Litcius/Paper detail

Ullmann-Like Covalent Bond Coupling without Participation of Metal Atoms

Teng Zhang, Renyi Li, Xiaoyu Hao, Quanzhen Zhang, Huixia Yang, Yanhui Hou, Baofei Hou, Liangguang Jia, Kaiyue Jiang, Yu Zhang, Xu Wu, Xiaodong Zhuang, Liwei Liu, Yugui Yao, Wei Guo, Yeliang Wang

2023ACS Nano13 citationsDOI

Abstract

Ullmann-like on-surface synthesis is one of the most appropriate approaches for the bottom-up fabrication of covalent organic nanostructures and many successes have been achieved. The Ullmann reaction requires the oxidative addition of a catalyst (a metal atom in most cases): the metal atom will insert into a carbon–halogen bond, forming organometallic intermediates, which are then reductively eliminated and form C–C covalent bonds. As a result, traditional Ullmann coupling involves reactions of multiple steps, making it difficult to control the final product. Moreover, forming the organometallic intermediates will potentially poison the metal surface catalytic reactivity. In the study, we used the 2D h BN, an atomically thin sp 2 -hybridized sheet with a large band gap, to protect the Rh(111) metal surface. It is an ideal 2D platform to decouple the molecular precursor from the Rh(111) surface while maintaining the reactivity of Rh(111). We realize an Ullmann-like coupling of a planar biphenylene-based molecule, i.e., 1,8-dibromobiphenylene (BPBr 2 ), on an h BN/Rh(111) surface with an ultrahigh selectivity of the biphenylene dimer product, containing 4-, 6-, and 8-membered rings. The reaction mechanism, including electron wave penetration and the template effect of the h BN, is elucidated by combining low-temperature scanning tunneling microscopy and density functional theory calculations. Our findings are expected to play an essential role regarding the high-yield fabrication of functional nanostructures for future information devices.

Topics & Concepts

Covalent bondMetalCoupling (piping)Materials scienceUllmann reactionBondChemistryChemical physicsComputational chemistryNanotechnologyCopperOrganic chemistryMetallurgyBusinessFinanceSurface Chemistry and CatalysisMolecular Junctions and NanostructuresAsymmetric Hydrogenation and Catalysis