Near infrared filtering properties in photonic crystal containing extrinsic and dispersive semiconductor defect

Chi Chung Liu; Chien Jang Wu

doi:10.2528/PIER13010107

Near infrared filtering properties in photonic crystal containing extrinsic and dispersive semiconductor defect

Chi Chung Liu, Chien Jang Wu^*

^*Corresponding author for this work

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

12 Citations (Scopus)

Abstract

In this work, near infrared filtering properties in a transmission narrowband filter are theoretically investigated. The filter is a defective photonic crystal of (LH)^ND(HL)^N, where N is the stack number, L is SiO₂, H is InP, and defect layer D is an extrinsic semiconductor of n-type silicon (n-Si). It is found that there are multiple transmission peaks within the photonic band gap (PBG) as the defect thickness increases. The filtering position can be changed by varying the doping density in n-Si. That is, the peak (channel) wavelength is blued-shifted when the doping density increases. In the angle-dependent filtering property, the channel wavelength is also blued-shifted as the angle of incidence increases for both TE and TM waves. These filtering properties are of technical use in the applications of semiconductor optoelectronics.

Original language	English
Pages (from-to)	359-370
Number of pages	12
Journal	Progress in Electromagnetics Research
Volume	137
DOIs	https://doi.org/10.2528/PIER13010107
Publication status	Published - 2013
Externally published	Yes

ASJC Scopus subject areas

Radiation
Condensed Matter Physics
Electrical and Electronic Engineering

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abstract = "In this work, near infrared filtering properties in a transmission narrowband filter are theoretically investigated. The filter is a defective photonic crystal of (LH)ND(HL)N, where N is the stack number, L is SiO2, H is InP, and defect layer D is an extrinsic semiconductor of n-type silicon (n-Si). It is found that there are multiple transmission peaks within the photonic band gap (PBG) as the defect thickness increases. The filtering position can be changed by varying the doping density in n-Si. That is, the peak (channel) wavelength is blued-shifted when the doping density increases. In the angle-dependent filtering property, the channel wavelength is also blued-shifted as the angle of incidence increases for both TE and TM waves. These filtering properties are of technical use in the applications of semiconductor optoelectronics.",

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year = "2013",

doi = "10.2528/PIER13010107",

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journal = "Progress in Electromagnetics Research",

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T1 - Near infrared filtering properties in photonic crystal containing extrinsic and dispersive semiconductor defect

AU - Liu, Chi Chung

AU - Wu, Chien Jang

PY - 2013

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N2 - In this work, near infrared filtering properties in a transmission narrowband filter are theoretically investigated. The filter is a defective photonic crystal of (LH)ND(HL)N, where N is the stack number, L is SiO2, H is InP, and defect layer D is an extrinsic semiconductor of n-type silicon (n-Si). It is found that there are multiple transmission peaks within the photonic band gap (PBG) as the defect thickness increases. The filtering position can be changed by varying the doping density in n-Si. That is, the peak (channel) wavelength is blued-shifted when the doping density increases. In the angle-dependent filtering property, the channel wavelength is also blued-shifted as the angle of incidence increases for both TE and TM waves. These filtering properties are of technical use in the applications of semiconductor optoelectronics.

AB - In this work, near infrared filtering properties in a transmission narrowband filter are theoretically investigated. The filter is a defective photonic crystal of (LH)ND(HL)N, where N is the stack number, L is SiO2, H is InP, and defect layer D is an extrinsic semiconductor of n-type silicon (n-Si). It is found that there are multiple transmission peaks within the photonic band gap (PBG) as the defect thickness increases. The filtering position can be changed by varying the doping density in n-Si. That is, the peak (channel) wavelength is blued-shifted when the doping density increases. In the angle-dependent filtering property, the channel wavelength is also blued-shifted as the angle of incidence increases for both TE and TM waves. These filtering properties are of technical use in the applications of semiconductor optoelectronics.

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Near infrared filtering properties in photonic crystal containing extrinsic and dispersive semiconductor defect

Abstract

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