Self-Assembled Multifunctional 3D Microdevices

Daeha Joung; Kriti Agarwal; Hyeong Ryeol Park; Chao Liu; Sang Hyun Oh; Jeong Hyun Cho

doi:10.1002/aelm.201500459

Self-Assembled Multifunctional 3D Microdevices

Daeha Joung, Kriti Agarwal, Hyeong Ryeol Park, Chao Liu, Sang Hyun Oh, Jeong Hyun Cho

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Abstract

Multifunctional 3D microstructures have been extensively investigated for the development of new classes of electronic and optical devices. Here, functionalized, free-standing, hollow, 3D, dielectric (150 nm thick aluminum oxide) microcontainers with metal patterning on their surfaces are realized by an evolved self-assembly approach. To functionalize the 3D structure and use it as a device, metal patterns, arrays of split-ring resonators (SRRs) acting as metamaterials, are defined on the surface of the 3D dielectric microcontainers. The SRRs on all six facets of a given microcube show a resonant behavior in terahertz regimes. Since desired metal and semiconductor patterns can be incorporated onto surfaces of 3D dielectric microstructures, this self-assembly process can be harnessed in developing next-generation microdevices utilizing the numerous advantages of 3D configurations.

Original language	English (US)
Article number	1500459
Journal	Advanced Electronic Materials
Volume	2
Issue number	6
DOIs	https://doi.org/10.1002/aelm.201500459
State	Published - Jun 1 2016

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Publisher Copyright:
© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

Keywords

3D microstructures
functionalization
self-assembly
surface patterning
THz split ring resonators

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title = "Self-Assembled Multifunctional 3D Microdevices",

abstract = "Multifunctional 3D microstructures have been extensively investigated for the development of new classes of electronic and optical devices. Here, functionalized, free-standing, hollow, 3D, dielectric (150 nm thick aluminum oxide) microcontainers with metal patterning on their surfaces are realized by an evolved self-assembly approach. To functionalize the 3D structure and use it as a device, metal patterns, arrays of split-ring resonators (SRRs) acting as metamaterials, are defined on the surface of the 3D dielectric microcontainers. The SRRs on all six facets of a given microcube show a resonant behavior in terahertz regimes. Since desired metal and semiconductor patterns can be incorporated onto surfaces of 3D dielectric microstructures, this self-assembly process can be harnessed in developing next-generation microdevices utilizing the numerous advantages of 3D configurations.",

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AU - Agarwal, Kriti

AU - Park, Hyeong Ryeol

AU - Liu, Chao

AU - Oh, Sang Hyun

AU - Cho, Jeong Hyun

PY - 2016/6/1

Y1 - 2016/6/1

N2 - Multifunctional 3D microstructures have been extensively investigated for the development of new classes of electronic and optical devices. Here, functionalized, free-standing, hollow, 3D, dielectric (150 nm thick aluminum oxide) microcontainers with metal patterning on their surfaces are realized by an evolved self-assembly approach. To functionalize the 3D structure and use it as a device, metal patterns, arrays of split-ring resonators (SRRs) acting as metamaterials, are defined on the surface of the 3D dielectric microcontainers. The SRRs on all six facets of a given microcube show a resonant behavior in terahertz regimes. Since desired metal and semiconductor patterns can be incorporated onto surfaces of 3D dielectric microstructures, this self-assembly process can be harnessed in developing next-generation microdevices utilizing the numerous advantages of 3D configurations.

AB - Multifunctional 3D microstructures have been extensively investigated for the development of new classes of electronic and optical devices. Here, functionalized, free-standing, hollow, 3D, dielectric (150 nm thick aluminum oxide) microcontainers with metal patterning on their surfaces are realized by an evolved self-assembly approach. To functionalize the 3D structure and use it as a device, metal patterns, arrays of split-ring resonators (SRRs) acting as metamaterials, are defined on the surface of the 3D dielectric microcontainers. The SRRs on all six facets of a given microcube show a resonant behavior in terahertz regimes. Since desired metal and semiconductor patterns can be incorporated onto surfaces of 3D dielectric microstructures, this self-assembly process can be harnessed in developing next-generation microdevices utilizing the numerous advantages of 3D configurations.

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Self-Assembled Multifunctional 3D Microdevices

Abstract

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Keywords

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