17 000%/W second-harmonic conversion efficiency in single-crystalline aluminum nitride microresonators

Alexander W. Bruch; Xianwen Liu; Xiang Guo; Joshua B. Surya; Zheng Gong; Liang Zhang; Junxi Wang; Jianchang Yan; Hong X. Tang

doi:10.1063/1.5042506

17 000%/W second-harmonic conversion efficiency in single-crystalline aluminum nitride microresonators

Alexander W. Bruch
, Xianwen Liu
, Xiang Guo
, Joshua B. Surya
, Zheng Gong
, Liang Zhang
, Junxi Wang
, Jianchang Yan
, Hong X. Tang

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

114 Citations (Scopus)

Abstract

High quality factor optical microcavities have been employed in a variety of material systems to enhance nonlinear optical interactions. While single-crystalline aluminum nitride microresonators have recently emerged as a low loss platform for integrated nonlinear optics such as four wave mixing and Raman lasing, few studies have investigated this material for second-harmonic generation. In this letter, we demonstrate an optimized fabrication of dually resonant phase-matched ring resonators from epitaxial aluminum nitride thin films. An unprecendented second-harmonic generation efficiency of 17 000%/W is obtained in the low power regime, and pump depletion is observed at a relatively low input power of 3.5 mW. This poses epitaxial aluminum nitride as the highest efficiency second-harmonic generator among current integrated platforms.

Original language	English
Article number	131102
Journal	Applied Physics Letters
Volume	113
Issue number	13
DOIs	https://doi.org/10.1063/1.5042506
Publication status	Published - 24 Sept 2018
Externally published	Yes

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title = "17 000\%/W second-harmonic conversion efficiency in single-crystalline aluminum nitride microresonators",

abstract = "High quality factor optical microcavities have been employed in a variety of material systems to enhance nonlinear optical interactions. While single-crystalline aluminum nitride microresonators have recently emerged as a low loss platform for integrated nonlinear optics such as four wave mixing and Raman lasing, few studies have investigated this material for second-harmonic generation. In this letter, we demonstrate an optimized fabrication of dually resonant phase-matched ring resonators from epitaxial aluminum nitride thin films. An unprecendented second-harmonic generation efficiency of 17 000\%/W is obtained in the low power regime, and pump depletion is observed at a relatively low input power of 3.5 mW. This poses epitaxial aluminum nitride as the highest efficiency second-harmonic generator among current integrated platforms.",

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T1 - 17 000%/W second-harmonic conversion efficiency in single-crystalline aluminum nitride microresonators

AU - Bruch, Alexander W.

AU - Liu, Xianwen

AU - Guo, Xiang

AU - Surya, Joshua B.

AU - Gong, Zheng

AU - Zhang, Liang

AU - Wang, Junxi

AU - Yan, Jianchang

AU - Tang, Hong X.

PY - 2018/9/24

Y1 - 2018/9/24

N2 - High quality factor optical microcavities have been employed in a variety of material systems to enhance nonlinear optical interactions. While single-crystalline aluminum nitride microresonators have recently emerged as a low loss platform for integrated nonlinear optics such as four wave mixing and Raman lasing, few studies have investigated this material for second-harmonic generation. In this letter, we demonstrate an optimized fabrication of dually resonant phase-matched ring resonators from epitaxial aluminum nitride thin films. An unprecendented second-harmonic generation efficiency of 17 000%/W is obtained in the low power regime, and pump depletion is observed at a relatively low input power of 3.5 mW. This poses epitaxial aluminum nitride as the highest efficiency second-harmonic generator among current integrated platforms.

AB - High quality factor optical microcavities have been employed in a variety of material systems to enhance nonlinear optical interactions. While single-crystalline aluminum nitride microresonators have recently emerged as a low loss platform for integrated nonlinear optics such as four wave mixing and Raman lasing, few studies have investigated this material for second-harmonic generation. In this letter, we demonstrate an optimized fabrication of dually resonant phase-matched ring resonators from epitaxial aluminum nitride thin films. An unprecendented second-harmonic generation efficiency of 17 000%/W is obtained in the low power regime, and pump depletion is observed at a relatively low input power of 3.5 mW. This poses epitaxial aluminum nitride as the highest efficiency second-harmonic generator among current integrated platforms.

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U2 - 10.1063/1.5042506

DO - 10.1063/1.5042506

M3 - Article

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SN - 0003-6951

VL - 113

JO - Applied Physics Letters

JF - Applied Physics Letters

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M1 - 131102

ER -

17 000%/W second-harmonic conversion efficiency in single-crystalline aluminum nitride microresonators

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