Abstract
THE ability to observe the optical spectrum of a single molecule can afford insights into the interactions that distinguish one molecular environment from another. Such sensitivity has recently been achieved at liquid-helium temperatures1–5. Here we show that the near-field scanning optical microscope6,7 can be used to obtain the time-dependent emission spectrum of a single molecule in air at room temperature, with a spatial resolution of about 100 nm. We have examined single molecules of l,l'-dioctadecyl-3,3,3',3'-tetra-methylindocarbocyanine (dil) dispersed on polymethylmethacrylate. The spectra of individual molecules exhibit shifts of ±8 nm relative to the average spectrum, and are typically narrower, as is expected for spectral lines broadened inhomogeneously (that is, by a distribution of molecular environments). The spectra also vary in width by up to 8 nm, some being as broad as the far-field many-molecule spectrum. The emission spectra of some individual mol-ecules exhibit time-dependent shifts of up to 10 nm. This variety in spectral position, width, shape and time dependence can be understood within a model of inhomogeneous broadening in which there is a distribution of barrier heights to rearrangement of the molecular environment.
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Trautman, J., Macklin, J., Brus, L. et al. Near-field spectroscopy of single molecules at room temperature. Nature 369, 40–42 (1994). https://doi.org/10.1038/369040a0
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DOI: https://doi.org/10.1038/369040a0
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