Chatterjee Abhishikta, Mondal Papri, Chakraborty Priyanka, Mandal Sourav, Rizzoli Corrado, Gómez-García Carlos J, Adhikary Bibhutosh, Senapati Dulal, Dey Subrata K
Department of Chemistry, Sidho-Kanho-Birsha University, Purulia 723104, WB, India.
Department of Chemistry, Indian Institution of Engineering Science and Technology, Shibpur, Howrah 711103, India.
ACS Catal. 2025 Jan 27;15(3):2472-2483. doi: 10.1021/acscatal.4c06466. eCollection 2025 Feb 7.
Electrocatalytic water splitting is a challenging step toward hydrogen production to mitigate fossil fuel dependence. In nature, water oxidation is catalyzed by the MnCaO cluster in photosystem-II, but the design of synthetic molecular catalysts still remains a challenge. A few catalysts with low-cost abundant cobalt metal ions have been previously reported, although with low durability and high overpotentials. Here, we report two cobalt cluster catalysts with very low overpotentials and high stability for electrochemical water splitting. These two highly efficient heterogeneous bifunctional (BF) electrocatalysts (ECs), formulated as [CoL(HO)]·2.5HO () and [CoLCl] (), (L = ethyl-2-(picolinoylimino)-propanoate), are readily prepared from economical and nontoxic starting materials. The distortions of the coordination geometry around the cobalt atoms, due to the steric effects of the bulky ligand (L), modify the electronic environment of the cobalt centers and facilitate water coordination and subsequent splitting. Furthermore, targeted molecular level modifications on previously reported clusters have provided insight into multimetallic cooperativity and structure-activity relationships. Interestingly, , having a hitherto unknown CoO core, acts as an efficient water splitting EC. shows a higher activity than and very low overpotentials (η) for both the oxygen evolution reaction (OER) and hydrogen evolution reaction (HER) at 10 mA cm (η = 157 mV for the OER and 39.8 mV for the HER) and small Tafel slopes (40.0 mV dec for the OER and 40.4 mV dec for the HER). Additionally, also shows a high-performance alkaline HO electrolyzing capacity with a cell voltage of 1.486 V at 10 mA cm and exhibits remarkable long-term stability. Thus, our cheap BF molecular EC clearly opens up an innovative platform for scalable O and H production.
电催化水分解是减少对化石燃料依赖的制氢过程中具有挑战性的一步。在自然界中,水氧化由光系统II中的MnCaO簇催化,但合成分子催化剂的设计仍然是一个挑战。此前已报道了一些含有低成本且储量丰富的钴金属离子的催化剂,尽管其耐久性低且过电位高。在此,我们报道了两种用于电化学水分解的过电位极低且稳定性高的钴簇催化剂。这两种高效的多相双功能(BF)电催化剂(ECs),化学式为[CoL(HO)]·2.5HO ()和[CoLCl] (),(L = 2-(吡啶甲酰亚氨基)丙酸乙酯),可由经济且无毒的起始原料轻松制备。由于庞大配体(L)的空间效应,钴原子周围配位几何结构的扭曲改变了钴中心的电子环境,促进了水的配位及随后的分解。此外,对先前报道的簇进行有针对性的分子水平修饰,有助于深入了解多金属协同作用和结构 - 活性关系。有趣的是,具有迄今未知的CoO核心,作为一种高效的水分解电催化剂。在10 mA cm时,对于析氧反应(OER)和析氢反应(HER),显示出比更高的活性和非常低的过电位(η)(OER的η = 157 mV,HER的η = 39.8 mV)以及小的塔菲尔斜率(OER为40.0 mV dec,HER为40.4 mV dec)。此外,在10 mA cm时电池电压为1.486 V,还显示出高性能的碱性HO电解能力,并表现出显著的长期稳定性。因此,我们这种廉价的BF分子电催化剂显然为可扩展的O和H生产开辟了一个创新平台。
