Photoluminescence microscopy of conjugated polymer molecules in a polyethylene host has been applied to monitor the transition of a phase-separated polymer blend into a molecular dispersion induced by solid-state tensile deformation. Statistical analysis of conjugated polymer cluster sizes as a function of the degree of matrix deformation shows that phase-separated domains of conjugated polymer transform into smaller clusters and single molecules as the degree of matrix deformation increases. Concomitantly, the conjugated guest molecules tend to adopt the preferential orientation of the surrounding matrix. We demonstrate that single-molecule detection can be readily extended and applied to probing molecular dispersion, orientation, and morphology in polymer−polymer blends.
ACS Full Text Snapshot:C\:\\Users\\scherzad\\Zotero\\storage\\BXUQEZ8P\\jp000213a.html:text/html;Trabesinger et al. - 2000 - Single-Molecule Imaging Revealing the Deformation-.pdf:C\:\\Users\\scherzad\\Zotero\\storage\\NWTSEY67\\Trabesinger et al. - 2000 - Single-Molecule Imaging Revealing the Deformation-.pdf:application/pdf
%0 Journal Article
%1 trabesinger2000singlemolecule
%A Trabesinger, Werner
%A Renn, Alois
%A Hecht, Bert
%A Wild, Urs P.
%A Montali, Andrea
%A Smith, Paul
%A Weder, Christoph
%D 2000
%J J. Phys. Chem.
%K experiment nano-optics single-molecules
%N 22
%P 5221-5224
%R 10.1021/jp000213a
%T Single-Molecule Imaging Revealing the Deformation-Induced Formation of a Molecular Polymer Blend
%V 104
%X Photoluminescence microscopy of conjugated polymer molecules in a polyethylene host has been applied to monitor the transition of a phase-separated polymer blend into a molecular dispersion induced by solid-state tensile deformation. Statistical analysis of conjugated polymer cluster sizes as a function of the degree of matrix deformation shows that phase-separated domains of conjugated polymer transform into smaller clusters and single molecules as the degree of matrix deformation increases. Concomitantly, the conjugated guest molecules tend to adopt the preferential orientation of the surrounding matrix. We demonstrate that single-molecule detection can be readily extended and applied to probing molecular dispersion, orientation, and morphology in polymer−polymer blends.
@article{trabesinger2000singlemolecule,
abstract = {Photoluminescence microscopy of conjugated polymer molecules in a polyethylene host has been applied to monitor the transition of a phase-separated polymer blend into a molecular dispersion induced by solid-state tensile deformation. Statistical analysis of conjugated polymer cluster sizes as a function of the degree of matrix deformation shows that phase-separated domains of conjugated polymer transform into smaller clusters and single molecules as the degree of matrix deformation increases. Concomitantly, the conjugated guest molecules tend to adopt the preferential orientation of the surrounding matrix. We demonstrate that single-molecule detection can be readily extended and applied to probing molecular dispersion, orientation, and morphology in polymer−polymer blends.},
added-at = {2020-02-10T14:32:55.000+0100},
author = {Trabesinger, Werner and Renn, Alois and Hecht, Bert and Wild, Urs P. and Montali, Andrea and Smith, Paul and Weder, Christoph},
biburl = {https://www.bibsonomy.org/bibtex/28974d34cd579397d7b8da9d504795a0b/ep5optics},
day = 01,
doi = {10.1021/jp000213a},
file = {ACS Full Text Snapshot:C\:\\Users\\scherzad\\Zotero\\storage\\BXUQEZ8P\\jp000213a.html:text/html;Trabesinger et al. - 2000 - Single-Molecule Imaging Revealing the Deformation-.pdf:C\:\\Users\\scherzad\\Zotero\\storage\\NWTSEY67\\Trabesinger et al. - 2000 - Single-Molecule Imaging Revealing the Deformation-.pdf:application/pdf},
interhash = {9d3e46273d48d56807576a1d685d43f5},
intrahash = {8974d34cd579397d7b8da9d504795a0b},
issn = {1520-6106},
journal = {J. Phys. Chem.},
keywords = {experiment nano-optics single-molecules},
month = {06},
number = 22,
pages = {5221-5224},
timestamp = {2020-02-10T14:32:55.000+0100},
title = {Single-Molecule Imaging Revealing the Deformation-Induced Formation of a Molecular Polymer Blend},
urldate = {2020-02-10},
volume = 104,
year = 2000
}