AI Article Synopsis
- A series of 2-pyridyl-pyrazole derivatives with five-membered ring hydrogen bonding were created, demonstrating varying structural flexibility that affects their behavior.
- The research focused on how changes in molecular structure influence excited-state intramolecular proton transfer (ESIPT), revealing that increased structural constraints reduce the rate of ESIPT.
- At low concentrations, ESIPT occurs in derivatives 1 and 2 but not in 3 and 4 due to higher geometric restrictions; when concentration rises, dimerization happens for most compounds, leading to a change in luminescence.
Article Abstract
A series of 2-pyridyl-pyrazole derivatives 1-4 possessing five-membered ring hydrogen bonding configuration are synthesized, the structural flexibility of which is strategically tuned to be in the order of 1 > 2 > 3 > 4. This system then serves as an ideal chemical model to investigate the correlation between excited-state intramolecular proton transfer (ESIPT) reaction and molecular skeleton motion associated with hydrogen bonds. The resulting luminescence data reveal that the rate of ESIPT decreases upon increasing the structural constraint. At sufficiently low concentration where negligible dimerization is observed, ESIPT takes place in 1 and 2 but is prohibited in 3 and 4, for which high geometry constraint is imposed. The results imply that certain structural bending motions associated with hydrogen bonding angle/distance play a key role in ESIPT. This trend is also well supported by the DFT computational approach, in which the barrier associated with ESIPT is in the order of 1 < 2 < 3 < 4. Upon increasing the concentration in cyclohexane, except for 2, the rest of the title compounds undergo ground-state dimerization, from which the double proton transfer takes place in the excited state, resulting in a relatively blue shifted dimeric tautomer emission (cf. the monomer tautomer emission). The lack of dimerization in 2 is rationalized by substantial energy required to adjust the angle of hydrogen bond via twisting the propylene bridge prior to dimerization.
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| http://dx.doi.org/10.1039/c2cp23938h | DOI Listing |
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