2D Vibrational Exciton Nanoimaging of Domain Formation in Self-Assembled Monolayers
journal contributionposted on 22.06.2021, 15:34 by Thomas P. Gray, Jun Nishida, Samuel C. Johnson, Markus B. Raschke
Order, disorder, and domains affect many of the functional properties in self-assembled monolayers (SAMs). However, carrier transport, wettability, and chemical reactivity are often associated with collective effects, where conventional imaging techniques have limited sensitivity to the underlying intermolecular coupling. Here we demonstrate vibrational excitons as a molecular ruler of intermolecular wave function delocalization and nanodomain size in SAMs. In the model system of a 4-nitrothiophenol (4-NTP) SAM on gold, we resolve coupling-induced peak shifts of the nitro symmetric stretch mode with full spatio-spectral infrared scattering scanning near-field optical microscopy. From modeling of the underlying 2D Hamiltonian, we infer domain sizes and their distribution ranging from 3 to 12 nm across a field of view on the micrometer scale. This approach of vibrational exciton nanoimaging is generally applicable to study structural phases and domains in SAMs and other molecular interfaces.
Read the peer-reviewed publication
micrometer scale2 D Vibrational Exciton Nanoimagingscanning near-fielddomain sizesnanodomain sizeimaging techniquesself-assembled monolayersSAMcarrier transportstretch modewave function delocalization12 nmDomain Formationchemical reactivityvibrational exciton nanoimagingvibrational excitonsSelf-Assembled Monolayers Ordermodel system2 Dcoupling-induced peak shiftsNTP