Journal
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY
Volume 131, Issue 2, Pages 849-854Publisher
AMER CHEMICAL SOC
DOI: 10.1021/ja8080154
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Funding
- NSF [EEC0118025, CHE-0414554, BES-0507036]
- AFOSR DURIP [FA9550-07-1-0526]
- DTRA JSTO [FA9550-06-1-0558]
- AFOSR/DARPA [(FA9550-08-1-0221]
- NSF NSEC program [EEC-0647560]
- NSF MRSEC [DMR-0520513]
- Materials Research Center of Northwestern University
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The surface-enhanced Raman excitation profiles (REPS) of rhodamine 6G (R6G) on Ag surfaces are studied using a tunable optical parametric oscillator excitation source and versatile detection scheme. These experiments afford the ability to finely tune the excitation wavelength near the molecular resonance of R6G (i.e., similar to 500-575 nm) and perform wavelength-scanned surface-enhanced Raman excitation measurements of a single molecule. The ensemble-averaged surface-enhanced REPS are measured for collections of molecules on Ag island films. The relative contributions of the 0-0 and 0-1 vibronic transitions to the surface-enhanced REPS vary with vibrational frequency. These results highlight the role of excitation energy in determining the resonance Raman intensities for R6G on surface-enhancing nanostructures. Single-molecule measurements are obtained from individual molecules of R6G on Ag colloidal aggregates, where single-molecule junctions are located using the isotope-edited approach. Overall, single-molecule surface-enhanced REPS are narrow in comparison to the ensemble-averaged excitation profiles due to a reduction in inhomogeneous broadening. This work describes the first Raman excitation spectroscopy studies of a single molecule, revealing new information previously obscured by the ensemble.
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