intermediates to analyze the electrocatalytic performance of the 2D Nb-ZrSe$_2$. The electronic properties calculations depict that the 2D monolayer ZrSe$_2$ has a large band gap of 1.48 eV, which is not favorable for the ORR mechanism. After the doping of Nb, the electronic band gap vanishes and 2D Nb-ZrSe$_2$ acts as a conductor. We studied both the dissociative and associative pathways through which the ORR can proceed to reduce the oxygen molecule (O$_2$). Our results show that the more favorable path for O$_2$ reduction on the surface of the 2D Nb-ZrSe$_2$ is the 4e$^-$ associative path. The detailed ORR mechanisms (both associated and dissociative) have been explored by computing the changes of Gibbs free energy ({\Delta}G). All the ORR reaction intermediate steps are thermodynamically stable and energetically favorable. The free energy profile for the associative path shows the downhill behavior of the free energy vs. the reaction steps, suggesting that all ORR intermediate structures are catalytically active for the 4e$^-$ associative path and a high 4e$^-$ reduction pathway selectivity. Therefore, 2D Nb-ZrSe$_2$ is a promising catalyst for the ORR which can be used as an alternative ORR catalyst compared with expensive platinum (Pt).