The valence-bond charge-transfer-exciton model for predicting nonlinear optical properties (hyperpolarizabililies and saturation length) of polymeric materials

Daqi Lu; Guanhua Chen; William A. Goddard

doi:10.1063/1.467414

The valence-bond charge-transfer-exciton model for predicting nonlinear optical properties (hyperpolarizabililies and saturation length) of polymeric materials

Daqi Lu
, Guanhua Chen
, William A. Goddard

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

Abstract

A simple theory is developed and applied to the polarizability (α), second hyperpolarizability (γ), and the saturation lengths for nine polymeric materials. The theory is based on a valence bond view of the ground and excited states and considers the excited states as charge transfer excitons. It involves just two parameters which can be extracted from simple molecular orbital calculations and/or from experimental values of band gap and bandwidth. For the one system (oligothiophenes) with experimental data on saturation length, the predicted behavior of α and γ with polymer length is in good agreement with experiment.

Original language	English
Pages (from-to)	4920-4930
Number of pages	11
Journal	Journal of Chemical Physics
Volume	101
Issue number	6
DOIs	https://doi.org/10.1063/1.467414
Publication status	Published - 1 Jan 1994
Externally published	Yes

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title = "The valence-bond charge-transfer-exciton model for predicting nonlinear optical properties (hyperpolarizabililies and saturation length) of polymeric materials",

abstract = "A simple theory is developed and applied to the polarizability (α), second hyperpolarizability (γ), and the saturation lengths for nine polymeric materials. The theory is based on a valence bond view of the ground and excited states and considers the excited states as charge transfer excitons. It involves just two parameters which can be extracted from simple molecular orbital calculations and/or from experimental values of band gap and bandwidth. For the one system (oligothiophenes) with experimental data on saturation length, the predicted behavior of α and γ with polymer length is in good agreement with experiment.",

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AU - Goddard, William A.

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N2 - A simple theory is developed and applied to the polarizability (α), second hyperpolarizability (γ), and the saturation lengths for nine polymeric materials. The theory is based on a valence bond view of the ground and excited states and considers the excited states as charge transfer excitons. It involves just two parameters which can be extracted from simple molecular orbital calculations and/or from experimental values of band gap and bandwidth. For the one system (oligothiophenes) with experimental data on saturation length, the predicted behavior of α and γ with polymer length is in good agreement with experiment.

AB - A simple theory is developed and applied to the polarizability (α), second hyperpolarizability (γ), and the saturation lengths for nine polymeric materials. The theory is based on a valence bond view of the ground and excited states and considers the excited states as charge transfer excitons. It involves just two parameters which can be extracted from simple molecular orbital calculations and/or from experimental values of band gap and bandwidth. For the one system (oligothiophenes) with experimental data on saturation length, the predicted behavior of α and γ with polymer length is in good agreement with experiment.

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DO - 10.1063/1.467414

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The valence-bond charge-transfer-exciton model for predicting nonlinear optical properties (hyperpolarizabililies and saturation length) of polymeric materials

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