A Universal Approach for Controllable Synthesis of Homogeneously Alloyed PtM Nanoflowers toward Enhanced Methanol Oxidation

Abstract Platinum (Pt)‐based alloys have received considerable attention due to their compositional variability and unique electrochemical properties. However, homogeneous element distribution at the nanoscale, which is beneficial to various electrocatalytic reactions, is still a great challenge. Herein, a universal approach is proposed to synthesize homogeneously alloyed and size‐tunable Pt‐based nanoflowers utilizing high gravity technology. Owing to the significant intensification of micro‐mixing and mass transfer in unique high gravity shearing surroundings, five typical binary/ternary Pt‐based nanoflowers are instantaneously achieved at room temperature. As a proof‐of‐concept, as‐synthesized Platinum‐Silver nanoflowers (PtAg NFs) demonstrate excellent catalytic performance and anti‐CO poisoning ability for anodic methanol oxidation reaction with high mass activity of 1830 mA mg Pt −1 , 3.5 and 3.2 times higher than those of conventional beaker products and commercial Pt/C, respectively. The experiment in combination with theory calculations suggest that the enhanced performance is due to additional electronic transmission and optimized d‐band center of Pt caused by high alloying degree.