Atom-stepped surface-regulated Pd nanowires for boosting alcohol oxidation activity

A highly active surface can endow the electrocatalysts with extraordinary catalytic performances. However, it remains challenging to tailor the atomic packing characteristics and thus the physical and chemical characteristics of the electrocatalysts. Herein, penta-twinned Pd nanowires (NWs) with abundant high-energy atomic steps (i.e., stepped Pd) are synthesized by seeded synthesis on Pd NWs enclosed by (100) facets. Benefiting from the catalytically active atomic steps, such as [n(100) x m(111)] on the surface, the resultant stepped Pd NWs can work as an effective electrocatalyst for the ethanol oxidation reaction (EOR) and ethylene glycol oxidation reaction (EGOR), which are essential anode reactions in direct alcohol fuel cells (DAFCs). Compared with commercial Pd/C, the Pd nanowires bound by (100) facets and atomic steps both display enhanced catalytic activity and stability towards the EOR and EGOR. Importantly, the mass activities of the stepped Pd NWs toward the EOR and EGOR are 6.38 and 7.98 A mg(Pd)(-1), which are 3.1 and 2.6 times those of Pd NWs enclosed by (100) facets, respectively. Besides, our synthetic strategy also enables the formation of bimetallic Pd-Cu nanowires with abundant atomic steps. This work not only demonstrates a simple yet effective strategy to obtain mono- or bimetallic nanowires with abundant atomic steps, but also highlights the significant role of atomic steps for boosting the activity of electrocatalysts.

Automated summary

Penta-twinned Pd nanowires with abundant high-energy atomic steps have been synthesized and they exhibit superior catalytic activity for ethanol and ethylene glycol oxidation reactions. These stepped Pd nanowires show enhanced catalytic performance and stability compared to commercial Pd/C. The mass activities of stepped Pd nanowires for EOR and EGOR are 6.38 and 7.98 A mg(Pd)(-1), respectively, which are 3.1 and 2.6 times higher than Pd nanowires enclosed by (100) facets.