Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications
The creation of CMOS compatible light sources is an important step for the realization of electronic-photonic integrated circuits. An efficient CMOS-compatible light source is considered the final missing component towards achieving this goal. In this work, we present a novel crossbeam structure wit...
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sg-ntu-dr.10356-1488362021-05-17T09:29:28Z Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications Jung, Yongduck Kim, Youngmin Burt, Daniel Joo, Hyo-Jun Kang, Dong-Ho Luo, Manlin Chen, Melvina Lin, Zhang Tan, Chuan Seng Nam, Donguk School of Electrical and Electronic Engineering Centre for OptoElectronics and Biophotonics (OPTIMUS) Engineering::Electrical and electronic engineering Germanium Photonics The creation of CMOS compatible light sources is an important step for the realization of electronic-photonic integrated circuits. An efficient CMOS-compatible light source is considered the final missing component towards achieving this goal. In this work, we present a novel crossbeam structure with an embedded optical cavity that allows both a relatively high and fairly uniform biaxial strain of ~0.9% in addition to a high-quality factor of >4,000 simultaneously. The induced biaxial strain in the crossbeam structure can be conveniently tuned by varying geometrical factors that can be defined by conventional lithography. Comprehensive photoluminescence measurements and analyses confirmed that optical gain can be significantly improved via the combined effect of low temperature and high strain, which is supported by a three-fold reduction of the full width at half maximum of a cavity resonance at ~1,940 nm. Our demonstration opens up the possibility of further improving the performance of germanium lasers by harnessing geometrically amplified biaxial strain. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) National Research Foundation (NRF) Published version 2021-05-17T09:29:28Z 2021-05-17T09:29:28Z 2021 Journal Article Jung, Y., Kim, Y., Burt, D., Joo, H., Kang, D., Luo, M., Chen, M., Lin, Z., Tan, C. S. & Nam, D. (2021). Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications. Optics Express, 29(10), 14174-14181. https://dx.doi.org/10.1364/OE.417330 1094-4087 https://hdl.handle.net/10356/148836 10.1364/OE.417330 10 29 14174 14181 en NRF2018-NRF-ANR009 TIGER NRF-CRP19-2017-01 MOE2018-T2-2-011 RG 148/19 iGrant of Singapore (A2083c0053) Optics Express © 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement. application/pdf |
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Engineering::Electrical and electronic engineering Germanium Photonics Jung, Yongduck Kim, Youngmin Burt, Daniel Joo, Hyo-Jun Kang, Dong-Ho Luo, Manlin Chen, Melvina Lin, Zhang Tan, Chuan Seng Nam, Donguk Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications |
| description |
The creation of CMOS compatible light sources is an important step for the realization of electronic-photonic integrated circuits. An efficient CMOS-compatible light source is considered the final missing component towards achieving this goal. In this work, we present a novel crossbeam structure with an embedded optical cavity that allows both a relatively high and fairly uniform biaxial strain of ~0.9% in addition to a high-quality factor of >4,000 simultaneously. The induced biaxial strain in the crossbeam structure can be conveniently tuned by varying geometrical factors that can be defined by conventional lithography. Comprehensive photoluminescence measurements and analyses confirmed that optical gain can be significantly improved via the combined effect of low temperature and high strain, which is supported by a three-fold reduction of the full width at half maximum of a cavity resonance at ~1,940 nm. Our demonstration opens up the possibility of further improving the performance of germanium lasers by harnessing geometrically amplified biaxial strain. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Jung, Yongduck Kim, Youngmin Burt, Daniel Joo, Hyo-Jun Kang, Dong-Ho Luo, Manlin Chen, Melvina Lin, Zhang Tan, Chuan Seng Nam, Donguk |
| format |
Article |
| author |
Jung, Yongduck Kim, Youngmin Burt, Daniel Joo, Hyo-Jun Kang, Dong-Ho Luo, Manlin Chen, Melvina Lin, Zhang Tan, Chuan Seng Nam, Donguk |
| author_sort |
Jung, Yongduck |
| title |
Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications |
| title_short |
Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications |
| title_full |
Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications |
| title_fullStr |
Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications |
| title_full_unstemmed |
Biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications |
| title_sort |
biaxially strained germanium crossbeam with a high-quality optical cavity for on-chip laser applications |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/148836 |
| _version_ |
1701270619153235968 |