RU2633285C1 - Fibre operating generator - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: generator contains a pumping source and a resonator consisting of two fibre parts - an active nonlinear loop and a long linear part connected via a four-port fibre coupler; the active loop forms a nonlinear loop mirror and active fibre section, the long linear part contains a long segment of passive fibre, with one end connected to a Faraday mirror; in accordance with the invention, in order to provide a stable mode for generating pulsed radiation with a high pulse energy (>4 μJ) and high average radiation powers, a loop of intracavity power distribution is additionally introduced into the long linear part of the resonator, consisting of an adjustable power attenuator, an additional active fibre cutoff, an additional fibre combiner of wave lengths with an additional pump source, an optical isolator, two fibre polarization dividers having a minimum of three fibre ports.

EFFECT: stable mode of generating pulsed radiation by reducing the influence of nonlinear effects in the long part of the resonator.

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Description

The invention relates to lasers - devices for generation using stimulating radiation of coherent electromagnetic waves.

Ultra-long fiber master oscillators with passive synchronization of radiation modes are known [1-4], the pulse energy of which increases due to an increase in the length of the resonator of the fiber master oscillator. The main disadvantage of fiber master oscillators of this type is the limitation of the pulse energy at a level of 4 μJ due to the critical growth of nonlinear effects, which lead to a violation of the synchronization mode of the radiation modes of the fiber master oscillator with an output pulse energy of more than ~ 4 μJ.

Closest to the claimed device is a fiber master oscillator with passive synchronization of radiation modes in a linear-ring resonator [5].

In this prototype, mode synchronization is based on the effect of nonlinear polarization evolution. A feature of this prototype is the linear-circular design of the resonator using a Faraday mirror (FZ) in the long linear part of the resonator, which allows you to double the length of the resonator due to the double pass of the long linear part of the resonator and, accordingly, double the energy of the pulses, and also allows through the use of the FS, to compensate in this part of the resonator a linear change in the polarization state that occurs at the places of bends and inhomogeneities in this long fiber and under environmental dangers (when the temperature changes, when squeezing and bending the optical fiber, etc.). However, the FZ does not compensate for the rotation of the polarization state (both linear and nonlinear, associated with high radiation intensity) in the annular part of the resonator, as well as the nonlinear rotation of the polarization state in the long linear part of the resonator.

The disadvantages of this prototype are:

1. The limitation of the maximum pulse energy at 1.7 μJ due to nonlinear effects arising in a long section of the cavity due to the large length of the optical fiber and the relatively high average power, leading to the decay of the pulses into subpulses.

2. The sensitivity of the master oscillator to environmental influences, leading to a linear change in the state of polarization in the annular part of the resonator, which, in turn, leads to a breakdown of the pulse generation mode.

3. The use of polarization controllers, the action of which is based on the deformation of the fiber.

The disadvantage of such controllers is their short-term stability. This is due to the change over time of the birefringence parameters of the optical fiber at the compression / twisting site due to its amorphous structure.

The problem to which the claimed invention is directed, is to create a fiber master oscillator with high pulse energy and passive synchronization of radiation modes, providing a stable mode of generation of pulsed radiation with a relatively high pulse energy (more than 4 μJ) by reducing the influence of nonlinear effects in the long part of the resonator and with a relatively high average output power (more than 0.3 W).

The problem is solved due to the fact that in the fiber master oscillator containing a pump source and a resonator, consisting of two fiber parts - an active nonlinear loop and a long linear part, connected by a four-port fiber coupler; the active loop forms a nonlinear loop mirror and contains a segment of active fiber, one end of which is connected to the first port of the four-port coupler, and the other end is connected to the output of a fiber combiner of wavelengths, the pump input of which is connected to the pump source, and the signal input is connected to the second port of the four-port coupler , in which the fourth port is used to output radiation from the resonator; the long linear part contains a long stretch of passive fiber, one end connected to a Faraday mirror; according to the invention, in order to ensure a stable mode of generation of pulsed radiation with high pulse energy (more than 4 μJ) and high average radiation powers, an intracavity power distribution loop is additionally introduced into the long linear part of the resonator, consisting of an adjustable power attenuator, an additional segment of active fiber, an additional fiber combiner of lengths waves with an additional pump source, an optical isolator, two fiber polarizing dividers having at least three fiber ports; the third port of the first fiber polarizing splitter is connected to the third port of the four-port coupler, and the first port is connected to the input of an adjustable power attenuator, the output of which is connected to the first port of the second fiber polarizing splitter; the second port of the first fiber polarizing divider is connected to one end of an additional segment of active fiber, the other end of which is connected to the output of the additional fiber wavelength combiner, the pump input of which is connected to an additional pump source, and the signal input is connected to the output of the optical isolator; the input of the insulator is connected to the second port of the second fiber polarizing divider, the third port of which is connected to the second end of a long segment of the passive fiber.

The technical result provided by the given set of features is the possibility of implementing stable passive synchronization of radiation modes in a fiber master oscillator, which provides a mode for generating pulses with a high energy of more than 4 μJ and a high average power of more than 0.3 W, high efficiency of converting the optical pump energy into the energy of the generated pulses , the reliability of the design and the absence of the need for maintenance during operation and after transportation.

The invention is illustrated by the diagram of the proposed device, shown in FIG. 1, where:

1 - pump source,

2 - resonator fiber master oscillator,

3 - active resonator loop,

4 - loop intracavity power distribution,

5 - fiber four-port coupler,

5.1, 5.2, 5.3, 5.4 - the first, second, third, fourth ports of the fiber four-port coupler 5,

6 - segment of active fiber,

7 - fiber combiner wavelengths,

8 - the first polarizing divider,

8.1, 8.2, 8.3, 8.4, - the first, second, third, fourth ports of the polarization divider 8,

9 - attenuator,

10 - second polarization divider,

10.1, 10.2, 10.3, 10.4 - the first, second, third, fourth ports of the polarization divider 10,

11 is a long segment of a passive fiber,

12 - Faraday mirror

13 - optical isolator,

14 is an additional combiner of wavelengths,

15 is an additional segment of active fiber,

16 is an additional source of pumping,

17 - output of a fiber laser.

The device operates as follows.

The radiation from the pump source 1 with a wavelength of λ ₀ is introduced into the resonator 2 of the fiber master oscillator, through the fiber combiner 7 it enters the segment of the active fiber 6, where it is absorbed, causing transitions of atoms to the excited quantum state, resulting in generation and amplification of radiation by the generation wavelength λ ₁ .

From the active loop 3, forming a nonlinear loop mirror (NPZ), radiation with a wavelength of λ ₁ through the four-port fiber coupler 5 through the third port 5.3 partially enters the long linear part of the resonator 2, and the other part of the radiation is output from the resonator through the fourth port 5.4 of the four-port fiber tap 5.

The emitted part of the radiation from port 5.3 of the four-port fiber coupler 5 through the third port 8.3 of the first polarizing divider 8 falls into the loop of the intracavity power distribution 4.

In this intracavity power distribution loop 4, the radiation propagates in the forward direction (from right to left) along the upper path from port 8.1 of the first polarizing divider 8 to port 10.1 of the second polarizing divider 10 and in the opposite direction (from left to right) from port 10.2 of the second polarizing divider 10 to the port 8.2 of the first polarizing divider 8.

Having passed through the first polarizing divider 8 from the port 8.3. to port 8.1, the radiation is divided into two components with linear polarizations orthogonal to each other. One of these radiation components goes out through port 8.1 of the first polarizing divider 8 and passes through attenuator 9, where a part of the power of this radiation is attenuated, and the other radiation component goes through port 8.2 of the first polarizing divider 8 and is blocked by insulator 13. Linearly polarized through the attenuator 9 part of the radiation enters port 10.1 and exits through port 10.3 of the second polarization divider 10.

Then the radiation passes through a long segment of the passive fiber 11 and is reflected from the Faraday mirror 12. When reflected from the Faraday mirror 12, the radiation polarization is rotated 90 degrees. The reflected radiation, having passed a long length of the passive fiber 11, returns to port 10.3 of the second polarizing divider 10. Since the returned radiation is linearly polarized orthogonal to the polarization of the radiation coming out of port 10.3, this returned radiation leaves port 10.2 of the second polarizing divider 10. Next, the radiation passes the optical insulator 13 and an additional combiner of wavelengths 14 and falls into an additional segment of the active fiber 15, where due to absorption of radiation from an additional source As a pump 16 with a wavelength of λ ₀ , introduced into an additional segment of active fiber 15 through an additional combiner of wavelengths 14, the radiation power entering the additional segment of active fiber 15 at a generation wavelength λ ₁ is amplified and restored to the power level of the loop intracavity power distribution 4.

Amplified radiation enters port 8.2 and leaves port 8.3 of the first polarization divider 8. Then, through port 5.3 of the four-port fiber coupler 5, the radiation returns to the active loop 3.

When entering the active loop 3, the incoming radiation at the generation wavelength λ ₁ is divided by a four-port fiber coupler 5 into two parts propagating in the opposite direction from port 5.1 to port 5.2 of the four-port fiber coupler 5 and vice versa. These parts of the radiation during the passage of the active loop 3 receive different nonlinear phase incursions, depending on the division ratio of the fiber four-port coupler 5, the gain in the segment of the active fiber 6, the lengths of the segments of the active and passive fibers of the active loop 3.

After the active loop passes, the indicated parts of the radiation at the generation wavelength λ ₁ interfere with each other and again exit the active loop 3. Part of the radiation through port 5.3 again falls into the intracavity power distribution loop 4, and the other part through port 5.4 is output from the fiber master resonator generator 2. The transmission coefficient to port 5.3 and port 5.4 of the four-port fiber coupler 5 depends on the difference in the nonlinear phase shift Δφ of the radiation propagating in the active loop 3.

The intracavity power distribution loop 4 serves to reduce the radiation power in front of a long segment of the passive fiber 11 in order to reduce non-linear effects in this part of the resonator of the fiber master oscillator. And also, the intracavity power distribution loop 4 serves to restore the radiation power in front of the active loop 3 in order to increase the signal-to-noise ratio (similar to the preamplifier stage in amplifiers).

A nonlinear loop mirror (SCR), forming an active loop 4 and used to obtain the mode synchronization mode, is less sensitive to environmental influences than in the case of fiber master oscillators with mode synchronization based on the effect of nonlinear polarization evolution, since in fiber master oscillators with The refinery mode synchronization mode is caused by the difference in the nonlinear phase incursion, less sensitive to changes in the polarization of radiation that occur under the influence of the environment.

Together, the use of a refiner and an intracavity power distribution loop in a fiber master oscillator provides stable generation of pulses with an energy of more than 4 μJ (Optics Express. Vol.24, Issue 6, pp.6650-6655 (2016)).

Sources of information used:

1. Optics Express. - 2008 .-- Vol.16. - No. 26. - P. 21936-21941.

2. Laser Physics Letters. - 2012. Vol. 9. - No. 1. - P. 59-67.

3. Optics Express. - 2006. - Vol. 18. - No. 20. - P. 20673-20680.

4. ESOC 2010, 19-23 September, 2010, Torino, Italy (http://www.nsu.ru/srd/lls/pdfs/Mode-Locking_in_25-km_Fibre_Laser_(ECOC-2010).pdf)

5. Laser Physics Letters. - 2010 .-- Vol. 7. - No. 9. - P. 661-665.

Claims (1)

A fiber master oscillator comprising a pump source and a resonator, consisting of two fiber parts - an active nonlinear loop and a long linear part, connected by a four-port fiber coupler; the active loop forms a nonlinear loop mirror and contains a segment of active fiber, one end of which is connected to the first port of the four-port coupler, and the other end is connected to the output of a fiber combiner of wavelengths, the pump input of which is connected to the pump source, and the signal input is connected to the second port of the four-port coupler , in which the fourth port is used to output radiation from the resonator; the long linear part contains a long stretch of passive fiber, one end connected to a Faraday mirror; characterized in that an intracavity power distribution loop is additionally introduced into the long linear part of the resonator, consisting of an adjustable power attenuator, an additional segment of active fiber, an additional fiber wavelength combiner with an additional pump source, an optical isolator, two fiber polarization dividers (first and second), having at least three fiber ports; the third port of the first fiber polarizing splitter is connected to the third port of the four-port coupler, and the first port is connected to the input of an adjustable power attenuator, the output of which is connected to the first port of the second fiber polarizing splitter; the second port of the first fiber polarizing divider is connected to one end of an additional segment of active fiber, the other end of which is connected to the output of the additional fiber wavelength combiner, the pump input of which is connected to an additional pump source, and the signal input is connected to the output of the optical isolator; the input of the insulator is connected to the second port of the second fiber polarizing divider, the third port of which is connected to the second end of a long segment of the passive fiber.

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