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Trimetallic Porous PtIrBi Nanoplates with Robust CO Tolerance for Enhanced Formic Acid Oxidation Catalysis

Yingjun Sun, Weibin Chen, Wenshu Zhang, Yan Nie, Qinghua Zhang, Lin Gu, Mingchuan Luo, Shaojun Guo

2023Advanced Functional Materials40 citationsDOIOpen Access PDF

Abstract

Abstract Spreading the formic acid (HCOOH) fuel cells demands a better anode electrocatalyst for the oxidation of formic acid. The catalytic efficiency of platinum (Pt)– the only choice of practicability, is mainly limited by its intrinsic affinity to CO, thus desiring a proper release. Herein, theoretical calculations are first leveraged to find that the introduction of iridium (Ir) can facilitate HCOOH oxidation with robust CO tolerance through a dehydrogenation pathway. Then, this strategy experimentally by designing a new trimetallic catalyst of 2D porous PtIrBi nanoplates (p‐PtIrBi NPs) is implemented. The optimized p‐PtIrBi NPs/C exhibits a very high mass activity of 8.2 A mg −1 pt and a high retention rate of 55.9% after the durability test, which is among the best formic acid oxidation catalysts reported to date, much higher than those of PtIrBi NPs/C, PtBi NPs/C, and Pt/C. The CO‐stripping and in situ Fourier transform infrared (FTIR) experiments collectively evidence that two types of due site, i.e., “Pt‐Bi” and “Ir‐Bi”, endow the catalyst with suppressed CO‐poisoning property to achieve super‐high activity and stability for formic acid oxidation reaction.

Topics & Concepts

Formic acidCatalysisDehydrogenationMaterials scienceFourier transform infrared spectroscopyPlatinumElectrocatalystChemical engineeringIridiumAnodeInorganic chemistryElectrochemistryChemistryOrganic chemistryElectrodePhysical chemistryEngineeringElectrocatalysts for Energy ConversionCatalytic Processes in Materials ScienceCO2 Reduction Techniques and Catalysts