Adam Lancaster scite author profile

A compact mid-infrared channel waveguide laser is demonstrated in Cr:ZnS with a view to power scaling chromium laser technology utilizing the thermo-mechanical advantages of Cr:ZnS over alternative transition metal doped II-VI semiconductor laser materials. The laser provided a maximum power of 101 mW of CW output at 2333 nm limited only by the available pump power. A maximum slope efficiency of 20% was demonstrated.

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Mid-infrared laser emission from Fe:ZnSe cladding waveguides

Lancaster

Cook

McDaniel

et al. 2015

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The authors present a mid-IR depressed cladding waveguide laser in Fe:ZnSe. The laser produced a maximum output power of 76 mW at 4122 nm and laser thresholds as low as 154 mW were demonstrated. This represents a 44% reduction in threshold power compared with the bulk laser system demonstrated in this paper. The waveguide laser was found to have a narrow spectral linewidth of 6 nm FHWM compared to the 50 nm typical of bulk Fe:ZnSe lasers.

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59 GHz graphene based q-switched modelocked mid-infrared monolithic waveguide laser

et al. 2017

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A high repetition rate Q-switched modelocked ~2.1 µm monolithic waveguide laser is reported. Ultrafast laser inscription is used to fabricate 3D depressed cladding channel waveguides in holmium doped yttrium aluminium garnet. This results in a transversely single mode waveguide laser. With the use of a graphene based saturable output coupler, Q-switched modelocking was achieved with a pulse repetition frequency of 5.9 GHz and up to 170 mW of average output power. This first demonstration of multi-GHz repetition rate operation from a Ho:YAG laser provides a compact and convenient source for a number of applications.

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Power scaling of ultrafast laser inscribed waveguide lasers in chromium and iron doped zinc selenide

McDaniel¹,

Lancaster²,

Evans³

et al. 2016

Opt. Express

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We report demonstration of Watt level waveguide lasers fabricated using Ultrafast Laser Inscription (ULI). The waveguides were fabricated in bulk chromium and iron doped zinc selenide crystals with a chirped pulse Yb fiber laser. The depressed cladding structure in Fe:ZnSe produced output powers of 1 W with a threshold of 50 mW and a slope efficiency of 58%, while a similar structure produced 5.1 W of output in Cr:ZnSe with a laser threshold of 350 mW and a slope efficiency of 41%. These results represent the current state-of-the-art for ULI waveguides in zinc based chalcogenides.

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Operation of Ho:YAG ultrafast laser inscribed waveguide lasers

et al. 2017

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We report fabrication and operation of multi-watt level waveguide lasers utilizing holmium-doped yttrium aluminum garnet (Ho:YAG). The waveguides were fabricated using ultrafast laser inscription, which relies on a chirped pulse ytterbium fiber laser to create depressed cladding structures inside the material. A variety of waveguides were created inside the Ho:YAG samples. We demonstrate output powers of ∼2 W from both a single-mode 50 μm waveguide laser and a multimode 80 μm waveguide laser. In addition, laser action from a co-doped Yb:Ho:YAG sample under in-band pumping conditions was demonstrated.

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Adam Lancaster

Compact Cr:ZnS channel waveguide laser operating at 2333 nm

Mid-infrared laser emission from Fe:ZnSe cladding waveguides

59 GHz graphene based q-switched modelocked mid-infrared monolithic waveguide laser

Power scaling of ultrafast laser inscribed waveguide lasers in chromium and iron doped zinc selenide

Operation of Ho:YAG ultrafast laser inscribed waveguide lasers

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