Premium
Influence of Donor on the Sensing Performance of a Series of Through‐Bond Energy Transfer‐Based Two‐photon Fluorescent Cu 2+ Probes
Author(s) -
Zhang YuJin,
Wang Xin,
Zhou Yong,
Wang ChuanKui
Publication year - 2016
Publication title -
photochemistry and photobiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.818
H-Index - 131
eISSN - 1751-1097
pISSN - 0031-8655
DOI - 10.1111/php.12597
Subject(s) - fluorescence , photochemistry , acceptor , chemistry , density functional theory , moiety , quinoline , förster resonance energy transfer , quenching (fluorescence) , rhodamine , derivative (finance) , computational chemistry , stereochemistry , physics , organic chemistry , financial economics , economics , condensed matter physics , quantum mechanics
Abstract Optical properties of a series of molecular two‐photon fluorescent Cu 2+ probes containing the same acceptor (rhodamine group) are analyzed using time‐dependent density functional theory in combination with analytical response theory. Special emphasis is placed on evolution of the probes' optical properties in the presence of Cu 2+ . In this study, the compound with naphthalene as the donor is shown to be excellent ratiometric fluorescent chemosensor, whereas the compound with quinoline derivative as the donor shows off/on‐typed colorimetric fluorescent response. For the compound with naphthalimide derivative as the donor, changing the connection between the donor and acceptor can efficiently prevent the fluorescent quenching of the probe both in the absence and presence of Cu 2+ . The donor moiety and the connection between donor and acceptor are thus found to play dominant roles on sensing performance of these probes. Moreover, distributions of molecular orbitals involved in the excitation and emission of the probes are analyzed to explore responsive mechanism of the probes. The through‐bond energy transfer process is theoretically demonstrated. Our results are used to elucidate the available experimental measurements. This work is helpful to understand the relationships of structure with optical properties for the studied probes.