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DPPM-Bridged Binuclear Pt(II) Pincer Complexes: Chemistry, Structure, and Photophysics in Solution Revisited. / Шилов, Роман Алексеевич; Подкорытов, Иван Сергеевич; Кисель, Кристина Станиславовна; Галенко, Екатерина Евгениевна; Карпицкая, Дарья Олеговна; Родионов, Иван Алексеевич; Шакирова, Юлия Равилевна; Туник, Сергей Павлович.

в: Inorganic Chemistry, Том 63, № 24, 05.06.2024, стр. 11194–11208.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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@article{6cd4df1c73c647738da2e6ecc7e22a84,
title = "DPPM-Bridged Binuclear Pt(II) Pincer Complexes: Chemistry, Structure, and Photophysics in Solution Revisited",
abstract = "A series of luminescent binuclear ([dppm{Pt(NNC)}2]2+) and mononuclear ([PPh3Pt(NNC)]+) complexes containing pincer ligands were synthesized and characterized. Photophysical characteristics of both types of complexes were studied in dichloromethane solution. In the solid phase, the binuclear compounds adopt a syn configuration where the {Pt(NNC)} fragments are held together due to intramolecular Pt-Pt bonding and π-stacking of the pincer ligand aromatic systems. Analysis of the complexes{\textquoteright} molecular structure in solution by multinuclear NMR spectroscopy showed that the stacked intramolecular configuration is retained in fluid media, which is in complete agreement with a considerable red shift of the emission wavelength due to formation of the intramolecular Pt-Pt bond, leading to the transformation of an emissive excited state to 3MMLCT. It was also found that triethylamine quenches the emission of both types of complexes; the mechanism of quenching is a combination of dynamic and static channels of excited-state deactivation. In the case of binuclear complexes, deprotonation of the dppm methylene bridge by triethylamine also contributes to the chromophore quenching. To explain the observed chemistry of binuclear complex interactions with Et3N, a chemical equilibrium scheme was suggested, which was confirmed by quantitative monitoring of the 31P signal variations as a function of triethylamine concentration.",
author = "Шилов, {Роман Алексеевич} and Подкорытов, {Иван Сергеевич} and Кисель, {Кристина Станиславовна} and Галенко, {Екатерина Евгениевна} and Карпицкая, {Дарья Олеговна} and Родионов, {Иван Алексеевич} and Шакирова, {Юлия Равилевна} and Туник, {Сергей Павлович}",
year = "2024",
month = jun,
day = "5",
doi = "10.1021/acs.inorgchem.4c00984",
language = "English",
volume = "63",
pages = "11194–11208",
journal = "Inorganic Chemistry",
issn = "0020-1669",
publisher = "American Chemical Society",
number = "24",

}

RIS

TY - JOUR

T1 - DPPM-Bridged Binuclear Pt(II) Pincer Complexes: Chemistry, Structure, and Photophysics in Solution Revisited

AU - Шилов, Роман Алексеевич

AU - Подкорытов, Иван Сергеевич

AU - Кисель, Кристина Станиславовна

AU - Галенко, Екатерина Евгениевна

AU - Карпицкая, Дарья Олеговна

AU - Родионов, Иван Алексеевич

AU - Шакирова, Юлия Равилевна

AU - Туник, Сергей Павлович

PY - 2024/6/5

Y1 - 2024/6/5

N2 - A series of luminescent binuclear ([dppm{Pt(NNC)}2]2+) and mononuclear ([PPh3Pt(NNC)]+) complexes containing pincer ligands were synthesized and characterized. Photophysical characteristics of both types of complexes were studied in dichloromethane solution. In the solid phase, the binuclear compounds adopt a syn configuration where the {Pt(NNC)} fragments are held together due to intramolecular Pt-Pt bonding and π-stacking of the pincer ligand aromatic systems. Analysis of the complexes’ molecular structure in solution by multinuclear NMR spectroscopy showed that the stacked intramolecular configuration is retained in fluid media, which is in complete agreement with a considerable red shift of the emission wavelength due to formation of the intramolecular Pt-Pt bond, leading to the transformation of an emissive excited state to 3MMLCT. It was also found that triethylamine quenches the emission of both types of complexes; the mechanism of quenching is a combination of dynamic and static channels of excited-state deactivation. In the case of binuclear complexes, deprotonation of the dppm methylene bridge by triethylamine also contributes to the chromophore quenching. To explain the observed chemistry of binuclear complex interactions with Et3N, a chemical equilibrium scheme was suggested, which was confirmed by quantitative monitoring of the 31P signal variations as a function of triethylamine concentration.

AB - A series of luminescent binuclear ([dppm{Pt(NNC)}2]2+) and mononuclear ([PPh3Pt(NNC)]+) complexes containing pincer ligands were synthesized and characterized. Photophysical characteristics of both types of complexes were studied in dichloromethane solution. In the solid phase, the binuclear compounds adopt a syn configuration where the {Pt(NNC)} fragments are held together due to intramolecular Pt-Pt bonding and π-stacking of the pincer ligand aromatic systems. Analysis of the complexes’ molecular structure in solution by multinuclear NMR spectroscopy showed that the stacked intramolecular configuration is retained in fluid media, which is in complete agreement with a considerable red shift of the emission wavelength due to formation of the intramolecular Pt-Pt bond, leading to the transformation of an emissive excited state to 3MMLCT. It was also found that triethylamine quenches the emission of both types of complexes; the mechanism of quenching is a combination of dynamic and static channels of excited-state deactivation. In the case of binuclear complexes, deprotonation of the dppm methylene bridge by triethylamine also contributes to the chromophore quenching. To explain the observed chemistry of binuclear complex interactions with Et3N, a chemical equilibrium scheme was suggested, which was confirmed by quantitative monitoring of the 31P signal variations as a function of triethylamine concentration.

UR - https://www.mendeley.com/catalogue/4e44055d-c8bc-3cef-bed3-8732466ff61e/

U2 - 10.1021/acs.inorgchem.4c00984

DO - 10.1021/acs.inorgchem.4c00984

M3 - Article

VL - 63

SP - 11194

EP - 11208

JO - Inorganic Chemistry

JF - Inorganic Chemistry

SN - 0020-1669

IS - 24

ER -

ID: 120357102