Machine learning assisted high-throughput screening of transition metal single atom based superb hydrogen evolution electrocatalysts

Carbon-based transition metal (TM) single-atom catalysts (SACs) have shown great potential toward electrochemical water splitting and H-2 production. Given that two-dimensional (2D) materials are widely exploited for sustainable energy conversion and storage applications, the optimization of SACs with respect to diverse 2D materials is of importance. Herein, using density functional theory (DFT) and machine learning (ML) approaches, we highlight a new perspective for the rational design of TM-SACs. We have tuned the electronic properties of similar to 364 rationally designed catalysts by embedding 3d/4d/5d TM single atoms in diverse substrates including g-C3N4, pi-conjugated polymer, pyridinic graphene, and hexagonal boron nitride with single and double vacancy defects each with a mono- or dual-type non-metal (B, N, and P) doped configuration. In ML analysis, we use various types of electronic, geometric and thermodynamic descriptors and demonstrate that our model identifies stable and high-performance HER electrocatalysts. From the DFT results, we found 20 highly promising candidates which exhibit excellent HER activities (|Delta G(H*)| <= 0.1 eV). Remarkably, Pd@B-4, Ru@N2C2, Pt@B2N2, Fe@N-3, Fe@P-3, Mn@P-4 and Fe@P-4 show practically near thermo-neutral binding energies (|Delta G(H*)| = 0.01-0.02 eV). This work provides a fundamental understanding of the rational design of efficient TM-SACs for H-2 production through water-splitting.

Automated summary

This study highlights a new perspective for the rational design of transition metal single-atom catalysts (SACs) using density functional theory (DFT) and machine learning (ML) approaches. By embedding single atoms of 3d/4d/5d transition metals in different substrates, the electronic properties of 364 catalysts were tuned. Machine learning analysis identified stable and high-performance catalysts for hydrogen evolution reaction (HER) based on various descriptors. The study provides a fundamental understanding for the efficient rational design of TM-SACs for H-2 production through water-splitting.