Self-similarity mode locking optical fiber femtosecond laser device based on spectrum compression and amplification

A femtosecond laser, self-similar technology, applied in the direction of lasers, laser components, phonon exciters, etc., can solve the loss of fiber laser compactness and easy operation advantages, is not conducive to high-energy femtosecond laser pulse output, loss of cavity Internal pulse energy and other issues to achieve the effect of increasing spectral energy density, realizing nonlinear phase balance, and increasing pulse spectral broadening

Inactive Publication Date: 2014-12-24
CHINA ACADEMY OF SPACE TECHNOLOGY
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Problems solved by technology

Among them, in the first self-similar-soliton mode-locking method, the pulse energy amplification and spectral broadening are ultimately limited by the pulse soliton fission in the negative dispersion fiber; while the second dissipative self-similar mode-locking method usually uses a combination of diffraction gratings The fiber collimator forms a Gaussian narrow-band filter to achieve strong spectral filtering to complete the pulse self-similar amplification evolution in the gain fiber.

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  • Self-similarity mode locking optical fiber femtosecond laser device based on spectrum compression and amplification
  • Self-similarity mode locking optical fiber femtosecond laser device based on spectrum compression and amplification
  • Self-similarity mode locking optical fiber femtosecond laser device based on spectrum compression and amplification

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Embodiment Construction

[0028] Specific embodiments of the present invention will be further described in detail below in conjunction with the accompanying drawings.

[0029]The femtosecond laser of the present invention utilizes the self-phase modulation effect induced positive frequency chirp during the amplification process of the negative chirped pulse in the positive dispersion gain fiber to balance the initial negative chirp, so that the pulse energy of the long and short wave parts of the negative chirped pulse is redistributed , continuously concentrated near the central wavelength, while amplifying the energy of the negatively chirped pulse, realize spectral nonlinear compression, form a narrow-band high peak power chirp-free picosecond pulse and then inject it into the single-mode fiber, using the self-phase of the single-mode fiber Modulation and positive group velocity dispersion complete self-similar evolution and spectral broadening, and directly output broadband linearly chirped parabol...

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Abstract

A self-similarity mode locking optical fiber femtosecond laser device based on spectrum compression and amplification is composed of an optical fiber coupling output laser diode, a wavelength division multiplexing coupler, a ytterbium-mixed monomode optical fiber, an optical fiber frequency spectrum filter, a monomode optical fiber, an optical fiber collimator, a quarter-wave plate, a half-wave plate, a polarization splitting prism, a 45-degree reflector, a grating and an optical fiber isolator. Spectrum is compressed by using the self-phase modulation generated when negative chirp pulses are amplified in the ytterbium-mixed monomode optical fiber, narrow-band chirp-free picosecond pulses are formed, the optical fiber frequency spectrum filter is used for eliminating residual side lobes in nonlinear spectrum compression, self-similarity evolution is completed in the monomode optical fiber, broadband linear chirp parabola pulses are output directly, and Fourier transformation extremity femtosecond lasers are output after chirps are eliminated. The self-similarity mode locking optical fiber femtosecond laser device is high in efficiency, large in self-similarity evolution spectrum widening amount, capable of obtaining Fourier transformation extremity femtosecond laser pulses high in energy and narrow in pulse width, compact in structure and easy to operate.

Description

technical field [0001] The invention belongs to the technical field of ultrafast lasers, in particular to a self-similar mode-locked fiber femtosecond laser based on spectrum compression and amplification. Background technique [0002] Passively mode-locked fiber femtosecond lasers have outstanding advantages such as low cost, compact structure, simple operation, self-starting, good beam quality and strong stability. There are a wide range of applications in scale distance measurement, biomedical imaging, tissue processing, and nanodiagnostics. The formation process of femtosecond laser pulses in passively mode-locked fiber lasers is mainly the evolutionary balance process of gain, group velocity dispersion and self-phase modulation. Saturable absorbers play a role in initiating and stabilizing mode-locking, and the most commonly used method is nonlinear polarization rotation. In the case of negative dispersion in the fiber laser cavity, the balance of group velocity dispe...

Claims

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Application Information

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IPC IPC(8): H01S3/067H01S3/098H01S3/081
Inventor 王思佳
Owner CHINA ACADEMY OF SPACE TECHNOLOGY
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