Hiroaki Maeda, Eunice Jia Han Phua, Yuta Sudo, Sayoko Nagashima, Wentai Chen, Mayumi Fujino, Kenji Takada, Naoya Fukui, Hiroyasu Masunaga, Sono Sasaki, Kazuhito Tsukagoshi, Hiroshi Nishihara
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引用次数: 0
Abstract
Development of efficient electrocatalysts for hydrogen evolution reactions (HERs) is necessary to achieve environmentally friendly and sustainable hydrogen production. To reduce cost and to circumvent the scarcity of platinum, the most efficient catalyst for HER, it is essential to develop catalysts using ubiquitous base metals or minimal amounts of precious metals. Bis(diimino)metal (MDI) coordination nanosheets are potential HER catalysts because their electric conductivities, two-dimensionality, and porous structures provide large surface areas and efficient mass and electron transfer. In addition, with sparse metal arrangements in their chemical structures, nanosheets can reduce the amount of metal needed. We synthesized bis(diimino)palladium coordination nanosheets (PdDI) as a coordination polymer composed of bis(diimino)palladium, with semiconducting characteristics, using gas-liquid interfacial synthesis and electrochemical oxidation. These electrochemically synthesized PdDIs exhibit remarkable catalytic performance with overpotential reaching 10 mA cm-2 of 34 mV, a Tafel slope of 47 mV dec-1, and an exchange current density of 2.1 mA cm-2 after appropriate activation. This performance is closely comparable to that of metallic platinum. An ex-situ investigation of the activation process revealed that reduction of the divalent Pd center in bis(diimino)palladium produced a composite of Pd(0) species and PdDI, combining high catalytic activity with smooth electron transfer.
开发高效的析氢电催化剂是实现环境友好型和可持续制氢的必要条件。为了降低成本并避免铂(HER最有效的催化剂)的短缺,必须开发使用普遍存在的贱金属或最少量的贵金属的催化剂。双(二亚胺)金属(MDI)配位纳米片是潜在的HER催化剂,因为它们的导电性、二维性和多孔结构提供了大的表面积和有效的质量和电子传递。此外,纳米片的化学结构中有稀疏的金属排列,可以减少所需的金属量。采用气液界面合成和电化学氧化的方法,合成了具有半导体特性的双(二亚胺)钯配位聚合物(PdDI)。这些电化学合成的pddi具有显著的催化性能,经过适当的活化后,过电位达到34 mV的10 mA cm-2, Tafel斜率为47 mV dec1,交换电流密度为2.1 mA cm-2。这一性能与金属铂非常接近。对活化过程的原位研究表明,还原双(二亚)钯中的二价钯中心产生Pd(0)和PdDI的复合物,具有高催化活性和平滑的电子转移。
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Chemistry—A European Journal is a truly international journal with top quality contributions (2018 ISI Impact Factor: 5.16). It publishes a wide range of outstanding Reviews, Minireviews, Concepts, Full Papers, and Communications from all areas of chemistry and related fields.
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