Temporal effects on spectroscopic line shapes, resolution, and sensitivity of the broad-band sum frequency generation

Sum frequency generation (SFG) is a surface-selective spectroscopy that provides a wealth of molecular-level information on the structure and dynamics at surfaces and interfaces. This paper addresses the general issue of spectral resolution and sensitivity of the broad-band (BB) SFG that involves a...

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Veröffentlicht in:	The Journal of chemical physics 2010-06, Vol.132 (23), p.234503-234503-9
Hauptverfasser:	Stiopkin, Igor V., Jayathilake, Himali D., Weeraman, Champika, Benderskii, Alexander V.
Format:	Artikel
Sprache:	eng
Schlagworte:	Air Alkynes - chemistry Models, Theoretical Propionates - chemistry Spectrum Analysis - methods Spectrum Analysis - statistics & numerical data Time Factors Water - chemistry
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container_end_page	234503-9
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container_title	The Journal of chemical physics
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creator	Stiopkin, Igor V. Jayathilake, Himali D. Weeraman, Champika Benderskii, Alexander V.
description	Sum frequency generation (SFG) is a surface-selective spectroscopy that provides a wealth of molecular-level information on the structure and dynamics at surfaces and interfaces. This paper addresses the general issue of spectral resolution and sensitivity of the broad-band (BB) SFG that involves a spectrally narrow nonresonant (usually visible) and a BB resonant (usually infrared) laser pulses. We examine how the spectral width and temporal shape of the two pulses, and the time delay between them, relate to the spectroscopic line shape and signal level in the BB-SFG measurement. By combining experimental and model calculations, we show that the best spectral resolution and highest signal level are simultaneously achieved when the nonresonant narrow-band upconversion pulse arrives with a nonzero time delay after the resonant BB pulse. The nonzero time delay partially avoids the linear trade-off of improving spectral resolution at the expense of decreasing signal intensity, which is common in BB-SFG schemes utilizing spectral filtering to produce narrow-band visible pulses.
doi_str_mv	10.1063/1.3432776
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source	MEDLINE; AIP Journals Complete; AIP Digital Archive; Alma/SFX Local Collection
subjects	Air Alkynes - chemistry Models, Theoretical Propionates - chemistry Spectrum Analysis - methods Spectrum Analysis - statistics & numerical data Time Factors Water - chemistry
title	Temporal effects on spectroscopic line shapes, resolution, and sensitivity of the broad-band sum frequency generation
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