Diamond sodium guide star laser

Bai²,

et al. 2021

Front. Phys.

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Diamond has a broad spectral transmission range (>0.2 μm) and the largest Raman frequency shift (1,332 cm−1) among known Raman crystals. Hence, the diamond Raman laser has the potential to achieve lasing in the long-wave infrared (LWIR) range, which is difficult to reach via other crystalline lasers. Here, we report a new approach to achieve LWIR output using diamond Raman conversion and provide the corresponding analysis model and simulation results. The conversion efficiency is analyzed as function of the pump waist size, output-coupler transmission, and crystal length, at constant pump power. The maximum output power at which a diamond of relatively large size can be operated without damage is predicted. This study paves a way for high-power LWIR lasing in diamond.

Section: Discussionmentioning

confidence: 96%

Numerical Simulation of Long-Wave Infrared Generation Using an External Cavity Diamond Raman Laser

Bai²,

et al. 2021

Front. Phys.

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International Journal of Optics

“…e Raman cavity is based on a simple standing-wave structure pumped by a multilongitudinal mode laser. Subsequently, the same group [5] demonstrated a SLM 589 nm laser with near-diffraction limited beam quality generated in a standing-wave diamond Raman resonator with intracavity second-harmonic generation. With a 63 W 1018 nm pump, 589 nm laser with output power up to 22 W was achieved.…”

Section: Nonlinear Frequency Conversion Methodmentioning

confidence: 99%

“…With only one fundamental frequency component, singlelongitudinal-mode (SLM) lasers have the advantages of narrow linewidths and low phase noise and are therefore ideal for applications where a high-coherence light source is required, including Doppler wind lidar, atmospheric composition measurement, coherent optical communication, gravitational wave detection, sodium guide star, and nonlinear optics [1][2][3][4][5]. In general, if the linewidth of an SLM laser is narrower than the resolution of a spectrum analyzer or the nonlinear gain bandwidth of a specific medium, it is assumed to be a single-frequency laser.…”

Section: Introductionmentioning

confidence: 99%

Development of Single-Longitudinal-Mode Selection Technology for Solid-State Lasers

Zhang

Wang

Shi

et al. 2021

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Lasers with narrow linewidths and single frequencies are widely used in fields such as radar detection, nonlinear optics, and precision measurements. The demand for such lasers has promoted the rapid development of single-longitudinal-mode (SLM) selection technology. Here, we highlight the working principles of current mainstream SLM selection technologies and the recent advances in the field. We compare the characteristics of different SLM selection methods and list the challenges faced by these technologies.

“…The results show that the self-suppression provided by additional gain competition strongly reduces the instability of SLM caused by thermally induced cavity length. In 2020, the author first realized a 22 W of CW output at 589 nm with neardiffraction-limited beam quality in the diamond Raman and second-harmonic generation resonator [74] . The 1018 nm ytterbium-doped fiber (YDF) laser as the pump laser consists of two parts: fiber Bragg grating oscillator and one-stage YDF amplifier.…”

Section: Slmmentioning

confidence: 99%

Diamond Raman laser: a promising high-beam-quality and low-thermal-effect laser

Ding

Bai

et al. 2021

High Pow Laser Sci Eng

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Stimulated Raman-scattering-based lasers provide an effective way to achieve wavelength conversion. However, thermally induced beam degradation is a notorious obstacle to power scaling and it also limits the applicable range where high output beam quality is needed. Considerable research efforts have been devoted to developing Raman materials, with diamond being a promising candidate to acquire wavelength-versatile, high-power, and high-quality output beam owing to its excellent thermal properties, high Raman gain coefficient, and wide transmission range. The diamond Raman resonator is usually designed as an external-cavity pumped structure, which can easily eliminate the negative thermal effects of intracavity laser crystals. Diamond Raman converters also provide an approach to improve the beam quality owing to the Raman cleanup effect. This review outlines the research status of diamond Raman lasers, including beam quality optimization, Raman conversion, thermal effects, and prospects for future development directions.