Numerical investigation of nematic liquid crystals in the THz band based on EIT sensor

Peng Yuan Wang; Tao Jin; Fan Yi Meng; Yue Long Lyu; Daniel Erni; Qun Wu; Lei Zhu

doi:10.1364/OE.26.012318

Numerical investigation of nematic liquid crystals in the THz band based on EIT sensor

Peng Yuan Wang
, Tao Jin
, Fan Yi Meng
, Yue Long Lyu
, Daniel Erni
, Qun Wu
, Lei Zhu

Research output: Journal Publication › Article › peer-review

24 Citations (Scopus)

Abstract

This paper introduces the concept of electromagnetically induced transparency (EIT) into the permittivity extraction of an anisotropic material—nematic liquid crystal (NLC). A novel two-step strategy is presented to extract the complex permittivity of the NLC at the THz band, which evaluates the relative permittivity tensor from the resonant frequencies and then determines the loss tangent from the quality factor Q of the EIT sensor. The proposed method features high accuracy due to the sharp resonance of the EIT sensor and also high robustness to the thickness of the NLC layer because only amplitude rather than phase information of the transmission coefficients is required. The NLC filled EIT sensor shows a sensitivity of 56.8 μm/RIU (the resonance wavelength shift over the refractive index change unit (RIU)) and Figure of Merit (FoM) of 6.92. The uncertainty of the proposed technique in the relative permittivity and loss tangent is 3% and 8.2%, respectively.

Original language	English
Article number	Y
Pages (from-to)	12318-12329
Number of pages	12
Journal	Optics Express
Volume	26
Issue number	9
DOIs	https://doi.org/10.1364/OE.26.012318
Publication status	Published - 30 Apr 2018
Externally published	Yes

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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10.1364/OE.26.012318

Cite this

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title = "Numerical investigation of nematic liquid crystals in the THz band based on EIT sensor",

abstract = "This paper introduces the concept of electromagnetically induced transparency (EIT) into the permittivity extraction of an anisotropic material—nematic liquid crystal (NLC). A novel two-step strategy is presented to extract the complex permittivity of the NLC at the THz band, which evaluates the relative permittivity tensor from the resonant frequencies and then determines the loss tangent from the quality factor Q of the EIT sensor. The proposed method features high accuracy due to the sharp resonance of the EIT sensor and also high robustness to the thickness of the NLC layer because only amplitude rather than phase information of the transmission coefficients is required. The NLC filled EIT sensor shows a sensitivity of 56.8 μm/RIU (the resonance wavelength shift over the refractive index change unit (RIU)) and Figure of Merit (FoM) of 6.92. The uncertainty of the proposed technique in the relative permittivity and loss tangent is 3\% and 8.2\%, respectively.",

author = "Wang, \{Peng Yuan\} and Tao Jin and Meng, \{Fan Yi\} and Lyu, \{Yue Long\} and Daniel Erni and Qun Wu and Lei Zhu",

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AU - Wang, Peng Yuan

AU - Jin, Tao

AU - Meng, Fan Yi

AU - Lyu, Yue Long

AU - Erni, Daniel

AU - Wu, Qun

AU - Zhu, Lei

PY - 2018/4/30

Y1 - 2018/4/30

N2 - This paper introduces the concept of electromagnetically induced transparency (EIT) into the permittivity extraction of an anisotropic material—nematic liquid crystal (NLC). A novel two-step strategy is presented to extract the complex permittivity of the NLC at the THz band, which evaluates the relative permittivity tensor from the resonant frequencies and then determines the loss tangent from the quality factor Q of the EIT sensor. The proposed method features high accuracy due to the sharp resonance of the EIT sensor and also high robustness to the thickness of the NLC layer because only amplitude rather than phase information of the transmission coefficients is required. The NLC filled EIT sensor shows a sensitivity of 56.8 μm/RIU (the resonance wavelength shift over the refractive index change unit (RIU)) and Figure of Merit (FoM) of 6.92. The uncertainty of the proposed technique in the relative permittivity and loss tangent is 3% and 8.2%, respectively.

AB - This paper introduces the concept of electromagnetically induced transparency (EIT) into the permittivity extraction of an anisotropic material—nematic liquid crystal (NLC). A novel two-step strategy is presented to extract the complex permittivity of the NLC at the THz band, which evaluates the relative permittivity tensor from the resonant frequencies and then determines the loss tangent from the quality factor Q of the EIT sensor. The proposed method features high accuracy due to the sharp resonance of the EIT sensor and also high robustness to the thickness of the NLC layer because only amplitude rather than phase information of the transmission coefficients is required. The NLC filled EIT sensor shows a sensitivity of 56.8 μm/RIU (the resonance wavelength shift over the refractive index change unit (RIU)) and Figure of Merit (FoM) of 6.92. The uncertainty of the proposed technique in the relative permittivity and loss tangent is 3% and 8.2%, respectively.

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Numerical investigation of nematic liquid crystals in the THz band based on EIT sensor

Abstract

ASJC Scopus subject areas

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