1. Terahertz metasurface laser design and study of optical feedback
- Author
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Kim, Anthony, Williams, Benjamin S.1, Kim, Anthony, Kim, Anthony, Williams, Benjamin S.1, and Kim, Anthony
- Abstract
Terahertz (THz) external-cavity lasers based on quantum-cascade (QC) metasurfaces are emerging as widely-tunable, single-mode sources with the potential to cover the 1-6 THz range in discrete bands with watt-level output power. By operating on an ultra-short cavity with a length on the order of the wavelength, the QC vertical-external-cavity surface-emitting-laser (VECSEL) architecture enables continuous, broadband tuning while producing high quality beam patterns and scalable power output. These properties are favorable for spectroscopic applications that can benefit from large bandwidths and high output powers, such as serving as a local-oscillator (LO) for heterodyne receivers in astronomy. THz QC-lasers have garnered much attention in the past decade in the astrophysics community due to the lack of well-established THz LO sources above 3 THz. The QC-VECSEL has potential to fill this technological gap, and provide the power output levels necessary for next-generation heterodyne receiver arrays.In this thesis, we discuss the methods and challenges for designing the metasurface at various frequencies across the 1-6 THz bandwidth, and establish fundamental rules for VECSEL scaling. We discuss the methods and challenges for designing the metasurface at various frequencies across the THz bandwidth, and demonstrate single-mode lasing up to 5.72 THz. The device is enabled by a reflectarray metasurface composed of sub-wavelength metallic antennas loaded with quantum-cascade gain material. In theory, wavelength-scaling the metasurface is a matter of scaling up or down the geometric parameters proportionally, maintaining the electromagnetic properties of the structure. However, as the QC-VECSEL is scaled below 2 THz, the primary challenges are reduced gain from the QC active region, increased metasurface quality factor and its effect on tunable bandwidth, and larger power consumption due to a correspondingly scaled metasurface area. At frequencies above 4.5 THz, challenges
- Published
- 2024