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Combining high-resolution scanning tunnelling microscopy and first-principles simulations to identify halogen bonding

James Lawrence, Gabriele C. Sosso, Luka Đorđević∞, Harry Pinfold, Davide Bonifazi, Giovanni Costantini

2020Nature Communications61 citationsDOIOpen Access PDF

Abstract

Scanning tunnelling microscopy (STM) is commonly used to identify on-surface molecular self-assembled structures. However, its limited ability to reveal only the overall shape of molecules and their relative positions is not always enough to fully solve a supramolecular structure. Here, we analyse the assembly of a brominated polycyclic aromatic molecule on Au(111) and demonstrate that standard STM measurements cannot conclusively establish the nature of the intermolecular interactions. By performing high-resolution STM with a CO-functionalised tip, we clearly identify the location of rings and halogen atoms, determining that halogen bonding governs the assemblies. This is supported by density functional theory calculations that predict a stronger interaction energy for halogen rather than hydrogen bonding and by an electron density topology analysis that identifies characteristic features of halogen bonding. A similar approach should be able to solve many complex 2D supramolecular structures, and we predict its increasing use in molecular nanoscience at surfaces.

Topics & Concepts

Supramolecular chemistryIntermolecular forceScanning tunneling microscopeHalogen bondChemical physicsMoleculeHalogenDensity functional theoryHydrogen bondResolution (logic)Quantum tunnellingNanotechnologyMaterials scienceCrystallographyChemistryComputational chemistryComputer scienceOptoelectronicsAlkylArtificial intelligenceOrganic chemistrySurface Chemistry and CatalysisAdvanced Chemical Physics StudiesForce Microscopy Techniques and Applications