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引用次数: 0
摘要
通过浸渍法制备出了支撑在碳上的单分散铂纳米粒子(Pt/C)。通过改变初始试剂混合物中铂前驱体的浓度,可将平均粒径(d)控制在小于 2 纳米的狭窄范围内。当这些材料用于氧还原反应(ORR)时,其比活度(SA)在 1.8 nm 以下的范围内随着 d 的增大而迅速提高,在 d = 1.3 nm 时达到最大值。该值约为商用铂/碳化硼催化剂的四倍。电化学活性面积 ECAA(电化学表面积 (ECSA)/ 比表面积 (SSA) ×100)随着 d 值在 1.3 nm 以下的减小而从 100%急剧下降。在本研究中,我们提出了 SA 与 ECAA 之间的相关性,以此来确定聚合物电解质燃料电池 (PEFC) 的合适 d 值,并提出了最佳尺寸。
Size-Dependence of the Electrochemical Activity of Platinum Particles in the 1 to 2 Nanometer Range
Monodisperse Pt nanoparticles supported on carbon (Pt/C) were prepared via an impregnation method. By changing the concentration of the platinum precursor in the initial reagent mixture, the average particle size (d) could be controlled to within a narrow range of less than 2 nm. The specific activity (SA) of these materials, when applied to the oxygen reduction reaction (ORR), increased rapidly with d in the range below 1.8 nm, with a maximum SA at d = 1.3 nm. This value is approximately four times that of a commercial Pt/CB catalyst. The electrochemical active area, ECAA (electrochemical surface area (ECSA)/specific surface area (SSA) × 100), decreased drastically from 100% with decreases in d below 1.3 nm. In this study, we present a correlation between SA and ECAA as a means of determining the appropriate d for polymer electrolyte fuel cells (PEFCs) and propose an optimal size.
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