The coherent interaction between quantum emitters and photonic modes in cavities underlies many of the current strategies aiming at generating and controlling photonic quantum states. A plasmonic nanocavity provides a powerful solution for reducing the effective mode volumes down to nanometre scale, but spatial control at the atomic scale of the coupling with a single molecular emitter is challenging. Here we demonstrate sub-nanometre spatial control over the coherent coupling between a single molecule and a plasmonic nanocavity in close proximity by monitoring the evolution of Fano lineshapes and photonic Lamb shifts in tunnelling electron-induced luminescence spectra. The evolution of the Fano dips allows the determination of the effective interaction distance of ∼1 nm, coupling strengths reaching ∼15 meV and a giant self-interaction induced photonic Lamb shift of up to ∼3 meV. These results open new pathways to control quantum interference and field–matter interaction at the nanoscale.
Electrically driven molecular light emitters are considered to be one of the promising candidates as single-photon sources. However, it is yet to be demonstrated that electrically driven single-photon emission can indeed be generated from an isolated single molecule notwithstanding fluorescence quenching and technical challenges. Here, we report such electrically driven single-photon emission from a well-defined single molecule located inside a precisely controlled nanocavity in a scanning tunneling microscope. The effective quenching suppression and nanocavity plasmonic enhancement allow us to achieve intense and stable single-molecule electroluminescence. Second-order photon correlation measurements reveal an evident photon antibunching dip with the single-photon purity down to g
(2)(0) = 0.09, unambiguously confirming the single-photon emission nature of the single-molecule electroluminescence. Furthermore, we demonstrate an ultrahigh-density array of identical single-photon emitters.
The strong spatial confinement of a plasmonic field has made it possible to visualize the inner structure of a single molecule and even distinguish the vibrational modes in real space 1-4 . With such ever-improved spatial resolution, it is anticipated that full vibrational imaging of a molecule could be achieved to reveal molecular structural details. Here, we present a new technique, named as scanning Raman microscopy, to utilize for visually constructing the chemical structure of a single molecule. It is achieved by taking advantage of three key elements. First, the full mapping of individual vibrational modes with Ångström-level resolution allows to visually determine the placements of atoms or chemical bonds. Second, the positiondependent interference effect for symmetric and anti-symmetric vibrations enables to identify the connectivity of the chemical groups involved. The third element is the combination of spectromicroscopic images and Raman fingerprints for different chemical groups that conclusively ensures the definite arrangement of constituent
Probing
bond breaking and making as well as related structural
changes at the single-molecule level is of paramount importance for
understanding the mechanism of chemical reactions. In this work, we
report in situ tracking of bond breaking and making
of an up-standing melamine molecule chemisorbed on Cu(100) by subnanometer
resolved tip-enhanced Raman spectroscopy (TERS). We demonstrate a
vertical detection depth of about 4 Å with spectral sensitivity
at the single chemical-bond level, which allows us not only to justify
the up-standing configuration involving a dehydrogenation process
at the bottom upon chemisorption, but also to specify the breaking
of top N–H bonds and the transformation to its tautomer during
photon-induced hydrogen transfer reactions. Our results indicate the
chemical and structural sensitivity of TERS for single-molecule recognition
beyond flat-lying planar molecules, providing new opportunities for
probing the microscopic mechanism of molecular adsorption and surface
reactions at the chemical-bond level.
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