Excited state proton transfer in indole-2-carboxylic acid and indole-5-carboxylic acid

Citation
Pr. Bangal et S. Chakravorti, Excited state proton transfer in indole-2-carboxylic acid and indole-5-carboxylic acid, J PHYS CH A, 103(43), 1999, pp. 8585-8594
Citations number
40
Categorie Soggetti
Physical Chemistry/Chemical Physics
Journal title
JOURNAL OF PHYSICAL CHEMISTRY A
ISSN journal
10895639 → ACNP
Volume
103
Issue
43
Year of publication
1999
Pages
8585 - 8594
Database
ISI
SICI code
1089-5639(19991028)103:43<8585:ESPTII>2.0.ZU;2-Z
Abstract
Intramolecular excited state proton transfer in indole-2-carboxylic acid (I 2C) and indore-5-carboxylic acid (I5C) was investigated in various solvents in acidic, basic, and neutral media by steady state and time-resolved fluo rescence spectroscopy. Hidden dual fluorescence of I2C in polar and nonpola r solvents and distinct dual fluorescence of I5C in nonpolar solvents and b road structureless fluorescence band in polar solvent (which is composed of two fluorescence bands) are assigned to be arising out from Franck-Condon excited state and from proton transferred excited state, i.e., from zwitter ionic form, respectively. The modulation of proton transfer equilibrium con stant in beta-CD cavity has also been investigated for both the molecules. For I5C it has been observed that in protic solvents intramolecular proton transfer is blocked by H-bond formation with solvent molecules surrounding it but when it enters into the beta-CD cavity intramolecular proton transfe r in the excited state could be observed again. The excited state proton tr ansfer equilibrium constant was calculated from a fluorescence band shape a nalysis, and its large solvent dependence arises primarily from local solut e-solvent interaction. As the instrument time resolution was 500 ps, only m onoexponential fluorescence decay could be observed for all excitation wave lengths and this showed that the proton transfer (rise time) was considerab ly faster than fluorescence decay. Structural change and large dipole momen t in the excited state as revealed from quantum chemical calculations with AM1 Hamiltonian point to the tendency of proton transfer in first excited s inglet state and also hindrance of that in the ground state.