RU2014100859A - FIBER PULSE LINEAR LASER WITH PASSIVE SYNCHRONIZATION OF RADIATION MODES (OPTIONS) - Google Patents

Abstract

1. A fiber pulsed linear laser with passive synchronization of radiation modes, containing an optically coupled pump radiation source, supporting a radiation polarization, a fiber linear resonator containing a spectrally selective reflecting element, a collimator, a fiber end face that does not reflect the laser radiation back into this fiber, amplifying fiber, at least one fiber module for spectral reduction for introducing pump radiation into an amplifying fiber, at least one polarization-dependent a coupler for outputting radiation from the resonator, an end face of the fiber that does not reflect the laser radiation back into the fiber, a collimator, an optical element focusing the radiation, a resonator mirror, characterized in that the resonator mirror is located on the same surface of the laser-transparent optical element with Kerr nonlinearity and more than 0.5 mm thick, the other surface of which is located between the mirror and the optical element focusing the radiation and has an inclination angle of at least one degree to the cavity axis l zera.2. The laser according to claim 1, characterized in that the other surface of the optical element with Kerr nonlinearity has an antireflection coating. The laser according to claim 1, characterized in that the spectrally selective reflecting element is a prism in combination with a reflecting mirror or a Littrov prism with a reflective coating on the surface onto which the laser beam normally incident after refraction on the input Brewster surface of the prism. 4. The laser according to claim 1, characterized in that the spectrally selective reflective element is �

Claims (35)

1. A fiber pulsed linear laser with passive synchronization of radiation modes, containing an optically coupled pump radiation source, supporting a radiation polarization, a fiber linear resonator containing a spectrally selective reflecting element, a collimator, a fiber end face that does not reflect the laser radiation back into this fiber, amplifying fiber, at least one fiber module for spectral reduction for introducing pump radiation into an amplifying fiber, at least one polarization-dependent a coupler for outputting radiation from the resonator, an end face of the fiber that does not reflect the laser radiation back into the fiber, a collimator, an optical element focusing the radiation, a resonator mirror, characterized in that the resonator mirror is located on the same surface of the laser-transparent optical element with Kerr nonlinearity and more than 0.5 mm thick, the other surface of which is located between the mirror and the optical element focusing the radiation and has an inclination angle of at least one degree to the cavity axis l Zera. 2. The laser according to claim 1, characterized in that the other surface of the optical element with Kerr nonlinearity has an antireflective coating. 3. The laser according to claim 1, characterized in that the spectrally selective reflecting element is a prism in combination with a reflecting mirror or a Littrov prism with a reflective coating on the surface onto which the laser beam normally incident after refraction on the input Brewster surface of the prism. 4. The laser according to claim 1, characterized in that the spectrally selective reflective element is a fiber Bragg grating or a bulk diffraction grating. 5. The laser according to claim 1, characterized in that the spectrally selective reflective element is a mirror with a given spectral reflection band. 6. The laser according to claim 1, characterized in that between the focusing radiation optical element and the nearest collimator there is a polarizer with passable surfaces for laser radiation having an angle of inclination from the laser cavity axis of at least one degree. 7. The laser according to claim 6, characterized in that the surfaces of the polarizer passable for laser radiation have an antireflection coating. 8. The laser according to claim 1, characterized in that the surfaces of the collimators and the focusing radiation of the optical element passing through for laser radiation have an antireflection coating. 9. The laser according to claim 1, characterized in that both the glass optical fiber and the glass optical fiber doped with rare earth elements or doped with germanium and phosphorus oxides, as well as a combination thereof, are used as the reinforcing fiber, while the oxide matrix may include compound of the chemical element Si, Ν, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi. 10. The laser according to claim 1, characterized in that the radiation source of the fiber laser pump is a Raman laser when using fiberglass doped with germanium oxides and phosphorus as an amplifying fiber, as well as a combination thereof, while the compound of the chemical element Si can enter the oxide matrix , Ν, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi, while the Raman laser cavity is formed by two fiber Bragg gratings having perpendicular to the beam or inclined strokes and reflecting for the radiation of the first oksovoy components of the Raman laser. 11. The laser according to claim 10, characterized in that the Raman laser cavity is formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes components of a Raman laser. 12. A fiber pulsed linear laser with passive synchronization of radiation modes, containing an optically coupled pump radiation source supporting a radiation polarization, a fiber linear resonator containing a spectrally selective reflective element, a collimator, a fiber end face that does not reflect the laser radiation back into this fiber, amplifying fiber, at least one fiber module for spectral reduction for introducing pump radiation into an amplifying fiber, at least one polarization-dependent A simulated coupler for outputting radiation from a resonator, an end face of a fiber that does not reflect the laser radiation back into the fiber, a collimator, an optical element focusing the radiation, a resonator mirror, characterized in that an optical element with a Kerr nonlinearity and a thickness greater than 0.5 mm with passages for laser radiation surfaces having an angle of inclination to the axis of the laser cavity of at least one degree. 13. The laser according to claim 12, characterized in that both surfaces of the optical element with Kerr nonlinearity have an antireflection coating. 14. The laser according to claim 12, characterized in that the distance between the resonator mirror and the surface of the optical element with the Kerr nonlinearity closest to it does not exceed 1 mm. 15. The laser according to claim 12, characterized in that the spectrally selective reflective element is a prism in combination with a reflecting mirror or a Littrov prism with a reflective coating on the surface onto which the laser beam normally incident after refraction on the input Brewster surface of the prism. 16. The laser of claim 12, wherein the spectrally selective reflective element is a fiber Bragg grating or a bulk diffraction grating. 17. The laser according to claim 12, characterized in that the spectrally selective reflective element is a mirror with a given spectral reflection band. 18. The laser according to claim 12, characterized in that between the focusing radiation optical element and the nearest collimator there is a polarizer with passable surfaces for laser radiation having an angle of inclination from the laser cavity axis of at least one degree. 19. The laser according to claim 18, characterized in that the surfaces of the polarizer passable for laser radiation have an antireflective coating. 20. The laser according to claim 12, characterized in that the surfaces of the collimators and the focusing radiation of the optical element passing through for the laser radiation have an antireflection coating. 21. The laser according to claim 12, characterized in that both the glass optical fiber and the glass optical fiber doped with rare earth elements or doped with germanium and phosphorus oxides, as well as a combination thereof, are used as the reinforcing fiber, while the oxide matrix may include compound of the chemical element Si, Ν, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi. 22. The laser according to p. 12, characterized in that the radiation source of the fiber laser pump is a Raman laser when using fiberglass doped with germanium oxides and phosphorus as an amplifying fiber, as well as their combination, while the compound of the chemical element Si can enter the oxide matrix , Ν, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi, while the Raman laser cavity is formed by two fiber Bragg gratings having perpendicular to the beam or inclined strokes and reflecting for the radiation of the first current component of a Raman laser. 23. The laser according to claim 22, characterized in that the Raman laser cavity is formed by four fiber Bragg gratings having perpendicular to the beam or inclined lines, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes components of a Raman laser. 24. A passive-mode fiber pulsed linear laser containing an optically coupled pump radiation source supporting a radiation polarization; a linear fiber resonator containing a spectrally selective reflective element, a collimator, a fiber end face that does not reflect the laser radiation back into this fiber, amplifying fiber, at least one fiber module for spectral reduction for introducing pump radiation into an amplifying fiber, at least one polarization-dependent a simulated coupler for outputting radiation from a resonator, an end face of a fiber that does not reflect laser radiation back into this fiber, a collimator, an optical element focusing the radiation, a resonator mirror, characterized in that the resonator mirror is spherical, between the spherical mirror of the resonator and the optical focusing element in the waist of the radiation beam, an optical element with Kerr nonlinearity and a thickness of more than 0.5 mm is located with passable surfaces for laser radiation having an angle of inclination to the cavity axis laser at least one degree. 25. The laser according to claim 24, characterized in that both surfaces of the optical element with Kerr nonlinearity have an antireflection coating. 26. The laser according to claim 24, characterized in that both surfaces of the optical element with Kerr nonlinearity are Brewster. 27. The laser according to claim 24, wherein the spectrally selective reflecting element is a prism in combination with a reflecting mirror or a Littrov prism with a reflective coating on a surface onto which a laser beam normally incident after refraction on the input Brewster surface of the prism. 28. The laser of claim 24, wherein the spectrally selective reflective element is a fiber Bragg grating or a bulk diffraction grating. 29. The laser according to claim 24, characterized in that the spectrally selective reflective element is a mirror with a given spectral reflection band. 30. The laser according to claim 24, characterized in that between the focusing radiation optical element and the nearest collimator there is a polarizer with passable surfaces for laser radiation having an angle of inclination from the laser cavity axis of at least one degree. 31. The laser according to claim 24, characterized in that the surfaces of the polarizer passable for laser radiation have an antireflective coating. 32. The laser according to claim 24, characterized in that the surfaces of the collimators and the focusing radiation of the optical element passing through for the laser radiation have an antireflection coating. 33. The laser according to claim 24, characterized in that both the glass optical fiber and the glass optical fiber doped with rare earth elements or doped with germanium and phosphorus oxides, as well as a combination thereof, are used as the reinforcing fiber, while the oxide matrix may include compound of the chemical element Si, Ν, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi. 34. The laser according to p. 24, characterized in that the radiation source of the fiber laser pump is a Raman laser when using fiberglass doped with germanium oxides and phosphorus as an amplifying fiber, as well as a combination thereof, while the compound of the chemical element Si can enter the oxide matrix , Ν, Ga, Al, Fe, F, Ti, B, Sn, Ba, Ta, Zr, Bi, and the Raman laser cavity is formed by two fiber Bragg gratings having perpendicular to the beam or inclined lines and reflecting the radiation of the first Toksovo components of the Raman laser. 35. The laser according to claim 34, characterized in that the Raman laser cavity is formed by four fiber Bragg gratings having perpendicular to the beam or inclined strokes, two of which are reflective for the radiation of the first Stokes component of the Raman laser, and the other two are reflective for the radiation of the second Stokes components of a Raman laser.