Abstract: Metal-organic small-molecule electrocatalysts, owing to their well-defined structures, tunable electronic properties, and traceable reaction mechanisms, have emerged as a pivotal platform bridging homogeneous molecular chemistry and solid-state catalytic materials. This review systematically summarizes recent advances in their applications to key electrochemical reactions, including hydrogen evolution reaction (HER), oxygen evolution reaction (OER), oxygen reduction reaction (ORR), and carbon dioxide reduction reaction (CO₂RR). Particular emphasis is placed on the differentiated roles of N-, O-, S-, and P-containing functional groups in modulating electronic structures and reaction pathways, as well as their complementary advantages in activity, stability, and selectivity. In addition, key synthetic strategies, including substituent modification, metal doping, bimetallic cooperation, and interfacial engineering are highlighted. The complementing strategies are operando spectroscopic techniques and theoretical modeling, which offer vital insights for identifying real active sites and clarifying catalytic mechanisms. Thereby, the integration of molecular design, in situ characterization, and multiscale synergy is expected to accelerate the practical deployment of these catalysts in clean energy conversion and carbon cycle utilization.

Key words: Metal-organic small molecule, Electrocatalysis, Functional group modulation, Operando characterization, Clean energy