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Low-noise tunable deep-ultraviolet supercontinuum laser

Callum R. Smith, Asbjørn Moltke, Abubakar I. Adamu, Mattia Michieletto, Patrick Bowen, Peter M. Moselund, Christos Markos, Ole Bang

2020Scientific Reports20 citationsDOIOpen Access PDF

Abstract

The realization of a table-top tunable deep-ultraviolet (UV) laser source with excellent noise properties would significantly benefit the scientific community, particularly within imaging and spectroscopic applications, where source noise has a crucial role. Here we provide a thorough characterization of the pulse-to-pulse relative intensity noise (RIN) of such a deep-UV source based on an argon (Ar)-filled anti-resonant hollow-core (AR HC) fiber. Suitable pump pulses are produced using a compact commercially available laser centered at 1030 nm with a pulse duration of 400 fs, followed by a nonlinear compression stage that generates pulses with 30 fs duration, 24.2 μJ energy at 100 kHz repetition rate and a RIN of < 1%. Pump pulses coupled into the AR HC fiber undergo extreme spectral broadening creating a supercontinuum, leading to efficient energy transfer to a phase-matched resonant dispersive wave (RDW) in the deep-UV spectral region. The center wavelength of the RDW could be tuned between 236 and 377 nm by adjusting the Ar pressure in a 140 mm length of fiber. Under optimal pump conditions the RIN properties were demonstrated to be exceptionally good, with a value as low as 1.9% at ~ 282 nm. The RIN is resolved spectrally for the pump pulses, the generated RDW and the broadband supercontinuum. These results constitute the first broadband RIN characterization of such a deep-UV source and provide a significant step forward towards a stable, compact and tunable laser source for applications in the deep-UV spectral region.

Topics & Concepts

SupercontinuumLaserMaterials sciencePulse durationOpticsFiber laserRelative intensity noiseOptoelectronicsUltravioletWavelengthPhotonic-crystal fiberSemiconductor laser theoryPhysicsAdvanced Fiber Laser TechnologiesLaser-Matter Interactions and ApplicationsPhotonic Crystal and Fiber Optics
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