Transfer printed nanomembranes for heterogeneously integrated membrane photonics

Hongjun Yang; Deyin Zhao; Shihchia Liu; Yonghao Liu; Jung Hun Seo; Zhenqiang Ma; Weidong Zhou

doi:10.3390/photonics2041081

Transfer printed nanomembranes for heterogeneously integrated membrane photonics

Hongjun Yang
, Deyin Zhao
, Shihchia Liu
, Yonghao Liu
, Jung Hun Seo
, Zhenqiang Ma
, Weidong Zhou

Department of Materials Design and Innovation

University of Texas at Arlington
University of Wisconsin-Madison

Research output: Contribution to journal › Review article › peer-review

16 Scopus citations

Abstract

Heterogeneous crystalline semiconductor nanomembrane (NM) integration is investigated for single-layer and double-layer Silicon (Si) NM photonics, III-V/Si NM lasers, and graphene/Si NM total absorption devices. Both homogeneous and heterogeneous integration are realized by the versatile transfer printing technique. The performance of these integrated membrane devices shows, not only intact optical and electrical characteristics as their bulk counterparts, but also the unique light and matter interactions, such as Fano resonance, slow light, and critical coupling in photonic crystal cavities. Such a heterogeneous integration approach offers tremendous practical application potentials on unconventional, Si CMOS compatible, and high performance optoelectronic systems.

Original language	English
Pages (from-to)	1081-1100
Number of pages	20
Journal	Photonics
Volume	2
Issue number	4
DOIs	https://doi.org/10.3390/photonics2041081
State	Published - Dec 1 2015

Keywords

Critical coupling
Fano resonance
Heterogeneous integration
Photonic crystals
Semiconductor nanomembrane
Transfer printing

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10.3390/photonics2041081

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title = "Transfer printed nanomembranes for heterogeneously integrated membrane photonics",

abstract = "Heterogeneous crystalline semiconductor nanomembrane (NM) integration is investigated for single-layer and double-layer Silicon (Si) NM photonics, III-V/Si NM lasers, and graphene/Si NM total absorption devices. Both homogeneous and heterogeneous integration are realized by the versatile transfer printing technique. The performance of these integrated membrane devices shows, not only intact optical and electrical characteristics as their bulk counterparts, but also the unique light and matter interactions, such as Fano resonance, slow light, and critical coupling in photonic crystal cavities. Such a heterogeneous integration approach offers tremendous practical application potentials on unconventional, Si CMOS compatible, and high performance optoelectronic systems.",

keywords = "Critical coupling, Fano resonance, Heterogeneous integration, Photonic crystals, Semiconductor nanomembrane, Transfer printing",

author = "Hongjun Yang and Deyin Zhao and Shihchia Liu and Yonghao Liu and Seo, \{Jung Hun\} and Zhenqiang Ma and Weidong Zhou",

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doi = "10.3390/photonics2041081",

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TY - JOUR

T1 - Transfer printed nanomembranes for heterogeneously integrated membrane photonics

AU - Yang, Hongjun

AU - Zhao, Deyin

AU - Liu, Shihchia

AU - Liu, Yonghao

AU - Seo, Jung Hun

AU - Ma, Zhenqiang

AU - Zhou, Weidong

PY - 2015/12/1

Y1 - 2015/12/1

N2 - Heterogeneous crystalline semiconductor nanomembrane (NM) integration is investigated for single-layer and double-layer Silicon (Si) NM photonics, III-V/Si NM lasers, and graphene/Si NM total absorption devices. Both homogeneous and heterogeneous integration are realized by the versatile transfer printing technique. The performance of these integrated membrane devices shows, not only intact optical and electrical characteristics as their bulk counterparts, but also the unique light and matter interactions, such as Fano resonance, slow light, and critical coupling in photonic crystal cavities. Such a heterogeneous integration approach offers tremendous practical application potentials on unconventional, Si CMOS compatible, and high performance optoelectronic systems.

AB - Heterogeneous crystalline semiconductor nanomembrane (NM) integration is investigated for single-layer and double-layer Silicon (Si) NM photonics, III-V/Si NM lasers, and graphene/Si NM total absorption devices. Both homogeneous and heterogeneous integration are realized by the versatile transfer printing technique. The performance of these integrated membrane devices shows, not only intact optical and electrical characteristics as their bulk counterparts, but also the unique light and matter interactions, such as Fano resonance, slow light, and critical coupling in photonic crystal cavities. Such a heterogeneous integration approach offers tremendous practical application potentials on unconventional, Si CMOS compatible, and high performance optoelectronic systems.

KW - Critical coupling

KW - Fano resonance

KW - Heterogeneous integration

KW - Photonic crystals

KW - Semiconductor nanomembrane

KW - Transfer printing

UR - https://www.scopus.com/pages/publications/85018243789

U2 - 10.3390/photonics2041081

DO - 10.3390/photonics2041081

M3 - Review article

AN - SCOPUS:85018243789

SN - 2304-6732

VL - 2

SP - 1081

EP - 1100

JO - Photonics

JF - Photonics

IS - 4

ER -

Transfer printed nanomembranes for heterogeneously integrated membrane photonics

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Keywords

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