Observation of Electron Orbital Signatures of Single Atoms Within Metal-phthalocyanines Using Atomic Force Microscopy

Overview

Journal Nat Commun

Specialty Biology

Date 2023 Mar 17

PMID 36928085

Authors

Pengcheng Chen

Dingxin Fan

Annabella Selloni

Emily A Carter

Craig B Arnold

Yunlong Zhang

Adam S Gross

James R Chelikowsky

Nan Yao

Affiliations

Soon will be listed here.

Abstract

Resolving the electronic structure of a single atom within a molecule is of fundamental importance for understanding and predicting chemical and physical properties of functional molecules such as molecular catalysts. However, the observation of the orbital signature of an individual atom is challenging. We report here the direct identification of two adjacent transition-metal atoms, Fe and Co, within phthalocyanine molecules using high-resolution noncontact atomic force microscopy (HR-AFM). HR-AFM imaging reveals that the Co atom is brighter and presents four distinct lobes on the horizontal plane whereas the Fe atom displays a "square" morphology. Pico-force spectroscopy measurements show a larger repulsion force of about 5 pN on the tip exerted by Co in comparison to Fe. Our combined experimental and theoretical results demonstrate that both the distinguishable features in AFM images and the variation in the measured forces arise from Co's higher electron orbital occupation above the molecular plane. The ability to directly observe orbital signatures using HR-AFM should provide a promising approach to characterizing the electronic structure of an individual atom in a molecular species and to understand mechanisms of certain chemical reactions.

Citing Articles

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