Theoretical studies of a novel photo-switchable self-organized peptide system
Literature Information
Publication Date
2003-05-01
DOI
10.1039/B300549F
Impact Factor
3.676
Authors
Wenwen Qu, Hongwei Tan, Guangju Chen, Ruozhuang Liu
View Original
Abstract
Synthetic organic functional nanomaterials have been the subject of intense study lately due to their potential use in many fields. As a result, theoretical studies of such materials have also received extensive attention. In this paper, seven models of a novel photo-switchable self-organized peptide system were optimized using the semi-empirical molecular orbital method AM1, and single point calculations of three of them were investigated by means of the density functional B3LYP/3-21G* method. The geometries, energetics and frontier orbital interactions of these photo-switchable peptide subsystems were calculated and analyzed. Our results provide insight into the formation, self-assembly and photo-isomerization of the system. Weak interactions between two polypeptide rings, especially hydrogen-bonding interactions, are crucial for stabilizing the conformation and self-assembly. Remarkably, oligomers of the E form show almost no cooperative effect, strongly supporting the notion that it is possible to break the intermolecular hydrogen bonds to enable E → Z isomerization reactions. Moreover, the polypeptide rings strengthen the conjugation effect on azobenzene subunits and lead to a reduction in the frontier molecular orbital energy differences. The self-assembling process of the E form also reinforces frontier orbital interactions and favors E → Z isomerization.
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Source Journal
Physical Chemistry Chemical Physics
CiteScore:
5.5
Self-citation Rate:
10.3%
Articles per Year:
3036
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