W. P. Ambrose scite author profile

Recent advances in fluorescence excitation spectroscopy with high efficiency have produced greatly improved optical spectra for the first electronic transition of individual single molecules of pentacene in p-terphenyl crystals at low temperatures (1.5 to 10 K). Two classes of single molecule behavior are observed: class I molecules have time-independent resonance frequencies, and class II molecules show a diffusive motion among several resonant frequencies with time which we term ‘‘spectral diffusion’’ by analogy with a similar effect which is common in amorphous materials. The temperature dependence of the linewidth and the power dependence of the fluorescence emission rate and of the linewidth are reported and analyzed. Various forms of the surprising class II behavior are described, including jumping among several discrete frequencies, creeping toward the center of the inhomogeneous line in many small steps, and a wandering among many possible resonance frequencies. The occurrence of class II behavior is restricted to the wings of the inhomogeneous line suggesting that the effect is correlated with some form of local disorder. The spectral diffusion rate increases with increasing temperature, suggesting that the effect may be due to phonon-assisted transitions of local degrees of freedom around the pentacene defect whose source remains to be identified conclusively.

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Alterations of Single Molecule Fluorescence Lifetimes in Near-Field Optical Microscopy

Ambrose

Goodwin

Keller

et al. 1994

Science

343

206

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Fluorescence lifetimes of single Rhodamine 6G molecules on silica surfaces were measured with pulsed laser excitation, time-correlated single photon counting, and near-field scanning optical microscopy (NSOM). The fluorescence lifetime varies with the position of a molecule relative to a near-field probe. Qualitative features of lifetime decreases are consistent with molecular excited state quenching effects near metal surfaces. The technique of NSOM provides a means of altering the environment of a single fluorescent molecule and its decay kinetics in a repeatable fashion.

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Single molecule detection and photochemistry on a surface using near-field optical excitation

et al. 1994

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Single-Molecule Fluorescence Analysis in Solution

et al. 1996

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W. P. Ambrose

Fluorescence spectroscopy and spectral diffusion of single impurity molecules in a crystal

Detection and spectroscopy of single pentacene molecules in a p-terphenyl crystal by means of fluorescence excitation

Alterations of Single Molecule Fluorescence Lifetimes in Near-Field Optical Microscopy

Single molecule detection and photochemistry on a surface using near-field optical excitation

Single-Molecule Fluorescence Analysis in Solution

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