Pivotal role of transition density in circularly polarized luminescence

Zhanxiang Chen; Manli Huang; Cheng Zhong; Shaolong Gong; Veaceslav Coropceanu; Jean Luc Brédas; Chuluo Yang

doi:10.1039/d3sc01809a

Pivotal role of transition density in circularly polarized luminescence

Zhanxiang Chen, Manli Huang, Cheng Zhong, Shaolong Gong, Veaceslav Coropceanu, Jean Luc Brédas, Chuluo Yang

Chemistry and Biochemistry

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Realizing high luminescence dissymmetry factor (g) in circularly polarized luminescence (CPL) materials remains a big challenge, which necessitates understanding systematically how their molecular structure controls the CPL. Here we investigate representative organic chiral emitters with different transition density distributions and reveal the pivotal role of transition density in CPL. We rationalize that to obtain large g-factors, two conditions should be simultaneously satisfied: (i) the transition density for the S₁ (or T₁)-to-S₀ emission must be delocalized over the entire chromophore; and (ii) the chromophore inter-segment twisting must be restricted and tuned to an optimal value (∼50°). Our findings offer molecular-level insights into the CPL of organic emitters, with potential applications in the design of chiroptical materials and systems with strong CPL effects.

Original language	English (US)
Pages (from-to)	6022-6031
Number of pages	10
Journal	Chemical Science
Volume	14
Issue number	22
DOIs	https://doi.org/10.1039/d3sc01809a
State	Published - May 12 2023

ASJC Scopus subject areas

General Chemistry

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10.1039/d3sc01809a

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title = "Pivotal role of transition density in circularly polarized luminescence",

abstract = "Realizing high luminescence dissymmetry factor (g) in circularly polarized luminescence (CPL) materials remains a big challenge, which necessitates understanding systematically how their molecular structure controls the CPL. Here we investigate representative organic chiral emitters with different transition density distributions and reveal the pivotal role of transition density in CPL. We rationalize that to obtain large g-factors, two conditions should be simultaneously satisfied: (i) the transition density for the S1 (or T1)-to-S0 emission must be delocalized over the entire chromophore; and (ii) the chromophore inter-segment twisting must be restricted and tuned to an optimal value (∼50°). Our findings offer molecular-level insights into the CPL of organic emitters, with potential applications in the design of chiroptical materials and systems with strong CPL effects.",

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AU - Chen, Zhanxiang

AU - Huang, Manli

AU - Zhong, Cheng

AU - Gong, Shaolong

AU - Coropceanu, Veaceslav

AU - Brédas, Jean Luc

AU - Yang, Chuluo

PY - 2023/5/12

Y1 - 2023/5/12

N2 - Realizing high luminescence dissymmetry factor (g) in circularly polarized luminescence (CPL) materials remains a big challenge, which necessitates understanding systematically how their molecular structure controls the CPL. Here we investigate representative organic chiral emitters with different transition density distributions and reveal the pivotal role of transition density in CPL. We rationalize that to obtain large g-factors, two conditions should be simultaneously satisfied: (i) the transition density for the S1 (or T1)-to-S0 emission must be delocalized over the entire chromophore; and (ii) the chromophore inter-segment twisting must be restricted and tuned to an optimal value (∼50°). Our findings offer molecular-level insights into the CPL of organic emitters, with potential applications in the design of chiroptical materials and systems with strong CPL effects.

AB - Realizing high luminescence dissymmetry factor (g) in circularly polarized luminescence (CPL) materials remains a big challenge, which necessitates understanding systematically how their molecular structure controls the CPL. Here we investigate representative organic chiral emitters with different transition density distributions and reveal the pivotal role of transition density in CPL. We rationalize that to obtain large g-factors, two conditions should be simultaneously satisfied: (i) the transition density for the S1 (or T1)-to-S0 emission must be delocalized over the entire chromophore; and (ii) the chromophore inter-segment twisting must be restricted and tuned to an optimal value (∼50°). Our findings offer molecular-level insights into the CPL of organic emitters, with potential applications in the design of chiroptical materials and systems with strong CPL effects.

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Pivotal role of transition density in circularly polarized luminescence

Abstract

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