Effective permittivity and third-order nonlinear susceptibility for a dilute composite consisting of partially aligned nanorods

Yedidya Lior; Dan M. Marom

doi:10.1364/JOSAB.30.001864

Effective permittivity and third-order nonlinear susceptibility for a dilute composite consisting of partially aligned nanorods

Yedidya Lior^*, Dan M. Marom

^*Corresponding author for this work

The Institute of Applied Physics

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

3 Scopus citations

Abstract

The expected permittivity and third-order nonlinear susceptibility of a composite consisting of semiconductor nanorods (NRs) dispersed in a polymer host are derived using a generalized Maxwell Garnett model under various NR axis orientation statistics, achieved by an aligning electric field. The semiconductor NRs are analyzed as prolate spheroids and modeled as more realistic capsule shapes. From the angular distribution function of the NRs, the composite macroscopic characteristics are found for low filling fractions. As the alignment field strength increases, the composite optical properties asymptotically converge toward the nematic case. Aligning fields of order 10⁷ V/m are required for the optical properties to increase to half the value between random orientation and nematic array composites.

Original language	English
Pages (from-to)	1864-1871
Number of pages	8
Journal	Journal of the Optical Society of America B: Optical Physics
Volume	30
Issue number	7
DOIs	https://doi.org/10.1364/JOSAB.30.001864
State	Published - 1 Jul 2013

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abstract = "The expected permittivity and third-order nonlinear susceptibility of a composite consisting of semiconductor nanorods (NRs) dispersed in a polymer host are derived using a generalized Maxwell Garnett model under various NR axis orientation statistics, achieved by an aligning electric field. The semiconductor NRs are analyzed as prolate spheroids and modeled as more realistic capsule shapes. From the angular distribution function of the NRs, the composite macroscopic characteristics are found for low filling fractions. As the alignment field strength increases, the composite optical properties asymptotically converge toward the nematic case. Aligning fields of order 107 V/m are required for the optical properties to increase to half the value between random orientation and nematic array composites.",

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N2 - The expected permittivity and third-order nonlinear susceptibility of a composite consisting of semiconductor nanorods (NRs) dispersed in a polymer host are derived using a generalized Maxwell Garnett model under various NR axis orientation statistics, achieved by an aligning electric field. The semiconductor NRs are analyzed as prolate spheroids and modeled as more realistic capsule shapes. From the angular distribution function of the NRs, the composite macroscopic characteristics are found for low filling fractions. As the alignment field strength increases, the composite optical properties asymptotically converge toward the nematic case. Aligning fields of order 107 V/m are required for the optical properties to increase to half the value between random orientation and nematic array composites.

AB - The expected permittivity and third-order nonlinear susceptibility of a composite consisting of semiconductor nanorods (NRs) dispersed in a polymer host are derived using a generalized Maxwell Garnett model under various NR axis orientation statistics, achieved by an aligning electric field. The semiconductor NRs are analyzed as prolate spheroids and modeled as more realistic capsule shapes. From the angular distribution function of the NRs, the composite macroscopic characteristics are found for low filling fractions. As the alignment field strength increases, the composite optical properties asymptotically converge toward the nematic case. Aligning fields of order 107 V/m are required for the optical properties to increase to half the value between random orientation and nematic array composites.

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Effective permittivity and third-order nonlinear susceptibility for a dilute composite consisting of partially aligned nanorods

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