RU2382458C1 - Compact solid-state laser with longitudinal semiconductor pumping - Google Patents

Abstract

FIELD: physics; optics.

SUBSTANCE: compact solid-state laser with longitudinal pumping has an optical module which has a line of diodes, a housing in which there is a resonator with mirrors, an active element, a heat-removing jacket and a pumping lens. The rear mirror of the resonator is made in form of a separate optical element. The active element is fitted in the radially symmetrical heat-removing jacket mounted between the mirrors, and a support is made at the centre of the heat removing jacket. Between lateral surface of the active element and the support of the jacket there is a lining made from heat-conducting material. An optical module is placed outside the housing and is connected to the laser by an optical fibre connected to the pumping lens which is fitted on the butt-end of the laser housing on the side of the rear mirror of the resonator.

EFFECT: increased laser power with high radiation beam quality, as well as simplification of design, which reduces cost, simplifies assembling and improves maintainability of the laser.

2 cl, 3 dwg

Description

The invention relates to the field of quantum electronics and laser technology systems. A compact solid-state laser with longitudinal semiconductor pumping can be used as part of laser technological systems designed for surface treatment (marking) of various materials, in instrumentation, for optical communication and in medicine.

A longitudinally pumped solid-state laser is known in which the radiation of two laser diodes is focused by the first optical system, added by a polarizing prism, and focused by the second optical system into the active element of the solid-state laser [Kuratiev I.I. etc. Neodymium emitters with laser diode pumping. Izvestiya AN SSSR, ser. physical. - M .: Nauka, 1990, v. 54, N10]. The laser resonator is formed by the face of the active element facing the second focusing system and the output mirror. To maintain the required pump wavelength, the laser diodes are mounted on two micro-refrigerators supporting the given operating temperature of the diodes. The laser is characterized by relatively low power and is intended for use in laboratory conditions.

Known solid-state laser with longitudinal pumping [RF Patent No. 2172544]. The laser includes a series-connected optical pump module and a laser cavity with an output mirror and an active element glued by a heat-conducting compound into a calibrated lodgement. The lodgement is made on the side of the optical pump module in a cylindrical cavity of the resonator mounted in the laser housing coaxially with the optical axis of the pump module. The lodgement gauge D = d + (5-50) microns, where d is the diameter of the active element. The technical result of the invention: providing angular stabilization of radiation in a wide temperature range. The laser has low power in the continuous emission mode and cannot operate in the mode of pulse generation with high peak power.

A longitudinally pumped solid-state laser was selected as a prototype [RF patent No. 2172544]. The laser includes a series-connected optical pump module, a laser resonator with an active element and an output mirror. The active element is glued by a heat-conducting compound into a calibrated lodgement, which is made from the side of the optical pump module in a cylindrical cavity of the resonator mounted in the laser housing coaxially with the optical axis of the pump module. The resonator is made in the form of a cylindrical rim, the active element is glued on one side, and the output mirror of the resonator at the opposite end.

The disadvantages of the laser are the low power of the laser radiation, which does not allow its use, for example, to solve the problems of laser technology, the impossibility of generating radiation pulses with high peak power in the regime of Q-switching of the cavity with an active optical shutter.

The objective is to increase the laser power with a high quality of the radiation beam, expand the scope, simplify the design of the laser, which reduces the cost of the product and simplifies the assembly process, improves the maintainability of the laser during operation.

A compact longitudinal-pumped solid-state laser is proposed, which includes a housing in which a pump lens, a rear cavity mirror, an active element in a heat sink jacket, and a front cavity resonator are mounted in series. The front mirror of the resonator is mounted on the right end of the housing in the adjustment frame, which has two angular degrees of freedom, and the rear mirror of the resonator is made in the form of a separate optical element. The active element is installed in a radially symmetric heat sink jacket, mounted between the mirrors, in the center of which a lodgement is made in which the active element is placed. Between the lateral surface of the element and the mounting surface of the tool tray, a gasket of heat-conducting material is placed. The optical module is moved outside the laser housing and is connected to the laser by an optical fiber connected to the pump lens, which is mounted on the end of the laser housing from the side of the rear mirror of the resonator.

The laser may include an optical shutter, which is installed between the active element and the front mirror of the resonator.

The distance between the mirrors is the base of the resonator, and the position of the active element inside the resonator is determined by calculation, based on the required laser output power, the condition for the generation of the TEM ₀₀ mode, and also the criterion for the stability of the resonator [Ananiev Yu.A. Optical resonators and laser beams. - M .: Nauka, 1990, 263 p.].

Overheating of the active element with subsequent disruption of generation is prevented by efficient radially symmetric heat removal through the side surface of the element to the housing and heat dissipation into the environment. That is why the active element is installed in the lodgement of the “shirt” made of a material that conducts heat well, such as copper. Good continuous thermal contact of the side surface of the active element with the lodgement of the shirt is ensured by means of a gasket, for example, a foil of soft metal, for example indium, wrapped around the element. A shirt with an element placed in the laser housing between the mirrors of the resonator. Thermal contact of the shirt with the body is ensured by a heat-conducting pad. The outer surface of the housing may have ribs to increase heat transfer to the environment, which allows to increase the laser power. The end pumping of the active element is carried out using a pump lens, which focuses the pump radiation into the central part of the end of the active element. The pump radiation from the diode array is transmitted to the lens via optical fiber, which allows to obtain a high quality radiation beam.

The shirt has half rings, the inner radius of which is equal to the radius of the active element. When the shirt half-rings compress the lateral surface of the active element wrapped by a gasket, for example, a foil with a force providing plastic deformation of the foil, redistribution of the foil material occurs, which completely fills the gap between the surfaces. The high thermal conductivity of the gasket provides rapid radially symmetric heat removal from the active element. The described design of the shirt provides a radially symmetric thermal field in the active element, and therefore it becomes possible to further increase the pump power with a corresponding increase in the output power of the laser radiation. In addition, this contributes to the generation of single-mode radiation TEM ₀₀ , which is a sign of high quality radiation.

The design of the laser allows you to install between the active element and the front resonator mirror optical shutter and work in the modulation mode of the quality factor of the resonator. In this case, the laser generates a periodic sequence of radiation pulses with high peak power, which allows to expand the scope. Such lasers are widely used, for example, in laser technological installations designed for marking and engraving the surface of various materials.

The proposed laser has a minimum number of mechanical and optical parts, which reduces the cost of the product and simplifies the assembly process. The installation of the active element in the heat sink jacket allows you to change the active element without dismantling the resonator, which increases the maintainability of the laser during operation.

The use of an optical shutter, such as an acousto-optical shutter, allows you to expand the field of laser use.

Thus, the combination of distinctive features is sufficient and necessary to complete the task.

A compact solid-state laser with longitudinal semiconductor pumping comprises a housing 1, optical fiber 2, a pump lens 3, a rear resonator mirror — a separate optical element 4, an active element 5, a heat sink 6, an optical shutter 7, a front resonator mirror 8, and an optical module 9 (FIG. one).

The laser operates as follows.

Tests were made of the layout of the laser, assembled in accordance with the circuit shown in figure 1. The modal composition of the laser beam was recorded using a Spiricon LBA 300 laser beam quality analyzer. An image of the intensity distribution in the far section of the laser beam is shown in FIG. 3. The distribution is Gaussian, which corresponds to the TEM ₀₀ mode.

The optical elements of the laser are mounted in a rigid supporting body 1, for example, of a cylindrical shape. The pump radiation from the diode array located in the optical module is transmitted to the lens through the optical fiber 2 to the pump lens 3, which through the rear mirror of the resonator 4 concentrates the radiation in the volume of, for example, a cylindrical active element 5. The active element is made of yttrium aluminum garnet activated by neodymium ions , activator concentration ~ 0.9-1.1%. The transverse size of the concentration region is of the order of ~ (λ × L) ^1/2 . A multilayer dielectric reflective coating is applied to the rear mirror of the resonator, which almost completely reflects radiation with a wavelength of 1.06 μm and well transmits pump radiation of 0.808 μm. The front mirror of the resonator is mounted on the right end of the housing in the alignment frame, which has two angular degrees of freedom. The active element 5 is installed in the lodgement of the copper shirt 6 (Figure 2). The shirt consists of two half rings 6a and 6b, which cover the side surface of the active element (Figure 2). Between the lateral surface of the element and the surface of the lodgement of the shirt, for example, an indium foil with a thickness of, for example, 120 μm is embedded.

The shirt is installed inside the housing 1 and is pressed against the inner vertical wall of the housing by the end surface.

When the laser is turned on, the pump radiation from the optical module located in the power supply unit passes through the optical fiber 2 to the pump lens 3, which focuses the radiation inside the active element 5. Neodymium ions contained in the active element 5 absorb the pump radiation quanta and become excited. After some time, neodymium ions return to their original energy state, emitting part of the stored energy in the form of photons with a wavelength of 1.064 μm. Photons emerging from the active element 5 and propagating along the laser axis in the direction of the rear mirror 4 of the resonator are reflected from this mirror and returned to the active element, where there is an avalanche-like increase in the number of photons - light generation due to the process of stimulated emission. Further, the amplified photon flux propagates in the direction of the front mirror 8 of the resonator, which part of the photons reflects, and they return to the active element, thereby creating conditions for supporting the process of light generation, and part passes out. Thus, a beam of continuous radiation is formed at the laser output, which can be used to solve various practical problems.

An optical shutter can be installed between the active element and the front mirror of the resonator 7. In the case when the shutter is turned on, the amplified photon flux from the active element does not reach the front mirror of the resonator, which leads to generation failure - there is no radiation beam at the laser output, and the active element is absent energy accumulates. When the shutter is turned off, there is a surge of energy stored in the element in the form of a short radiation pulse with a high peak power. Periodically turning the shutter on and off leads to the synchronous formation of a beam of radiation at the laser output in the form of repeated light pulses.

It should be noted that the efficiency of converting the energy of pump radiation into laser energy is not more than 50%. The remaining energy is released in the active element 5 in the form of heat, which is transferred through the side surface of the element to the jacket 6 and then to the housing 1, from the surface of which the heat is dissipated into the environment.

Technical and economic effect

The totality of the proposed technical solutions provides an output laser radiation power of at least 10 W, which is significantly higher than that of the prototype, and has a modal composition of radiation: TEM ₀₀ . The proposed laser has a simple design with a minimum number of mechanical and optical parts, which reduces the cost of the product and simplifies the assembly process. The installation of the active element in the heat sink jacket allows you to change the active element without dismantling the resonator, which increases the maintainability of the laser during operation.

The use of an optical shutter, for example, an acousto-optical, allows the generation of high-power laser pulses with an energy of up to 5 mJ, a duration of 25-60 ns, and a repetition rate of up to 100 kHz. Such a laser can be used to solve a number of problems in laser technology, for example, in technological installations for laser engraving and surface marking of various products, installations for adjusting the value of film resistors, etc.

Claims (2)

1. A compact longitudinal-pumped solid-state laser, including an optical module containing a line of diodes, a housing in which a resonator with mirrors is installed, an active element placed in a lodgement, characterized in that it further comprises a heat-dissipating shirt, optical fiber and a pump lens, the back one the resonator mirror is made in the form of a separate optical element, the active element is installed in a radially symmetric heat sink, fixed between the mirrors, and a lodgement is made in the center of it, between a gasket of heat-conducting material is placed near the side surface of the element and the lodgement of the shirt, the optical module is removed from the housing and connected to the laser by an optical fiber connected to the pump lens mounted on the end of the laser housing from the side of the rear mirror of the resonator. 2. The compact solid-state laser according to claim 1, characterized in that an optical shutter is installed between the active element and the front mirror of the resonator.

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