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Energy Transfer Processes in the Excited States of an {[Ir(N C) 2(N N)] +-Rhodamine} Dyad : An Experimental and Theoretical Study. / Критченков, Илья Сергеевич; Мельников, А. С.; Сердобинцев, П.С.; Ходорковский, Михаил Алексеевич; Павловский, Владимир Владимирович; Порсев, Виталий Вениаминович; Туник, Сергей Павлович.

In: ChemPhotoChem, Vol. 6, No. 11, e202200048, 11.2022.

Research output: Contribution to journalArticlepeer-review

Harvard

Критченков, ИС, Мельников, АС, Сердобинцев, ПС, Ходорковский, МА, Павловский, ВВ, Порсев, ВВ & Туник, СП 2022, 'Energy Transfer Processes in the Excited States of an {[Ir(N C) 2(N N)] +-Rhodamine} Dyad: An Experimental and Theoretical Study', ChemPhotoChem, vol. 6, no. 11, e202200048. https://doi.org/10.1002/cptc.202200048

APA

Критченков, И. С., Мельников, А. С., Сердобинцев, П. С., Ходорковский, М. А., Павловский, В. В., Порсев, В. В., & Туник, С. П. (2022). Energy Transfer Processes in the Excited States of an {[Ir(N C) 2(N N)] +-Rhodamine} Dyad: An Experimental and Theoretical Study. ChemPhotoChem, 6(11), [e202200048]. https://doi.org/10.1002/cptc.202200048

Vancouver

Критченков ИС, Мельников АС, Сердобинцев ПС, Ходорковский МА, Павловский ВВ, Порсев ВВ et al. Energy Transfer Processes in the Excited States of an {[Ir(N C) 2(N N)] +-Rhodamine} Dyad: An Experimental and Theoretical Study. ChemPhotoChem. 2022 Nov;6(11). e202200048. https://doi.org/10.1002/cptc.202200048

Author

Критченков, Илья Сергеевич ; Мельников, А. С. ; Сердобинцев, П.С. ; Ходорковский, Михаил Алексеевич ; Павловский, Владимир Владимирович ; Порсев, Виталий Вениаминович ; Туник, Сергей Павлович. / Energy Transfer Processes in the Excited States of an {[Ir(N C) 2(N N)] +-Rhodamine} Dyad : An Experimental and Theoretical Study. In: ChemPhotoChem. 2022 ; Vol. 6, No. 11.

BibTeX

@article{86b34af2c742472fac68ab14dab4446b,
title = "Energy Transfer Processes in the Excited States of an {[Ir(N C) 2(N N)] +-Rhodamine} Dyad: An Experimental and Theoretical Study",
abstract = "Herein we report synthesis, characterization and photophysical study of the luminescent dyad Ir-RhB containing two emissive centres: fluorescent (RhB = rhodamine B) and phosphorescent (Ir = orthometalated iridium complex), bound each other by aliphatic bridge. The absence or very weak electronic conjugation of these chromophores makes them nearly independent but their excited triplet states proved to be very close in energy that allows for reversible energy transfer between them. The dynamics of this process and variation in excited states population have been studied by using pump-probe technique in a wide range of lifetimes, from picosecond to microsecond domains. The observed transient absorption spectra and their time dependent variations were interpreted in terms of relatively simple kinetic model, where selective excitation of iridium-based chromophore affords the corresponding emissive triplet, followed by its equilibration with the rhodamine based triplet and simultaneous relaxation to the dyad ground state through phosphorescent emission. This model allows for analytical solution to give key characteristics of the dyad excited state dynamics, including the energy gap between the Ir and RhB triplets (?E=0.017 eV) and the rate constant of energy transfer (k Ir-RhB =6.0x10 8  s -1 ) between these excited states. The data derived from experimental study of the transient absorption kinetics were also verified by quantum chemical DFT and TD DFT calculations.",
keywords = "density functional calculations, dual emission, excited states, iridium, rhodamine B, transient absorption spectroscopy",
author = "Критченков, {Илья Сергеевич} and Мельников, {А. С.} and П.С. Сердобинцев and Ходорковский, {Михаил Алексеевич} and Павловский, {Владимир Владимирович} and Порсев, {Виталий Вениаминович} and Туник, {Сергей Павлович}",
note = "Publisher Copyright: {\textcopyright} 2022 Wiley-VCH GmbH.",
year = "2022",
month = nov,
doi = "10.1002/cptc.202200048",
language = "English",
volume = "6",
journal = "ChemPhotoChem",
issn = "2367-0932",
publisher = "Wiley-Blackwell",
number = "11",

}

RIS

TY - JOUR

T1 - Energy Transfer Processes in the Excited States of an {[Ir(N C) 2(N N)] +-Rhodamine} Dyad

T2 - An Experimental and Theoretical Study

AU - Критченков, Илья Сергеевич

AU - Мельников, А. С.

AU - Сердобинцев, П.С.

AU - Ходорковский, Михаил Алексеевич

AU - Павловский, Владимир Владимирович

AU - Порсев, Виталий Вениаминович

AU - Туник, Сергей Павлович

N1 - Publisher Copyright: © 2022 Wiley-VCH GmbH.

PY - 2022/11

Y1 - 2022/11

N2 - Herein we report synthesis, characterization and photophysical study of the luminescent dyad Ir-RhB containing two emissive centres: fluorescent (RhB = rhodamine B) and phosphorescent (Ir = orthometalated iridium complex), bound each other by aliphatic bridge. The absence or very weak electronic conjugation of these chromophores makes them nearly independent but their excited triplet states proved to be very close in energy that allows for reversible energy transfer between them. The dynamics of this process and variation in excited states population have been studied by using pump-probe technique in a wide range of lifetimes, from picosecond to microsecond domains. The observed transient absorption spectra and their time dependent variations were interpreted in terms of relatively simple kinetic model, where selective excitation of iridium-based chromophore affords the corresponding emissive triplet, followed by its equilibration with the rhodamine based triplet and simultaneous relaxation to the dyad ground state through phosphorescent emission. This model allows for analytical solution to give key characteristics of the dyad excited state dynamics, including the energy gap between the Ir and RhB triplets (?E=0.017 eV) and the rate constant of energy transfer (k Ir-RhB =6.0x10 8  s -1 ) between these excited states. The data derived from experimental study of the transient absorption kinetics were also verified by quantum chemical DFT and TD DFT calculations.

AB - Herein we report synthesis, characterization and photophysical study of the luminescent dyad Ir-RhB containing two emissive centres: fluorescent (RhB = rhodamine B) and phosphorescent (Ir = orthometalated iridium complex), bound each other by aliphatic bridge. The absence or very weak electronic conjugation of these chromophores makes them nearly independent but their excited triplet states proved to be very close in energy that allows for reversible energy transfer between them. The dynamics of this process and variation in excited states population have been studied by using pump-probe technique in a wide range of lifetimes, from picosecond to microsecond domains. The observed transient absorption spectra and their time dependent variations were interpreted in terms of relatively simple kinetic model, where selective excitation of iridium-based chromophore affords the corresponding emissive triplet, followed by its equilibration with the rhodamine based triplet and simultaneous relaxation to the dyad ground state through phosphorescent emission. This model allows for analytical solution to give key characteristics of the dyad excited state dynamics, including the energy gap between the Ir and RhB triplets (?E=0.017 eV) and the rate constant of energy transfer (k Ir-RhB =6.0x10 8  s -1 ) between these excited states. The data derived from experimental study of the transient absorption kinetics were also verified by quantum chemical DFT and TD DFT calculations.

KW - density functional calculations

KW - dual emission

KW - excited states

KW - iridium

KW - rhodamine B

KW - transient absorption spectroscopy

UR - https://www.mendeley.com/catalogue/3d814435-75f8-3949-bf09-d96294673b96/

UR - http://www.scopus.com/inward/record.url?scp=85136807013&partnerID=8YFLogxK

U2 - 10.1002/cptc.202200048

DO - 10.1002/cptc.202200048

M3 - Article

VL - 6

JO - ChemPhotoChem

JF - ChemPhotoChem

SN - 2367-0932

IS - 11

M1 - e202200048

ER -

ID: 96209030