小さな新しいレーザーが、可視光の色の虹における長年のギャップを埋め、新しいアプリケーションを開く(Tiny New Lasers Fill a Long-Standing Gap in the Rainbow of Visible-Light Colors, Opening New Applications)

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20024-08-28 米国国立標準技術研究所(NIST)

科学者たちは、チップに収まるサイズのオレンジ、黄色、緑の小型レーザーを開発し、「グリーンギャップ」と呼ばれる技術的な欠陥を埋めました。この波長範囲の低ノイズでコンパクトなレーザーは、量子センシング、通信、情報処理に重要です。特に緑色のレーザーは、海中通信や医療治療、フルカラープロジェクションディスプレイなどでの応用が期待されています。今回の成果により、従来困難だった緑色光の生成が可能になり、新たな技術的応用が広がります。

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オンチップKerr光パラメトリック発振を、緑のギャップをカバーするコヒーレント・アプリケーションに向けて前進させる Advancing on-chip Kerr optical parametric oscillation towards coherent applications covering the green gap

Yi Sun,Jordan Stone,Xiyuan Lu,Feng Zhou,Junyeob Song,Zhimin Shi & Kartik Srinivasan
Light: Science and Applications  Published:21 August 2024
DOI:https://doi.org/10.1038/s41377-024-01534-x

小さな新しいレーザーが、可視光の色の虹における長年のギャップを埋め、新しいアプリケーションを開く(Tiny New Lasers Fill a Long-Standing Gap in the Rainbow of Visible-Light Colors, Opening New Applications)

Abstract

Optical parametric oscillation (OPO) in Kerr microresonators can efficiently transfer near-infrared laser light into the visible spectrum. To date, however, chromatic dispersion has mostly limited output wavelengths to >560 nm, and robust access to the whole green light spectrum has not been demonstrated. In fact, wavelengths between 532 nm and 633 nm, commonly referred to as the “green gap”, are especially challenging to produce with conventional laser gain. Hence, there is motivation to extend the Kerr OPO wavelength range and develop reliable device designs. Here, we experimentally show how to robustly access the entire green gap with Kerr OPO in silicon nitride microrings pumped near 780 nm. Our microring geometries are optimized for green-gap emission; in particular, we introduce a dispersion engineering technique, based on partially undercutting the microring, which not only expands wavelength access but also proves robust to variations in resonator dimensions. Using just four devices, we generate >150 wavelengths evenly distributed throughout the green gap, as predicted by our dispersion simulations. Moreover, we establish the usefulness of Kerr OPO to coherent applications by demonstrating continuous frequency tuning (>50 GHz) and narrow optical linewidths (<1 MHz). Our work represents an important step in the quest to bring nonlinear nanophotonics and its advantages to the visible spectrum.

1700応用理学一般
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