However, determining the optimum elemental components and composition is challenging because of the different physical behaviors and chemical activities of the metal elements in catalytic reactions. Furthermore, it is difficult to determine the metal combination that must be investigated as it is difficult to exactly determine which metal element will affect the catalytic performance within the alloy. Before the introduction of computational techniques, researchers have mainly investigated binary and ternary alloys, with the focus on searching for high-performance multi-metallic catalysts by experimental trial and error. [8][9][10] For example, noble and non-noble metals, for example, platinum (Pt), [11][12][13] ruthenium (Ru), [14,15] iridium (Ir), [16,17] palladium (Pd), [18,19] and nickel (Ni), [20] iron (Fe), [21] cobalt (Co), [22] molybdenum (Mo), [23] as well as their alloys, are typically used in the hydrogen evolution reaction (HER), rendering the dimensionality of the space of alloy composition candidates far beyond human intuition or brute-force search by trial and error. However, it was almost impossible to search for the optimal component and composition for high-performance catalysts as the determination of the catalyst performance is a timeconsuming and expensive process due to the enormous number of candidate combinations and compositions.Searching for an optimal component and composition of multi-metallic alloy catalysts, comprising two or more elements, is one of the key issues in catalysis research. Due to the exhaustive data requirement of conventional machine-learning (ML) models and the high cost of experimental trials, current approaches rely mainly on the combination of density functional theory and ML techniques. In this study, a significant step is taken toward overcoming limitations by the interplay of experiment and active learning to effectively search for an optimal component and composition of multi-metallic alloy catalysts. The active-learning model is iteratively updated using by examining electrocatalytic performance of fabricated solid-solution nanoparticles for the hydrogen evolution reaction (HER). An optimal metal precursor composition of Pt 0.65 Ru 0.30 Ni 0.05 exhibits an HER overpotential of 54.2 mV, which is superior to that of the pure Pt catalyst. This result indicates the successful construction of the model by only utilizing the precursor mixture composition as input data, thereby improving the overpotential by searching for an optimal catalyst. This method appears to be widely applicable since it is able to determine an optimal component and composition of electrocatalyst without obvious restriction to the types of catalysts to which it can be applied.
