Optical trapping of small structures is a powerful tool for the manipulation and investigation of colloidal and particulate materials. The tight focus excitation requirements of optical trapping are well suited to confocal Raman microscopy. In this work, an inverted confocal Raman microscope is developed for studies of chemical reactions on single, optically trapped particles and applied to reactions used in solid-phase peptide synthesis. Optical trapping and levitation allow a particle to be moved away from the coverslip and into solution, avoiding fluorescence interference from the coverslip. More importantly, diffusion of reagents into the particle is not inhibited by a surface, so that reaction conditions mimic those of particles dispersed in solution. Optical trapping and levitation also maintain optical alignment, since the particle is centered laterally along the optical axis and within the focal plane of the objective, where both optical forces and light collection are maximized. Hour-long observations of chemical reactions on individual, trapped silica particles are reported. Using two-dimensional least-squares analysis methods, the Raman spectra collected during the course of a reaction can be resolved into component contributions. The resolved spectra of the time-varying species can be observed, as they bind to or cleave from the particle surface.
Potential-dependent surface-enhanced Raman scattering (SERS) spectra of the nitrile stretching mode were acquired from a series of monolayers composed of alkanethiols (HS(CH 2 ) x CH 3 , where 6 e x e 10) and mercaptododecanenitrile (HS(CH 2 ) 11 CN). These spectra were used to investigate the diffuse double layer at a silver electrode interface modified with mixed self-assembled monolayers (SAMs). The alkanethiol species acts to dilute the nitrile-terminated thiol to isolate the nitrile reporter group within the diffuse double-layer region. Nitrile groups co-immobilized with shorter diluent alkanethiol chains are placed more deeply into the diffuse double layer (relative to the methyl terminus of the surrounding alkanethiol). Interfacial electric fields, measured using observed Stark tuning rates of the nitrile stretching frequency, were examined as a function of SAM composition to map the structure of the diffuse double-layer region versus distance from the SAM/ solution interface. The trends in the experimental data are largely consistent with Gouy-Chapman theory, in which Stark tuning rates, and the interfacial electric fields from which they originate, depend on both distance of the probe from the electrode surface and the ionic strength of the aqueous phase. For measurements at the highest ionic strengths, the experimentally observed double layer appeared to extend further into solution than predicted by Guoy-Chapman theory, which is consistent with the finite size of hydrated ions and theoretical predictions of the effect of a hydrophobic interface on the structure of the adjacent water layer. The results demonstrate the ability of this spectroelectrochemical experiment to characterize diffuse double-layer structure at electrochemical interfaces on a subnanometer distance scale.
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