Twisted Molecular Structure on Tuning Ultralong Organic Phosphorescence

Chen Sun; Xueqin Ran; Xuan Wang; Zhichao Cheng; Qi Wu; Suzhi Cai; Long Gu; Nan Gan; Huixian Shi; Zhongfu An; Huifang Shi; Wei Huang

doi:10.1021/acs.jpclett.7b02953

Twisted Molecular Structure on Tuning Ultralong Organic Phosphorescence

Chen Sun, Xueqin Ran, Xuan Wang, Zhichao Cheng, Qi Wu, Suzhi Cai, Long Gu, Nan Gan, Huixian Shi, Zhongfu An, Huifang Shi, Wei Huang

SCHOOL OF FLEXIBLE ELECTRONICS(FUTURE TECHNOLOGIES)|INSTITUTE OF ADVANCED MATERIALS(IAM)

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Abstract

Compared to planar carbazole, the molecular conjugation of iminodibenzyl (Id) was destroyed by a C-C bond and a twisted structure was formed, which exhibited blue-shifted ultralong phosphorescence with a lifetime of 402 ms in a crystal under ambient conditions. For the presence of an oscillating C-C bond between the two benzene rings in Id, more than one molecular configuration in the crystal was discovered by X-ray single-crystal analysis. Moreover, its ultralong phosphorescence color changed from blue to green by varying the excitation wavelength in solution at 77 K. Theoretical calculations also confirmed that different molecular configurations had certain impact on the phosphorescent photophysical properties. This result will allow a major step forward in expanding the scope of ultralong organic phosphorescent (UOP) materials, building a bridge to realize the relationship between molecular structure and UOP property.

Original language	English
Pages (from-to)	335-339
Number of pages	5
Journal	Journal of Physical Chemistry Letters
Volume	9
Issue number	2
DOIs	https://doi.org/10.1021/acs.jpclett.7b02953
State	Published - 18 Jan 2018

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title = "Twisted Molecular Structure on Tuning Ultralong Organic Phosphorescence",

abstract = "Compared to planar carbazole, the molecular conjugation of iminodibenzyl (Id) was destroyed by a C-C bond and a twisted structure was formed, which exhibited blue-shifted ultralong phosphorescence with a lifetime of 402 ms in a crystal under ambient conditions. For the presence of an oscillating C-C bond between the two benzene rings in Id, more than one molecular configuration in the crystal was discovered by X-ray single-crystal analysis. Moreover, its ultralong phosphorescence color changed from blue to green by varying the excitation wavelength in solution at 77 K. Theoretical calculations also confirmed that different molecular configurations had certain impact on the phosphorescent photophysical properties. This result will allow a major step forward in expanding the scope of ultralong organic phosphorescent (UOP) materials, building a bridge to realize the relationship between molecular structure and UOP property.",

author = "Chen Sun and Xueqin Ran and Xuan Wang and Zhichao Cheng and Qi Wu and Suzhi Cai and Long Gu and Nan Gan and Huixian Shi and Zhongfu An and Huifang Shi and Wei Huang",

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doi = "10.1021/acs.jpclett.7b02953",

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T1 - Twisted Molecular Structure on Tuning Ultralong Organic Phosphorescence

AU - Sun, Chen

AU - Ran, Xueqin

AU - Wang, Xuan

AU - Cheng, Zhichao

AU - Wu, Qi

AU - Cai, Suzhi

AU - Gu, Long

AU - Gan, Nan

AU - Shi, Huixian

AU - An, Zhongfu

AU - Shi, Huifang

AU - Huang, Wei

PY - 2018/1/18

Y1 - 2018/1/18

N2 - Compared to planar carbazole, the molecular conjugation of iminodibenzyl (Id) was destroyed by a C-C bond and a twisted structure was formed, which exhibited blue-shifted ultralong phosphorescence with a lifetime of 402 ms in a crystal under ambient conditions. For the presence of an oscillating C-C bond between the two benzene rings in Id, more than one molecular configuration in the crystal was discovered by X-ray single-crystal analysis. Moreover, its ultralong phosphorescence color changed from blue to green by varying the excitation wavelength in solution at 77 K. Theoretical calculations also confirmed that different molecular configurations had certain impact on the phosphorescent photophysical properties. This result will allow a major step forward in expanding the scope of ultralong organic phosphorescent (UOP) materials, building a bridge to realize the relationship between molecular structure and UOP property.

AB - Compared to planar carbazole, the molecular conjugation of iminodibenzyl (Id) was destroyed by a C-C bond and a twisted structure was formed, which exhibited blue-shifted ultralong phosphorescence with a lifetime of 402 ms in a crystal under ambient conditions. For the presence of an oscillating C-C bond between the two benzene rings in Id, more than one molecular configuration in the crystal was discovered by X-ray single-crystal analysis. Moreover, its ultralong phosphorescence color changed from blue to green by varying the excitation wavelength in solution at 77 K. Theoretical calculations also confirmed that different molecular configurations had certain impact on the phosphorescent photophysical properties. This result will allow a major step forward in expanding the scope of ultralong organic phosphorescent (UOP) materials, building a bridge to realize the relationship between molecular structure and UOP property.

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EP - 339

JO - Journal of Physical Chemistry Letters

JF - Journal of Physical Chemistry Letters

IS - 2

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Twisted Molecular Structure on Tuning Ultralong Organic Phosphorescence

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