Chen Guo, Ding Xiao-Lv, He Piao, Cheng Tao, Chen Yang, Lin Jian, Zhang Xi, Zhao Shan, Qiao Na, Yi Xiao-Yi
College of Chemistry and Chemical Engineering, Central South University Changsha Hunan 410083 P. R. China
School of Chemistry and Chemical Engineering, Southwest University Chongqing 400715 P. R. China.
Chem Sci. 2025 Mar 19;16(17):7573-7578. doi: 10.1039/d4sc02360a. eCollection 2025 Apr 30.
Precise regulation of the active site of molecular catalysts is appealing because it could provide insights into the catalytic mechanism and possibly provide a new strategy for catalyst design. A ruthenium complex, [Ru(dpp)(bipy)(Cl)] (CSU-3), containing -Me and -COMe substituted dipyridylpyrrole as a pincer ligand, was designed and synthesized. The CSU-3 complex featured a Cl ligand at the axial position as the active site for ammonia oxidation (AO), and is structurally analogous to AO catalyst [Ru(trpy)(dmabpy)(NH)][PF] (1) bearing a terpyridine ligand, but different from AO catalyst [Ru(dpp)(bipy)(NH)] (CSU-2) containing unsubstituted dipyridylpyrrole as a hemilabile ligand with the active site at an equatorial position. To gain insight into the role of active-site and ligand regulation in the AO reaction, the structure and electrochemical properties of CSU-3 and its catalytic performance and mechanism for the AO reaction were comparably studied. Complex CSU-3 has good selective catalytic performance for the oxidation of ammonia to hydrazine with a turnover frequency (TOF) of 258.8 h and NH formation selectivity of 84.7% at of 1.0 V. The DFT calculations reveal that NH as a dominant product is generated an ammonia nucleophilic attack of ruthenium(iv)-imide to form NH followed by NH-by-NH substitution.
精确调控分子催化剂的活性位点很有吸引力,因为它可以为催化机理提供见解,并可能为催化剂设计提供新策略。设计并合成了一种钌配合物[Ru(dpp)(bipy)(Cl)](CSU-3),其中含有 -Me和-COMe取代的二吡啶基吡咯作为钳形配体。CSU-3配合物在轴向位置具有Cl配体作为氨氧化(AO)的活性位点,其结构类似于带有三联吡啶配体的AO催化剂[Ru(trpy)(dmabpy)(NH)][PF](1),但不同于含有未取代二吡啶基吡咯作为半不稳定配体且活性位点在赤道位置的AO催化剂[Ru(dpp)(bipy)(NH)](CSU-2)。为了深入了解活性位点和配体调控在AO反应中的作用,对CSU-3的结构和电化学性质及其AO反应的催化性能和机理进行了比较研究。配合物CSU-3对氨氧化为肼具有良好的选择性催化性能,在1.0 V时的周转频率(TOF)为258.8 h,肼生成选择性为84.7%。密度泛函理论(DFT)计算表明,作为主要产物的肼是通过钌(IV)-亚胺的氨亲核进攻形成NH,然后通过NH-by-NH取代生成的。
