Choice of polymer matrix for a fast switchable III-V nanowire terahertz modulator

Sarwat A. Baig; Jessica L. Boland; Djamshid A. Damry; Hoe H. Tan; Chennupati Jagadish; Michael B. Johnston; Hannah J. Joyce

doi:10.1557/adv.2017.280

Choice of polymer matrix for a fast switchable III-V nanowire terahertz modulator

Sarwat A. Baig, Jessica L. Boland, Djamshid A. Damry, Hoe H. Tan, Chennupati Jagadish, Michael B. Johnston, Hannah J. Joyce

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

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Abstract

Progress in ultrafast terahertz (THz) communications has been limited due to the lack of picosecond switchable modulators with sufficient modulation depth. Gallium arsenide nanowires are ideal candidates for THz modulators as they absorb THz radiation, only when photoexcited - giving the potential for picosecend speed switching and high modulation depth. By embedding the nanowires in a polymer matrix and laminating together several nanowire-polymer films, we increase the areal density of nanowires, resulting in greater modulation of THz radiation. In this paper, we compare PDMS and Parylene C polymers for nanowire encapsulation and show that a high modulation depth is possible using Parylene C due to its thinness and its ability to be laminated. We characterize the modulator behavior and switching speed using optical pump- THz probe spectroscopy, and demonstrate a parylene-nanowire THz modulator with 13.5% modulation depth and 1ps switching speed.

Original language	English
Pages (from-to)	1475-1480
Number of pages	6
Journal	MRS Advances
Volume	2
Issue number	28
DOIs	https://doi.org/10.1557/adv.2017.280
Publication status	Published - 2017

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title = "Choice of polymer matrix for a fast switchable III-V nanowire terahertz modulator",

abstract = "Progress in ultrafast terahertz (THz) communications has been limited due to the lack of picosecond switchable modulators with sufficient modulation depth. Gallium arsenide nanowires are ideal candidates for THz modulators as they absorb THz radiation, only when photoexcited - giving the potential for picosecend speed switching and high modulation depth. By embedding the nanowires in a polymer matrix and laminating together several nanowire-polymer films, we increase the areal density of nanowires, resulting in greater modulation of THz radiation. In this paper, we compare PDMS and Parylene C polymers for nanowire encapsulation and show that a high modulation depth is possible using Parylene C due to its thinness and its ability to be laminated. We characterize the modulator behavior and switching speed using optical pump- THz probe spectroscopy, and demonstrate a parylene-nanowire THz modulator with 13.5% modulation depth and 1ps switching speed.",

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AU - Baig, Sarwat A.

AU - Boland, Jessica L.

AU - Damry, Djamshid A.

AU - Tan, Hoe H.

AU - Jagadish, Chennupati

AU - Johnston, Michael B.

AU - Joyce, Hannah J.

PY - 2017

Y1 - 2017

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AB - Progress in ultrafast terahertz (THz) communications has been limited due to the lack of picosecond switchable modulators with sufficient modulation depth. Gallium arsenide nanowires are ideal candidates for THz modulators as they absorb THz radiation, only when photoexcited - giving the potential for picosecend speed switching and high modulation depth. By embedding the nanowires in a polymer matrix and laminating together several nanowire-polymer films, we increase the areal density of nanowires, resulting in greater modulation of THz radiation. In this paper, we compare PDMS and Parylene C polymers for nanowire encapsulation and show that a high modulation depth is possible using Parylene C due to its thinness and its ability to be laminated. We characterize the modulator behavior and switching speed using optical pump- THz probe spectroscopy, and demonstrate a parylene-nanowire THz modulator with 13.5% modulation depth and 1ps switching speed.

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ER -

Choice of polymer matrix for a fast switchable III-V nanowire terahertz modulator

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