Nanoporous Gold for Energy Applications

Research activities using nanoporous gold (NPG) were reviewed in the field of energy applications in three categories: fuel cells, supercapacitors, and batteries. First, applications to fuel cells are reviewed with the subsections of proof-of-concept studies, studies on fuel oxidations at anode, and studies on oxygen reduction reactions at cathode. Second, applications to supercapacitors are reviewed from research activities on active materials/NPG composites to demonstrations of all-solid-state flexible supercapacitors using NPG electrodes. Third, research activities using NPG for battery applications are reviewed, mainly about fundamental studies on Li-air and Na-air batteries and some model studies on improving Li ion battery anodes. Although NPG based studies are the main subject of this review, some of meaningful studies using nanoporous metals are also discussed where relevant. Finally, summary and future outlook are given based on the survey on the research activities.

Facile solvothermal synthesis of Pt71Co29 lamellar nanoflowers as an efficient catalyst for oxygen reduction and methanol oxidation reactions

The research for highly efficient and stable electrocatalysts in fuel cells has attracted substantial interest. Herein, bimetallic alloyed Pt₇₁Co₂₉ lamellar nanoflowers (LNFs) with abundant active sites were obtained by a one-pot solvothermal method, where cetyltrimethylammonium chloride (CTAC) and 1-nitroso-2-naphthol (1-N-2-N) served as co-structure-directors, while oleylamine (OAm) as the solvent and reducing agent. The fabricated Pt₇₁Co₂₉ LNFs exhibited the higher mass activity (MA, 128.29 mA mg^-1) for oxygen reduction reaction (ORR) than those of home-made Pt₄₈Co₅₂ nanodendrites (NDs), Pt₇₉Co₂₁ NDs and commercial Pt black with the values of 39.46, 49.42 and 22.91 mA mg^-1, respectively. Meanwhile, the MA (666.23 mA mg^-1) and specific activity (SA, 2.51 mA cm^-2) of the constructed Pt₇₁Co₂₉ LNFs for methanol oxidation reaction (MOR) are superior than those of Pt₄₈Co₅₂ NDs (213.91 mA mg^-1, 1.99 mA cm^-2), Pt₇₉Co₂₁ NDs (210.09 mA mg^-1, 1.12 mA cm^-2) and Pt black (57.03 mA mg^-1, 0.25 mA cm^-2). Also, the Pt₇₁Co₂₉ LNFs catalyst exhibited the best durable ability relative to the references. This work demonstrates that the developed strategy provides a facile platform for synthesis of high-performance, low-cost and robust catalysts in practical catalysis, energy storage and conversion.