Accessing Energetically Restricted Optical Transitions in a Single Free-Base Porphyrin Molecule
Abstract: Characterizing the electronic properties of single atoms, molecules, and nanostructures is the hallmark of scanning tunneling microscopy (STM). Recently, exploration of a complex manifold of nonequilibrium many-body electron configurations has been enabled by the development of STM electroluminescence methods (STML). STML provides access to optical properties of individual molecules through a cascade of relaxation processes between many-body states that obey energy conservation. Insufficient charge attachment energies quench the relaxation cascade via optically excited states, causing even intrinsically bright molecules to remain dark in STML. Here, we leverage substrate work function control and tip-induced gating of the double barrier tunnel junction to induce an energy shift of the ionic transition state of a single free-base tetrabenzoporphyrin (H2TBP) to gain access to optically excited states and bright exciton emission. The experimental observations are validated by a rate equation and polaron model considering the relaxation energy of the NaCl decoupling layer upon charging of the molecule.
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