Broadband 2-µm emission on silicon chips: monolithically integrated Holmium lasers.

نویسندگان

  • Nanxi Li
  • Emir Salih Magden
  • Zhan Su
  • Neetesh Singh
  • Alfonso Ruocco
  • Ming Xin
  • Matthew Byrd
  • Patrick T Callahan
  • Jonathan D B Bradley
  • Christopher Baiocco
  • Diedrik Vermeulen
  • Michael R Watts
چکیده

Laser sources in the mid-infrared are of great interest due to their wide applications in detection, sensing, communication and medicine. Silicon photonics is a promising technology which enables these laser devices to be fabricated in a standard CMOS foundry, with the advantages of reliability, compactness, low cost and large-scale production. In this paper, we demonstrate a holmium-doped distributed feedback laser monolithically integrated on a silicon photonics platform. The Al2O3:Ho3+ glass is used as gain medium, which provides broadband emission around 2 µm. By varying the distributed feedback grating period and Al2O3:Ho3+ gain layer thickness, we show single mode laser emission at wavelengths ranging from 2.02 to 2.10 µm. Using a 1950 nm pump, we measure a maximum output power of 15 mW, a slope efficiency of 2.3% and a side-mode suppression ratio in excess of 50 dB. The introduction of a scalable monolithic light source emitting at > 2 µm is a significant step for silicon photonic microsystems operating in this highly promising wavelength region.

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عنوان ژورنال:
  • Optics express

دوره 26 3  شماره 

صفحات  -

تاریخ انتشار 2018