The ultrafast laser inscription technique has been used to fabricate channel waveguides in Tm-doped LuO ceramic gain medium for the first time to our knowledge. Laser operation has been demonstrated using a monolithic microchip cavity with a continuous-wave Ti:sapphire pump source at 796 nm. The maximum output power achieved from the Tm:LuO waveguide laser was 81 mW at 1942 nm. A maximum slope efficiency of 9.5% was measured with the laser thresholds observed to be in the range of 50-200 mW of absorbed pump power. Propagation losses for this waveguide structure are calculated to be 0.7 dB⋅cm ± 0.3 dB⋅cm at the lasing wavelength.
We report on the first demonstration, to the best of our knowledge, of a diode-pumped Tm:LuScO laser. Efficient and broadly tunable continuous wave operation in the 1973-2141 nm region and femtosecond mode-locking through the use of an ion-implanted InGaAsSb quantum-well-based semiconductor saturable absorber mirror are realized. When mode-locked, near-transform-limited pulses as short as 170 fs were generated at 2093 nm with an average output power of 113 mW and a pulse repetition frequency of 115.2 MHz. Tunable picosecond pulse generation was demonstrated in the 2074-2104 nm spectral range.
Ultrafast laser inscription (ULI) allows the fabrication of compact, highly-efficient and robust laser sources over a broad range of crystalline, ceramic and glass gain media. For instance, subsurface waveguides can be formed by the stress induced refractive index modification effect which takes place between two parallel modified regions referred to as "Type II" guiding [1]. Previously, a family of laser hosts known as sesquioxides, namely Lu 2 O 3 , Sc 2 O 3 and LuScO 3 , have been shown to demonstrate efficient, high-power and tunable laser operation around the 2 m region in both continuous-wave and pulsed regimes when doped with Tm 3+ [2,3]. Combining the Tm 3+ -doped sesquioxide material properties with the ULI waveguide laser geometry provides a means to produce compact, low-threshold and efficient laser sources near 2 m with the potential for high pulse repetition rate ultrafast operation. Here we report, to the best of our knowledge, the first demonstration of a ceramic Tm:Lu 2 O 3 waveguide laser source fabricated by ULI.The 9 mm long waveguides were fabricated in a polished 2.359 mm sample of 1 at.% Tm doped Lu 2 O 3 ceramic using an ultrafast laser (Light Conversion) emitting 200 fs pulses at 500 kHz pulse repetition rate at 1040 nm. The laser beam was circularly polarised and focussed with a 0.4 NA aspheric lens 300 μm beneath the sample surface, and the sample was translated at 5 mm/s through the focus. Type II guiding was observed in the structures inscribed at pulse energies between 0.8 μJ and 3 J with track separations of 20 μm and 30 μm. Optimal lasing performance was found for a waveguide written with 2 µJ pulses at a 30 µm track separation.The laser cavity was constructed with two plane dielectric mirrors mounted up against the uncoated 2.35 mm end facets of the sample. The input pump mirror was coated for a high reflectivity in the range of 1900 -2100 nm and a high transmission at the pump wavelength of 795 nm, while a number of different output couplers were investigated (T=2%, 9%, 20%, 30%, 40% and 75%). The pump source was a tunable Ti:sapphire laser producing a maximum output power of 2 W at 795 nm and a polarisation orientated in the y-axis. The slightly astigmatic pump was coupled into the waveguide using a 20 mm focal length lens resulting in an average diameter spot size of 27.5 µm. A maximum output power of 80.8 mW at 1942 nm was generated using the 40% output coupler for an absorbed power of 1.18 W (Fig. 1). A maximum slope efficiency, assuming perfect coupling, of 9.5% was achieved at optimal conditions and thresholds were observed to be in the range of 50 -120 mW. The pump and signal modes were imaged using commercial visible and mid-IR cameras, respectively (Fig. 2). The signal mode was calculated to have a diameter of 22.5 µm and 25.2 µm in the x and y directions, respectively. By detuning the pump source to a non-absorbing wavelength of 860 nm, a total insertion loss for the pump was estimated to be 1.6 dB. From the laser experiments the propagation loss for the laser wav...
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