Open AccessPhotoisomerization Dynamics in a Densely Packed Optically Transformable Azobenzene Monolayer
Author(s) -
Kyle M. McElhinny,
Joonkyu Park,
Youngjun Ahn,
Peishen Huang,
Yongho Joo,
Arunee Lakkham,
Anastasios Pateras,
Haidan Wen,
Padma Gopalan,
Paul G. Evans
Publication year - 2018
Publication title -
langmuir
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.042
H-Index - 333
eISSN - 1520-5827
pISSN - 0743-7463
DOI - 10.1021/acs.langmuir.8b01524
Subject(s) - azobenzene , monolayer , photoisomerization , control reconfiguration , nanoscopic scale , chemical physics , nucleation , molecular dynamics , materials science , kinetics , molecular electronics , nanotechnology , chemistry , isomerization , photochemistry , molecule , computational chemistry , physics , organic chemistry , catalysis , computer science , quantum mechanics , embedded system
Molecular monolayers that can be reconfigured through the use of external stimuli promise to enable the creation of interfaces with precisely selected dynamically adjustable physical and electronic properties with potential impact ranging from electronics to energy storage. Azobenzene-containing molecular monolayers have multiple stable molecular conformations but face a challenging nanoscale problem associated with understanding the basic mechanisms of reconfiguration. Time-resolved X-ray reflectivity studies show that the reconfiguration of a densely packed rhenium-azobenzene monolayer occurs in a period of many seconds. The degree of reconfiguration from trans to cis forms depends on the integrated UV fluence and has kinetics that are consistent with a mechanism in which the transformation occurs through the nucleation and growth of nanoscale two-dimensional regions of the cis isomer.
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