Fluorescence microscopy and spectroscopy of subsurface layer dynamics of polymers with nanometer resolution in the axial direction
Author:
Affiliation:
1. Institute for Spectroscopy
2. Russian Academy of Sciences
3. 142190 Moscow
4. Russia
5. Moscow Institute of Physics and Technology
6. University of Bayreuth
7. Institute of Physics and BIMF
8. 95440 Bayreuth
9. Germany
Abstract
We studied the dynamics in ultrathin subsurface layers of an amorphous polymer by the spectra of single fluorescent molecules embedded into the layer by vapor deposition and subsequent controlled diffusion to the desired depth in ≈0.5 nm steps. The spectral trails of single molecules were recorded at 4.5 K as a function of diffusion depth. In depths shallower than 20 nm, the spectral dynamics deviate from those deep in the bulk. Less than 5 nm deep, the linewidths increase rapidly, whereas the number of detected molecules decreases. No zero-phonon lines were observed closer than 0.5 nm to the polymer surface. Possible physical reasons of the observed phenomena are discussed.
Funder
Deutsche Forschungsgemeinschaft
Russian Foundation for Basic Research
Publisher
Royal Society of Chemistry (RSC)
Subject
Physical and Theoretical Chemistry
Link
http://pubs.rsc.org/en/content/articlepdf/2015/FD/C5FD00055F
Reference20 articles.
1. Low-Temperature Confocal Microscopy on Individual Molecules near a Surface
2. Does the Standard Model of Low-Temperature Glass Dynamics Describe a Real Glass?
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