Jangid Dilip Kumar, Dastider Saptarshi G, Biswas Rathindranath, Khirid Samreet, Meena Sangeeta, Kumar Pankaj, Sahoo Subash C, Verma Ved Prakash, Makde Ravindra D, Kumar Ashwani, Jangir Ravindra, Mondal Krishnakanta, Haldar Krishna Kanta, Dhayal Rajendra S
Department of Chemistry, Central University of Punjab, Bathinda 151401, India.
Department of Physics, Central University of Punjab, Bathinda 151401, India.
Inorg Chem. 2022 Aug 29;61(34):13342-13354. doi: 10.1021/acs.inorgchem.2c01281. Epub 2022 Aug 12.
The dichalcogenide ligated molecules in catalysis to produce molecular hydrogen through electroreduction of water are rarely explored. Here, a series of heterometallic [Ag(SPFc(OR)] [where Fc = Fe(η-CH)(η-CH), R = Me, ; Et, ; Pr, ; Amyl, ] clusters were synthesized and characterized by IR, absorption spectroscopy, NMR (H, P), and electrospray ionization mass spectrometry. The molecular structures of , , and clusters were established by single-crystal X-ray crystallographic analysis. The structural elucidation shows that each triangular face of a tetrahedral silver(I) core is capped by a ferrocenyl dithiophosphonate ligand in a trimetallic triconnective (η; μ, μ) pattern. A comparative electrocatalytic hydrogen evolution reaction of - (R = Pr, ) was studied in order to demonstrate the potential of these clusters in water splitting activity. The experimental results reveal that catalytic performance decreases with increases in the length of the carbon chain and branching within the alkoxy (-OR) group of these clusters. Catalytic durability was found effective even after 8 h of a chronoamperometric stability test along with 1500 cycles of linear sweep voltammetry performance, and only 15 mV overpotential was increased at 5 mA/cm current density for cluster . A catalytic mechanism was proposed by applying density functional theory (DFT) on clusters and as a representative. Here, a μ coordinated S-site between Ag core and ligand was found a reaction center. The experimental results are also in good accordance with the DFT analysis.
通过水的电还原催化生成分子氢的二硫属化物连接分子鲜有研究。在此,合成了一系列异金属[Ag(SPFc(OR)](其中Fc = Fe(η - C₅H₅)(η - C₅H₄),R = 甲基、乙基、丙基、戊基)簇合物,并通过红外光谱、吸收光谱、核磁共振(¹H、³¹P)和电喷雾电离质谱进行了表征。通过单晶X射线晶体学分析确定了[Ag(SPFc(OMe)]、[Ag(SPFc(OEt)]和[Ag(SPFc(OPr)]簇合物的分子结构。结构解析表明,四面体银(I)核的每个三角形面都由二茂铁基二硫代膦酸酯配体以三金属三连接(η³;μ²,μ²)模式封端。研究了[Ag(SPFc(OPr)](R = 丙基)的比较电催化析氢反应,以证明这些簇合物在水分解活性方面的潜力。实验结果表明,这些簇合物的催化性能随着烷氧基(-OR)基团中碳链长度的增加和支化程度的增加而降低。即使在进行8小时的计时电流稳定性测试以及1500次线性扫描伏安法性能循环后,催化耐久性仍然有效,对于[Ag(SPFc(OPr)]簇合物,在5 mA/cm²电流密度下过电位仅增加了15 mV。以[Ag(SPFc(OPr)]和[Ag(SPFc(OEt)]簇合物为代表,应用密度泛函理论(DFT)提出了催化机理。在此,发现银核与配体之间的μ配位S位点是反应中心。实验结果也与DFT分析很好地吻合。
