Diamond Raman laser with continuously tunable output from 338 to 380 μm

Synthetic single-crystal diamond has recently emerged as a promising platform for Raman lasers at exotic wavelengths due to its giant Raman shift, large transparency window and excellent thermal properties yielding a greatly enhanced figure-of-merit compared to conventional materials [1, 2, 3]. To date, diamond Raman lasers have been realized using bulk plates placed inside macroscopic cavities [3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13], requiring careful alignment and resulting in high threshold powers (~W-kW). Here we demonstrate an on-chip Raman laser based on fully-integrated, high quality-factor, diamond racetrack microresonators embedded in silica. Pumping at telecom wavelengths, we show Stokes output discretely tunable over a ~100nm bandwidth around 2-μm with output powers >250 μW, extending the functionality of diamond Raman lasers to an interesting wavelength range at the edge of the mid-infrared spectrum [14]. Continuous-wave operation with only ~85 mW pump threshold power in the feeding waveguide is demonstrated along with continuous, mode-hop-free tuning over ~7.5 GHz in a compact, integrated-optics platform.Diamond serves as a compelling material platform for Raman lasers operating over a wide spectrum due to its superlative Raman frequency shift (~40 THz), large Raman gain (~10 cm/GW @ ~1-μm wavelength) and ultra-wide transparency window (from UV (>220nm) all the way to THz, except for a slightly lossy window from ~2.6 -6 μm due to multiphonon-induced absorption) [1,15]. Furthermore, the excellent thermal properties afforded by diamond (giant thermal conductivity of ~1800 W/m/K @ 300K and low thermo-optic coefficient of ~10 -5 /K) [1,2] along with negligible birefringence [3,15] make it an ideal material for high-power Raman lasing with greatly reduced thermal lensing effects [1,3].The availability of CVD-grown, high-quality polished, single-crystal diamond plates has enabled the development of bulk Raman lasers using macroscopic optical cavities across the UV [6], visible [4, 5], near-infrared [7, 8, 9, 10, 11, 12] and even mid-infrared [13] regions of the optical spectrum. Although showing great performance with large output powers (many Watts) [12] and near quantum-limited conversion efficiencies [5,9], most operate in pulsed mode in order to attain the very high pump powers required to exceed the Raman lasing threshold [5,6,11,12]. Demonstration of continuous-wave diamond Raman lasing has been challenging, with very few reports [3,7,8]. Bulk cavity systems also require precise alignment and maintenance of optical components for the laser to function robustly.

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confidence: 99%

On-chip diamond Raman laser

Latawiec

Venkataraman

Burek

et al. 2015

Optica

130

111

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“…Temperature-dependent loss measurements for the pump polarization along the [100] axis in the OP-GaP crystal have also been performed, for the first time, indicating a drop in transmission from 28.8% at 50ºC to 19.4% at 160ºC. © 2015 Optical Society of America OCIS codes : (190.4360) Nonlinear optics, devices; (190.4400) Nonlinear optics, materials; (190.4410 Mid-infrared (mid-IR) coherent sources based on optical parametric down-conversion are of great significance for a variety of applications such as spectroscopy [1], up-conversion imaging [2] and as pump source for other nonlinear processes [3]. Oxide-based nonlinear crystals, and especially their quasi-phase matched (QPM) counterparts such as MgO-doped periodically-poled LiNbO3 (MgO:PPLN), stoichiometric LiTaO3 (MgO:sPPLT) and KTiOPO4 (PPKTP), have enabled broadband mid-IR coverage up to ~4 μm, in all time-scales from continuous-wave (CW) to femtosecond domain [4][5][6][7].…”

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confidence: 99%

“…Mid-infrared (mid-IR) coherent sources based on optical parametric down-conversion are of great significance for a variety of applications such as spectroscopy [1], up-conversion imaging [2] and as pump source for other nonlinear processes [3]. Oxide-based nonlinear crystals, and especially their quasi-phase matched (QPM) counterparts such as MgO-doped periodically-poled LiNbO3 (MgO:PPLN), stoichiometric LiTaO3 (MgO:sPPLT) and KTiOPO4 (PPKTP), have enabled broadband mid-IR coverage up to ~4 μm, in all time-scales from continuous-wave (CW) to femtosecond domain [4][5][6][7].…”

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confidence: 99%

Optical parametric generation in orientation-patterned gallium phosphide

Kumar²,

Wei

et al. 2017

Opt. Lett.

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We report the first optical parametric generator (OPG) based on the new nonlinear material, orientationpatterned gallium phosphide (OP-GaP). Pumped by a Qswitched nanosecond Nd:YAG laser at 1064 nm with 25 kHz pulse repetition rate, the OPG can be tuned across 1721-1850 nm in the signal and 2504-2787 nm in the idler. Using a 40-mm-long crystal in single pass, we have generated a total average output power of up to ~18 mW, with ~5 mW of idler power at 2670 nm, for 2 W of input pump power. The OPG exhibits a passive stability in total output power better than 0.87% rms over 1 hour, at a crystal temperature of 120 ºC, compared to 0.14% rms for the input pump. The output signal pulses, recorded at 1769 nm, have duration of 5.9 ns for input pump pulses of 9 ns. Temperature-dependent loss measurements for the pump polarization along the [100] axis in the OP-GaP crystal have also been performed, for the first time, indicating a drop in transmission from 28.8% at 50ºC to 19.4% at 160ºC. © 2015 Optical Society of America OCIS codes : (190.4360) Nonlinear optics, devices; (190.4400) Nonlinear optics, materials; (190.4410 Mid-infrared (mid-IR) coherent sources based on optical parametric down-conversion are of great significance for a variety of applications such as spectroscopy [1], up-conversion imaging [2] and as pump source for other nonlinear processes [3]. Oxide-based nonlinear crystals, and especially their quasi-phase matched (QPM) counterparts such as MgO-doped periodically-poled LiNbO3 (MgO:PPLN), stoichiometric LiTaO3 (MgO:sPPLT) and KTiOPO4 (PPKTP), have enabled broadband mid-IR coverage up to ~4 μm, in all time-scales from continuous-wave (CW) to femtosecond domain [4][5][6][7]. However, the onset of multiphonon absorption in these nonlinear crystals has been a fundamental barrier to reach spectral regions into the deep mid-IR. Non-oxide-based nonlinear materials with extended transparency in the mid-IR, such as ZnGeP2 (ZGP) and orientation-patterned GaAs (OP-GaAs), offer potential for the development of parametric sources beyond 4 μm. However, their low bandgap requires pumping beyond 2 μm to avoid two-photon absorption. The more recently developed nonlinear crystal, CdSiP2 (CSP), is an important new addition to the family of birefringent nonlinear materials for parametric downconversion into the deep mid-IR. The high optical nonlinearity, noncritical phase-matching (NCPM) capability, and a wide transparency range extending down to below ~1 μm, enable the deployment of the widely available Nd-based solid-state or Ybbased fiber lasers as pump source for deep mid-IR wavelength generation up to ~7 μm [8,9]. On the other hand, the new semiconductor nonlinear material, orientation-patterned GaP (OPGaP) can be considered as the QPM analog of CSP, and a promising alternative for deep mid-IR generation. As a QPM material, OP-GaP offers unique flexibility for tunable wavelength generation into the deep mid-IR using grating engineering under NCPM with no spatial walk-off. Moreover, unlike ZGP and OP-GaAs, it has sig...

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“…Diamond also happens to have a high Raman gain coefficient so that in its undoped single crystal form it is a convenient Raman laser medium. To date, a wide range of laser performance has been demonstrated including wavelengths from the ultraviolet to the mid‐infrared , temporal regimes from continuous wave to ultrashort pulses , and average powers up to several hundreds of watts . Its thermal conductivity—the highest of any bulk material at room temperature and more than several hundreds of times higher than most other laser gain materials—in combination with a low thermal expansion coefficient, reveals substantial potential for scaling laser power and brightness.…”

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confidence: 99%

Diamond‐based concept for combining beams at very high average powers

McKay

Spence

Coutts

et al. 2017

Laser & Photonics Reviews

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Ever since the laser's invention, there has been great interest in increasing beam output power without detriment to its coherence. Despite great advances having been obtained through the use of a diverse range of approaches, steady‐state beam powers above ten kilowatts remain a significant challenge for solid‐state lasers due to the heightened impact of detrimental nonlinear effects such as thermal lensing. Multiplexing several lasers using beam combination represents a method for surpassing the power barriers of single lasers. Here we propose and demonstrate a novel approach to beam combination and power scaling based on Raman conversion in diamond. Power from multiple non‐collinear pump beams is efficiently transferred onto a single Stokes beam in a single‐pass amplifier. Using three mutually‐independent nanosecond pulsed beams from a free‐running‐linewidth 1064 nm laser, 69% of the total peak pump power of 6.7 kW was transferred onto a TEM00 Stokes seed pulse at 1240 nm in a 9.5 mm long diamond crystal. Compared to other beam combination techniques, diamond beam combination has advantages of relaxed constraints on pump beam mutual coherence, while enabling narrowband output. Thermal considerations for extending from low duty‐cycle to continuous wave operation and higher power levels are discussed.

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Diamond Raman laser with continuously tunable output from 338 to 380 μm

Cited by 69 publications

References 19 publications

On-chip diamond Raman laser

On-chip diamond Raman laser

Optical parametric generation in orientation-patterned gallium phosphide

Diamond‐based concept for combining beams at very high average powers

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