RU2646440C2 - Fiber laser for generating high energy light pulses - Google Patents

Abstract

FIELD: laser engineering.

SUBSTANCE: invention relates to laser equipment. Fiber laser for generating high-energy light pulses contains a pumping source, a pump radiation input coupler, a fiber ring resonator with a length of ~10 m, including an active fiber, a non-linear loss device and a generated radiation output coupler of the ring resonator. Additional coupler for the output of the generated radiation from the fiber ring resonator, passive fiber, additional radiation input coupler of the fiber ring resonator are introduced into the laser. Pumping source is connected to one of the ends of the pump radiation input coupler, the other end of which is connected to the fiber ring resonator. Passive fiber is connected with one of its ends to an additional radiation output coupler of the fiber ring resonator, and its other end is connected to an additional radiation input coupler of the fiber ring resonator. Length of passive fiber is determined by the formula: L = T⋅υ, where T is the time interval between adjacent spikes, υ is the speed of light propagation in the fiber.

EFFECT: technical result consists in ensuring the possibility of obtaining stable and reproducible high-energy light pulses.

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Description

The present invention relates to laser technology and can be used to develop lasers with passive mode locking, with high energy output light pulses used in sensing the atmosphere, locations, precision processing of materials, creating ultra-strong light fields, the study of fast processes in physics, chemistry, biology etc.

Known fiber laser for generating high-energy light pulses (SM Kobtsev, SV Kukarin, SV Smirnov, and YS Fedotov, "High-energy mode-locked all-fiber laser with ultralong resonator", Laser Physics. 20, No. 2, pp. 351- 356, 2010). The specified laser with an energy of radiation pulses of about 4 μJ, with a duration of ~ 10 ns, consists of a pump source and a fiber ring resonator including an active fiber ~ 10 m long, which serves to amplify laser radiation, and a passive fiber, of the order of several kilometers, which serves to increasing the length of the resonator. Continuous pump radiation, which creates an inverse population in the active fiber, is introduced into the resonator through a radiation input coupler, the output of which is connected to the input of the active fiber. There is also a coupler of the output of the generated radiation, connected by its input to the output of the fiber ring resonator. A nonlinear loss device is placed in the gap of the fiber ring resonator, which leads to the formation of a radiation pulse. A decrease in the pulse repetition rate in the output radiation due to the longer fiber ring resonator leads to an increase in their energy at a constant average laser power.

However, this fiber laser has a generation feature associated with the loss of stability of the single-pulse mode of passive mode locking at sufficiently long passive fibers. The resulting instability manifests itself in the appearance of new pulses in the fiber ring resonator and in the structuring of the generated pulse. This generation feature leads to a deterioration in the quality of the generated pulses and prevents a further effective increase in their energy, which is a drawback of this fiber laser. The appearance of new pulses and the structuring of the generated pulse begin to manifest themselves with a passive fiber duration of about 200 m or more.

, F. Sanchez, "Mode-lock, Q-switch and CW operation of an Yb-doped double-clad fiber ring laser", Optics Communications. 198, pp. 141-146, 2001). Указанный лазер состоит из источника накачки и волоконного кольцевого резонатора длиной ~10 м, включающего в себя активное волокно, активированное иттербием, служащее для усиления лазерного излучения, и устройство нелинейных потерь, обеспечивающее работу лазера в режиме регулярных незатухающих пичков. Непрерывное излучение источника накачки, создающее в активном волокне инверсную заселенность, вводится в резонатор через специальную систему ввода. Имеется также система вывода части генерируемого излучения из резонатора. Нелинейные потери, создаваемые устройством нелинейных потерь, приводят к неустойчивости режима непрерывной генерации и реализации режима регулярных незатухающих пичков. Выходное излучение лазера представляет собой регулярную последовательность импульсов. Длительность импульса ~1 мкс, энергия импульса ~5 мкДж, расстояние между соседними импульсами ~8.3 мкс.In addition, a fiber laser for generating high-energy light pulses is known, which is the prototype of the invention (A. Hideur, T. Chattier, M. Brunel, M. Salhi, C.

, F. Sanchez, "Mode-lock, Q-switch and CW operation of an Yb-doped double-clad fiber ring laser", Optics Communications. 198, pp. 141-146, 2001). The specified laser consists of a pump source and a fiber ring resonator ~ 10 m long, which includes an active fiber activated by ytterbium, which serves to amplify laser radiation, and a nonlinear loss device that ensures the laser operates in the regime of regular undamped spikes. Continuous radiation of the pump source, which creates an inverse population in the active fiber, is introduced into the resonator through a special input system. There is also a system for removing part of the generated radiation from the resonator. Nonlinear losses created by the device of nonlinear losses lead to instability of the regime of continuous generation and implementation of the regime of regular undamped spikes. The laser output is a regular pulse train. The pulse duration is ~ 1 μs, the pulse energy is ~ 5 μJ, the distance between adjacent pulses is ~ 8.3 μs.

However, the specified fiber laser operating in the regime of regular undamped spikes, and not in the mode of passive mode synchronization, has the disadvantage that each generated spike is formed from the initial seed field, the role of which is played by intracavity spontaneous emission (Ya.I. Khanin, "Fundamentals of Laser Dynamics, Section 3.2.3. - M.: Science, Fizmatlit. 368 pp. 1999; A. Komarov, N. Leblond, F. Sanchez," Theoretical analysis of the operating mode of a passively mode-locked fiber laser through nonlinear polarization rotation ", Phys. Rev. A. 72, pp. 063811 (7), 2005), resulting in each output pulse ha occurs has its own, independent of previous history, random, non-reproducible spatial-temporal structure of the field. Such stochastization of the generated pulses is caused by the stochasticity of the intracavity spontaneous emission, which is the initial seed field from which each peak is formed. As a result, these impulses are not stable and reproducible.

The objective (technical result) of the present invention is to obtain stable and reproducible high-energy light pulses.

The problem is solved by the fact that in a fiber laser for generating high-energy light pulses containing a pump source, a coupler of input radiation pumping, a fiber ring resonator ~ 10 m long, which includes an active fiber, a nonlinear loss device and a coupler of outputting generated radiation from a ring resonator introduced a passive fiber of a certain length, an additional coupler outputting radiation from a fiber ring resonator, an additional coupler input from teaching a fiber ring resonator, the passive fiber with one of its ends is connected with an additional coupler radiation output from the fiber ring resonator, and the other end is connected to a further coupler input radiation into the fiber ring resonator.

The drawing shows a structural diagram of the proposed fiber laser for generating high-energy light pulses of light.

The proposed fiber laser for generating high-energy light pulses contains a pump source 1 IN, a coupler for inputting pump radiation 2, a fiber ring resonator ~ 10 m long, which includes an active fiber 3, a device for nonlinear loss 4 of an UNP, and a coupler for outputting the generated radiation from the ring resonator 5, as well as an additional coupler 6 for outputting the generated radiation from the fiber ring resonator, a passive fiber of a certain length 7, an additional coupler 8 for introducing radiation into the wave horse ring resonator.

In this case, the pump source 1 ID is connected to one end of the input coupler for pump radiation 2, the other end of which is connected to a fiber ring resonator ~ 10 m long, which includes an active fiber 3, a nonlinear loss device 4 of the UNP, and a coupler for outputting the generated radiation from the ring resonator 5, and the passive fiber 7 is connected at one of its ends to an additional coupler 6 of outputting radiation from a fiber ring resonator, and is connected at its other end to an additional input coupler 8 and radiation in the fiber ring resonator.

The proposed fiber laser operates as follows. In a ring resonator containing an active fiber 3 activated by rare-earth metal ions, which serves as an amplifier, and a device for nonlinear losses 4 of the SNF, radiation is formed in the form of regular undamped spikes. Part of the radiation of each such peak through an additional coupler 6 of the output of the generated radiation from the fiber ring resonator is directed to the passive fiber 7 and then through the additional coupler 8 of the radiation input into the fiber ring resonator again enters the fiber ring resonator containing the active fiber 3. The length of the passive fiber is selected such so that the pulse propagation time along it coincides with the time interval between adjacent spikes generated in the fiber ring resonance ore, and accordingly, is determined by the formula:

L = T⋅υ,

where T is the time interval between adjacent spikes, which is a characteristic of a fiber laser operating in the regime of regular undamped spikes, and determined by standard measurement methods,

υ = 2⋅10 ⁸ m / s - the speed of light propagation in the fiber.

As a result, each subsequent peak in the fiber ring resonator will be generated from the seed radiation of the previous peak (the fraction of radiation returned through the passive fiber to the fiber ring resonator containing active fiber 3 should be such that the effect of stochastic spontaneous radiation on the formation of the next peak is negligible small). The resulting continuity of the characteristics of each subsequent and previous spikes provides a mode of passive mode locking in the proposed laser and eliminates the stochastization of the generated pulses associated with spontaneous emission, that is, ensures the reproducibility and stability of the generated high-energy light pulses. Note that for the parameters of the laser, which is the prototype of the proposed fiber laser for generating high-energy light pulses, the length L of the passive fiber 7 should be about 1.66 km, found by the formula L = T⋅υ, where the time interval between adjacent spikes is T = 8.3 μs. Since the time interval T between adjacent spikes depends on the pump power, by varying this power, it is possible to precisely match the spiked spacing with the time the pulse travels through the passive fiber 7. In the proposed fiber laser, a hybrid mode of regular undamped spikes and a passive mode are implemented to generate high-energy light pulses laser mode synchronization.

In the case of using extra-long ring resonators to generate high-energy light pulses (see: SM Kobtsev, SV Kukarin, SV Smirnov, and YS Fedotov, "High-energy mode-locked all-fiber laser with ultralong resonator", Laser Physics. 20, No. 2, pp. 351-356, 2010), a high-energy generated pulse propagates along an extended passive fiber, which leads to significant nonlinear effects that contribute to the fragmentation of the generated pulse, which worsens its quality. In the proposed embodiment, a fiber laser for generating high-energy light pulses, a pulse with a significantly lower intensity propagates through the passive fiber 7, which eliminates the manifestation of these nonlinear effects. The nonlinear mechanism of the formation of light pulses in the proposed fiber laser for generating high-energy light pulses is substantially associated with gain saturation. Moreover, for the parameters of the fiber laser, which is the prototype of this device, the energy of a single pulse is equal to the energy of a single generated spike and amounts to ~ 5 μJ. In addition, the proposed fiber laser for generating high-energy light pulses has significant potential for further increasing the energy of the generated pulses while maintaining their stability and reproducibility. So, when switching from the regime of regular undamped spikes to the regime of regular giant pulses, the energy of the generated pulses can be significantly increased.

Thus, by using a fiber laser to generate high-energy light pulses operating in the regime of regular undamped spikes, the output of the output of the generated radiation from the fiber ring resonator through an additional coupler 6 of a certain part of the generated radiation and its transmission through the passive fiber 7 with the pulse propagation time through it coinciding with the time interval between adjacent spikes, with the subsequent supply of this radiation to the fiber ring resonance p coupler 8 via an additional input radiation in the fiber ring resonator is achieved the formation of stable and repeatable high energy light pulses.

Claims (4)

A fiber laser for generating high-energy light pulses, comprising a pump source, a pump radiation input coupler, a ~ 10 m fiber ring resonator including an active fiber, a nonlinear loss device, and a generated radiation coupler from the ring resonator, characterized in that additional coupler for outputting generated radiation from a fiber ring resonator, passive fiber, additional coupler for introducing radiation into a fiber ring a resonator, the pump source being connected to one of the ends of the pump radiation input coupler, the other end of which is connected to the fiber ring resonator, and the passive fiber is connected to the additional coupler of the radiation output from the fiber ring resonator by one of its ends and connected to the additional coupler by its other end input radiation into a fiber ring resonator, while the length of the passive fiber is determined by the formula: L = T⋅υ, where T is the time interval between adjacent spikes, υ is the speed of light propagation in the fiber.

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