JP2011159932A - Gas laser amplifier device and optical axis adjusting method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gas laser amplifier device that has a high amplification gain and suppresses parasitic oscillation with simple constitution, and to provide an optical axis adjusting method thereof. <P>SOLUTION: The gas laser amplifier device includes a housing 1 in which a laser gas such as CO<SB>2</SB>is charged, a pair of discharge electrodes 15, 16 provided in the housing 1 and configured to excite the laser gas, mirrors 4, 5 provided in the housing 1 and configured to reflect a laser beam amplified by the laser gas, window members 2, 3 provided to the housing 1 and configured to allow the laser beam pass between the inside and outside of the housing, etc. The mirror 4 is a return mirror installed so as to reflect light having passed in a discharge region and then guide it into the same discharge region again. The mirror 5 is a return mirror installed so as to reflect the light reflected by the mirror 4 and guide it into the same discharge region again. The mirrors 4, 5 are installed not in parallel with each other. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to a gas laser amplifier for amplifying laser light using a laser medium such as CO ₂ and an optical axis adjusting method thereof.

  A general gas laser oscillator includes a low-pressure container filled with a laser medium gas (for example, a mixed gas composed of carbon dioxide gas, helium gas, nitrogen gas, etc.), and a rear mirror provided between the laser medium gas and an output mirror. An optical resonator that makes laser oscillation by reciprocating a laser beam, a laser medium gas supply unit that supplies laser medium gas to a low-pressure vessel, a laser medium gas exhaust unit that exhausts laser medium gas, and supplies energy to the laser medium gas A laser medium gas excitation means (for example, a discharge device) that circulates, a laser medium gas circulation device that circulates the laser medium gas, and a cooling means that cools the laser medium gas that has been excited to a high temperature.

  In such a gas laser oscillator, when parasitic oscillation occurs, excitation energy is consumed even outside the original oscillation region, so that the efficiency of the laser oscillator decreases.

  As a countermeasure against parasitic oscillation, in Patent Document 1 described below, a convex mirror is used for at least a part of a plurality of folding mirrors in an orthogonal gas laser oscillator in which a plurality of folding mirrors are provided between an output mirror and a rear mirror to form an optical resonator. It has been proposed.

  With such a configuration, the opposing folding mirror is a combination of a convex mirror and a convex mirror, or a combination of a convex mirror and a plane mirror (installed in parallel to each other). Since the laser beam between the folding mirrors quickly diverges from the folding mirror, the limit gain (threshold value) for maintaining laser oscillation increases. As a result, the occurrence of parasitic oscillation between the folding mirrors is suppressed.

  Further, Patent Document 2 below discloses a gas laser amplifying apparatus configured such that incident laser light is vertically incident on a feedback mirror so that the laser light passes through the same discharge region twice. In this configuration, since the amplified outgoing laser light returns to the optical path coaxial with the incident laser light, a special optical system combining a wave plate and a polarizer is indispensable for separating the outgoing laser light.

Japanese Patent Laid-Open No. 11-87807 JP 2008-85292 A

  In the configuration of Patent Document 1, since the convex mirror is used as the folding mirror, the laser beam is diffused by the convex mirror, and an optical system for beam shaping with respect to the incident laser beam or the emitted laser beam is required, and the configuration as a whole is configured. It becomes complicated.

  In the configuration of Patent Document 2, the optical system becomes complicated and the optical loss increases.

  An object of the present invention is to provide a gas laser amplifier that has a high amplification gain and can suppress parasitic oscillation with a simple configuration.

  Another object of the present invention is to provide a method for adjusting the optical axis of a gas laser amplifier capable of suppressing parasitic oscillation with a simple procedure.

In order to achieve the above object, a gas laser amplifying apparatus according to the present invention includes a housing for enclosing a laser gas,
A discharge electrode provided in the housing for exciting the laser gas;
At least two mirrors provided in the housing for reflecting the laser light amplified by the laser gas;
A window member that is provided in the housing and allows the passage of laser light between the inside and outside of the housing;
The first mirror is a folding mirror that is disposed so as to reflect light that has passed through a discharge region determined by a certain pair of discharge electrodes of the discharge electrodes and to guide the light again into the discharge region;
The second mirror is a folding mirror installed so as to reflect the light reflected by the first mirror and guide it again into the discharge region,
The first and second mirrors are installed non-parallel to each other.

A gas laser amplifying apparatus according to the present invention includes a housing for enclosing a laser gas,
A discharge electrode provided in the housing for exciting the laser gas;
At least one mirror provided in the housing for reflecting the laser light amplified by the laser gas;
A window member that is provided in the housing and allows the passage of laser light between the inside and outside of the housing;
The first mirror is a folding mirror that is disposed so as to reflect light that has passed through a discharge region determined by a certain pair of discharge electrodes of the discharge electrodes and to guide the light again into the discharge region;
The optical axis of the laser beam incident on the first mirror and the optical axis of the laser beam emitted from the first mirror are not coaxial with each other.

A gas laser amplifying apparatus according to the present invention includes a housing for enclosing a laser gas,
A discharge electrode provided in the housing for exciting the laser gas;
At least three mirrors provided in the housing for reflecting the laser light amplified by the laser gas;
A window member that is provided in the housing and allows the passage of laser light between the inside and outside of the housing;
The first mirror is a folding mirror that is disposed so as to reflect light that has passed through a discharge region determined by a certain pair of discharge electrodes of the discharge electrodes and to guide the light again into the discharge region;
The second mirror is a folding mirror installed so as to reflect the light reflected by the first mirror and guide it again into the discharge region,
The third mirror is a folding mirror that is installed so as to reflect the light reflected by the second mirror and guide it back into the discharge region.
The first, second, and third mirrors are installed non-parallel to each other.

The present invention also includes a housing for enclosing laser gas,
A discharge electrode provided in the housing for exciting the laser gas;
At least one mirror provided in the housing for reflecting the laser light amplified by the laser gas;
An optical axis adjustment method for a gas laser amplifying apparatus, which is provided in a housing and includes a window member for allowing passage of laser light between the inside and outside of the housing,
Detecting the power of parasitic oscillation generated between the mirrors in a state where the laser gas is excited;
Adjusting the installation angle of each mirror so that the detected parasitic oscillation power is maximized;
Shifting the installation angle of at least one mirror so that the detected parasitic oscillation power is minimized.

The present invention also includes a housing for enclosing laser gas,
A discharge electrode provided in the housing for exciting the laser gas;
At least one mirror provided in the housing for reflecting the laser light amplified by the laser gas;
An optical axis adjustment method for a gas laser amplifying apparatus, which is provided in a housing and includes a window member for allowing passage of laser light between the inside and outside of the housing,
A first aperture having two openings and a second aperture having two openings are arranged at predetermined intervals along the optical path of the laser beam, and one opening center of the first aperture and one opening center of the second aperture Adjusting the first straight line connecting the second aperture center of the first aperture and the second straight line connecting the other aperture center of the second aperture to a twisted position;
Introducing guide light along the optical axis of each mirror;
Adjusting the installation angle of each mirror so that the introduced guide light can pass through all the openings.

  According to the present invention, a gas laser amplification device having a high amplification gain can be realized by adopting a mirror arrangement in which laser light passes through the discharge region a plurality of times. Further, by adjusting the folding mirrors so that they are not parallel to each other, parasitic oscillation can be suppressed with a simple configuration.

It is a perspective view which shows Embodiment 1 of this invention. It is a perspective view which shows Embodiment 2 of this invention. It is a perspective view which shows Embodiment 3 of this invention. It is explanatory drawing which defines a discharge area. It is a perspective view which shows Embodiment 4 of this invention. It is a graph which shows the relationship between the parallelism of a mirror, and parasitic oscillation. It is a perspective view which shows Embodiment 5 of this invention. It is the side view which looked at the relative position of each opening of an aperture, a mirror, and a window member from the A direction of FIG. It is a perspective view which shows an example of the shape of two apertures.

Embodiment 1 FIG.
FIG. 1 is a perspective view showing Embodiment 1 of the present invention. The gas laser amplifying apparatus is provided in the housing 1 for enclosing a laser gas such as CO ₂ , a pair of discharge electrodes 15 and 16 for exciting the laser gas, and the housing 1. Mirrors 4 and 5 for reflecting the laser light amplified by the laser gas, and window members 2 and 3 provided in the housing 1 for allowing the laser light to pass between the inside and the outside of the housing. Composed.

  A window member 2 is provided on one side of the housing 1, and a window member 3 is provided on the opposite side. The mirror 4 is attached to the side surface of the housing 1 in which the window member 2 is arranged, and the mirror 5 is attached to the side surface of the housing 1 in which the window member 3 is arranged.

  The mirrors 4 and 5 are preferably flat mirrors having a flat optical surface, and are attached to the side surface of the housing 1 via an angle adjustment mechanism so that the attachment angle can be finely adjusted. The mirrors 4 and 5 are installed non-parallel to each other, and are set so that the normal of the optical surface of the mirror 4 and the normal of the optical surface of the mirror 5 form an angle of about 1 mrad, for example.

  The discharge electrodes 15 and 16 are configured as electrodes that are metallized on the ceramic plates 11 and 12 that are electrode support members. When an AC voltage is applied between the discharge electrodes 15 and 16, a discharge occurs between the discharge electrode 15 and the discharge electrode 16, thereby exciting the laser gas.

  FIG. 4 is an explanatory diagram for defining the discharge region. The discharge region 19 is defined as a rectangular parallelepiped region sandwiched between the discharge electrodes 15 and 16. Accordingly, the laser gas existing in the discharge region 19 is excited, and the laser light passing through the discharge region 19 is amplified.

  Returning to FIG. 1, when laser light from an external laser oscillator or laser amplifier passes through the window member 2 and enters the gas laser amplifying apparatus as incident laser light 21, it is reflected by the mirror 4 and subsequently reflected by the mirror 5. After passing through the window member 3, the laser beam is finally emitted as the emitted laser beam 22.

  The mirror 4 is a folding mirror that is installed so as to reflect the light that has passed through the discharge region and guide it again into the same discharge region. The mirror 5 is a folding mirror installed so as to reflect the light reflected by the mirror 4 and guide it again into the same discharge region. Accordingly, the laser light passes through the discharge region three times in the order of the optical path from the window member 2 to the mirror 4, the optical path from the mirror 4 to the mirror 5, and the optical path from the mirror 5 to the window member 3, for a total of three times. It will be amplified. Furthermore, by increasing the number of folding mirrors, the number of passes through the discharge region is also increased, and more efficient light amplification is possible.

Thus, a high amplification gain can be obtained by passing the laser beam through the same discharge region a plurality of times. The gain G is defined as gain G = emitted light power Po / incident light power Pi. At this time, the relationship of gain G ≧ exp [g ₀ × L] is established. Here, g ₀ is a small signal gain per unit length, and L is a geometric length in the longitudinal direction of the excitation medium, that is, a length in the longitudinal direction of the discharge region.

In the gas laser amplifier configured to pass the laser beam only once through the same discharge region, the gain of the laser beam does not exceed exp [g ₀ × L] which is a gain at the time of a small signal (for example, (See Amnon Yariv, Kadao Tada, et al., “Optical Electronics”, 5th edition (2000). Small signal and small signal gain refer to the condition of minute input that is close to zero.)

In the present embodiment, since the laser light is configured to pass through the same discharge region three times, the distance that the laser light passes through the discharge region is three times that in the case of one pass. For example, when a 10 W incident laser beam is amplified and a 150 W outgoing laser beam is extracted under an excitation condition of g ₀ × L = 1.2, the gain G is 15, and exp [g ₀ × L ] = 3.3 is exceeded.

  In addition, as described above, the mirrors 4 and 5 having a flat optical surface are disposed so as to form an angle shifted by about 1 mrad from parallel to each other, thereby providing an effect of suppressing parasitic oscillation with a simple configuration.

  Assuming that the mirrors 4 and 5 are installed in parallel to each other, the mirrors 4 and 5 serve as resonators, and laser oscillation is performed using spontaneously emitted light generated in the discharge region determined by the discharge electrodes 15 and 16 as seed light. Occur. This is called parasitic oscillation. When parasitic oscillation occurs, excitation energy is consumed even outside the original oscillation region, so that the efficiency of the laser amplifier is reduced.

  As a countermeasure, in the present embodiment, the mirrors 4 and 5 are installed so as to form an angle shifted by about 1 mrad from the parallel, so that the diffraction loss in the optical path that makes one round trip between the mirrors 4 and 5 increases. Therefore, parasitic oscillation using the spontaneous emission light generated in the discharge region as seed light does not occur, and parasitic oscillation can be suppressed with a simple configuration.

  In the present embodiment, it is preferable that the incident laser beam 21 and the emitted laser beam 22 are configured so as not to return on the same axis, thereby obtaining an effect of reducing the return light to the oscillator with a simple configuration.

  In the present embodiment, an example using two folding mirrors 4 and 5 is shown, but three or more folding mirrors may be used. In this case, any two of the three or more folding mirrors may be used. If it is installed so as to form a small angle (1 mrad as a guideline) from parallel, the same effect can be obtained.

  The minute angle of the folding mirror may be 1 mrad or more, and the same effect can be obtained as long as the laser light amplified in the discharge region can pass through the same discharge region again.

Embodiment 2. FIG.
FIG. 2 is a perspective view showing Embodiment 2 of the present invention. In the present embodiment, an example in which laser light is configured to pass through the same discharge region twice will be described.

The gas laser amplifying apparatus is provided in the housing 1 for enclosing a laser gas such as CO ₂ , a pair of discharge electrodes 15 and 16 for exciting the laser gas, and the housing 1. The mirror 4 is configured to reflect the laser light amplified by the laser gas, and the window member 2 is provided in the housing 1 and allows the laser light to pass between the inside and the outside of the housing.

  A window member 2 is provided on one side surface of the housing 1, and a mirror 4 is attached to the opposite side surface. The mirror 4 is preferably a plane mirror having a flat optical surface, and is attached to the side surface of the housing 1 via an angle adjustment mechanism so that the attachment angle can be finely adjusted.

  The discharge electrodes 15 and 16 are configured as electrodes that are metallized on the ceramic plates 11 and 12 that are electrode support members. As shown in FIG. 4, the discharge region 19 is defined as a rectangular parallelepiped region sandwiched between the discharge electrodes 15 and 16. When an AC voltage is applied between the discharge electrodes 15 and 16, a discharge is generated between the discharge electrode 15 and the discharge electrode 16, thereby exciting the laser gas, and as a result, the laser light passing through the discharge region 19 is amplified.

  When laser light from an external laser oscillator or laser amplifier passes through the window member 2 and enters the gas laser amplifying apparatus as incident laser light 21, it is reflected by the mirror 4 and passes through the window member 2 again. The light 22 is emitted.

  Here, in order to prevent the optical axis of the incident laser beam 21 and the optical axis of the emitted laser beam 22 from being coaxial with each other, the incident laser beam 21 is, for example, at an angle of about 10 mrad with respect to the normal of the optical surface of the mirror 4. Incidently incident. At this time, the emitted laser light 22 is also reflected at an angle of about 10 mrad with respect to the normal of the optical surface of the mirror 4.

  The mirror 4 is a folding mirror that is installed so as to reflect the light that has passed through the discharge region and guide it again into the same discharge region. Accordingly, the laser light passes through the discharge region twice in the order of the optical path from the window member 2 to the mirror 4 and the optical path from the mirror 4 to the window member 2, and is amplified twice in total. Thus, a high amplification gain can be obtained by passing the laser beam through the same discharge region a plurality of times.

As with the first embodiment, the relationship of gain G = emitted light power Po / incident light power Pi ≧ exp [g ₀ × L] is established for the amplification gain. In the present embodiment, since the laser light passes through the same discharge region twice, the distance that the laser light passes through the discharge region is doubled compared to the case where the laser light passes once. For example, when 10 W of incident laser light is amplified and 40 W of emitted laser light is extracted under an excitation condition of g ₀ × L = 1.2, the gain G is 4, and exp [g ₀ × L ] = 3.3 is exceeded.

  In addition, as described above, the incident laser light 21 is, for example, about normal to the optical surface of the mirror 4 so that the optical axis of the incident laser light 21 and the optical axis of the emitted laser light 22 are not coaxial. By obliquely incident at an angle of 10 mrad, the effect of suppressing the return light to the oscillator is achieved with a simple configuration.

  In the present embodiment, the configuration in which the incident laser beam 21 and the emitted laser beam 22 pass through one window member 2 is shown. However, the window member through which the incident laser beam 21 passes and the window through which the emitted laser beam 22 passes. Even if the member is provided separately, the same effect can be obtained.

Embodiment 3 FIG.
FIG. 3 is a perspective view showing Embodiment 3 of the present invention. In the present embodiment, an example in which the laser beam is configured to pass through the same discharge region six times will be described.

The gas laser amplifying apparatus is provided in the housing 1 for enclosing a laser gas such as CO ₂ , a pair of discharge electrodes 15 and 16 for exciting the laser gas, and the housing 1. Mirrors 4, 5, 6 for reflecting the laser light amplified by the laser gas, and a window member 2 provided in the housing 1 for allowing the laser light to pass between the inside and the outside of the housing Composed.

  A window member 2 is provided on one side surface of the housing 1, and a mirror 5 is attached to the same side surface. Mirrors 4 and 6 are attached to the opposite side surfaces. The mirrors 4, 5, and 6 are preferably flat mirrors having a flat optical surface, and are attached to the side surface of the housing 1 via an angle adjustment mechanism so that the attachment angle can be finely adjusted.

  The mirrors 4 and 5 are installed non-parallel to each other, and are set so that the normal of the optical surface of the mirror 4 and the normal of the optical surface of the mirror 5 form an angle of about 1 mrad, for example. The mirrors 5 and 6 are also installed non-parallel to each other, and are set so that the normal of the optical surface of the mirror 5 and the normal of the optical surface of the mirror 6 form an angle of about 10 mrad, for example.

  The discharge electrodes 15 and 16 are configured as electrodes that are metallized on the ceramic plates 11 and 12 that are electrode support members. As shown in FIG. 4, the discharge region 19 is defined as a rectangular parallelepiped region sandwiched between the discharge electrodes 15 and 16. When an AC voltage is applied between the discharge electrodes 15 and 16, a discharge is generated between the discharge electrode 15 and the discharge electrode 16, thereby exciting the laser gas, and as a result, the laser light passing through the discharge region 19 is amplified.

  When laser light from an external laser oscillator or laser amplifier passes through the window member 2 and enters the gas laser amplifier as incident laser light 21, it is reflected in the order of mirror 4 → mirror 5 → mirror 6 → mirror 5 → mirror 4. When the light passes through the window member 2 again, it is finally emitted as emitted laser light 22.

  The mirror 4 is a folding mirror that is installed so as to reflect the light that has passed through the discharge region and guide it again into the same discharge region. The mirror 5 is a folding mirror installed so as to reflect the light reflected by the mirror 4 and guide it again into the same discharge region. The mirror 6 is a folding mirror installed so as to reflect the light reflected by the mirror 5 and guide it again into the same discharge region. Therefore, the laser light travels from the window member 2 to the mirror 4, from the mirror 4 to the mirror 5, from the mirror 5 to the mirror 6, from the mirror 6 to the mirror 5, and from the mirror 5 to the mirror 4. The discharge region passes through the discharge path six times in the order of the optical path and the optical path from the mirror 4 to the window member 3, and is amplified six times in total. Furthermore, by increasing the number of folding mirrors, the number of passes through the discharge region is also increased, and more efficient light amplification is possible.

As with the first embodiment, the relationship of gain G = emitted light power Po / incident light power Pi ≧ exp [g ₀ × L] is established for the amplification gain. In the present embodiment, since the laser beam is configured to pass through the same discharge region six times, the distance that the laser beam passes through the discharge region is six times that in the case where the laser beam passes once. For example, when 10 W of incident laser light is amplified and 1 kW of outgoing laser light is extracted under an excitation condition of g ₀ × L = 1.2, the gain G is 100, and exp [g ₀ × L ] = 3.3 is exceeded.

  In addition, as described above, the mirrors 4, 5 and 6 whose optical surfaces are flat are installed so as to have an angle shifted by about 1 mrad from the parallel, thereby providing an effect of suppressing parasitic oscillation with a simple configuration. Yes.

  If any two of the mirrors 4, 5, and 6 are installed in parallel to each other, these parallel mirrors become resonators, and the spontaneously emitted light generated in the discharge region is used as seed light. As a result, parasitic oscillation occurs. When parasitic oscillation occurs, excitation energy is consumed even outside the original oscillation region, so that the efficiency of the laser amplifier is reduced.

  As a countermeasure, in the present embodiment, as described above, the mirrors 4 and 5 are installed so as to form an angle shifted by about 1 mrad from the parallel, and the mirrors 5 and 6 are installed so as to form an angle shifted by about 10 mrad from the parallel. Therefore, the diffraction loss in the optical path that makes one round trip between the mirrors 4 and 5, the optical path that makes one round trip between the mirrors 5 and 6, and the optical path that makes one round trip between the mirrors 4, 5, and 6 increases. Therefore, parasitic oscillation using the spontaneous emission light generated in the discharge region as seed light does not occur, and parasitic oscillation can be suppressed with a simple configuration.

  Further, the incident laser beam 21 is inclined at an angle of, for example, about 10 mrad with respect to the normal of the optical surface of the mirror 6 so that the optical axis of the incident laser beam 21 and the optical axis of the emitted laser beam 22 are not coaxial. By making the light incident, return light to the oscillator can be suppressed with a simple configuration.

  In the present embodiment, the configuration in which the incident laser beam 21 and the emitted laser beam 22 pass through one window member 2 is shown. However, the window member through which the incident laser beam 21 passes and the window through which the emitted laser beam 22 passes. Even if the member is provided separately, the same effect can be obtained.

  In the first to third embodiments, an example in which a pair of discharge electrodes 15 and 16 are arranged is shown, but the same effect can be obtained even in a configuration in which a plurality of pairs of discharge electrodes are arranged along the optical path. Play.

  In the first to third embodiments, the discharge electrodes 15 and 16 are exemplified by using electrodes metallized on the ceramic plates 11 and 12, but the discharge electrodes 15 and 16 are attached to the housing 1 by other methods. Even if fixed, the same effect can be obtained.

In the first to third embodiments, CO ₂ is used as the laser medium. However, the same effect can be obtained even with another laser medium such as an excimer laser.

  In the first to third embodiments, an example in which laser gas is excited using AC discharge is shown, but the same effect can be obtained by using other excitation methods such as discharge excitation by DC voltage and excitation by light. .

Embodiment 4 FIG.
FIG. 5 is a perspective view showing Embodiment 4 of the present invention. Here, the optical axis adjustment method of the gas laser amplifier according to the present invention will be described. Hereinafter, the gas laser amplifying apparatus according to the first embodiment will be described as an example, but the present invention can be similarly applied to the gas laser amplifying apparatus according to the second and third embodiments.

  A damper 42 is installed as a laser absorption mechanism on the outside of the housing 1 so as to intersect with the optical axis of the incident laser light, and on the other hand, for example, a thermopile detector or the like so as to intersect with the optical axis of the emitted laser light. The power detector 41 is installed.

  In such a configuration, when the damper 42 and the power detector 41 are removed and the optical axis is adjusted so that the relative angle of the mirrors 4 and 5 is about 1 mrad, the same gas laser amplifying apparatus as in the first embodiment is obtained.

  First, by installing an auxiliary mirror (not shown) or the like on the optical axis of the incident laser light, guide light (for example, helium neon laser light) from an external light source is introduced along the optical axis of the incident laser light. . At this time, the optical axis of the guide light is adjusted so that the guide light passes through the center of the window member 2 and hits the center of the optical surface of the mirror 4.

  Next, the installation angle of the mirror 4 is adjusted so that the guide light reflected by the mirror 4 strikes the center of the optical surface of the mirror 5. Subsequently, the installation angle of the mirror 5 is adjusted so that the guide light reflected by the mirror 5 passes through the center of the window member 3. Thereafter, the auxiliary mirror is removed and the introduction of the guide light is stopped.

  Next, an AC voltage is applied to the discharge electrodes 15 and 16, and the laser gas is excited in a discharge region determined by the discharge electrodes 15 and 16. Here, if the mirrors 4 and 5 form an angle θa that is extremely close to each other in parallel (for example, an angle smaller than 1 mrad order), the parasitic oscillation light 23 is generated between the mirrors 4 and 5. Part of the parasitic oscillation light 23 is diffracted by the mirror 5 to become diffracted light 24, passes through the window member 3, reaches the power detector 41, and further diffracted by the mirror 4 to become diffracted light 25. 3 to reach the damper 41.

  On the other hand, when the relative angle of the mirrors 4 and 5 is larger than the angle θa, parasitic oscillation does not occur and the power detector 41 does not detect parasitic oscillation light. In this case, by finely adjusting the installation angle of the mirror 4 and / or the mirror 5, the optical axes of the mirrors 4 and 5 are adjusted so that the relative angle of the mirrors 4 and 5 is equal to or smaller than the angle θa, and parasitic oscillation occurs. Alignment state to be performed. At this time, by setting the parasitic oscillation power detected by the power detector 41 to be maximum, the mirrors 4 and 5 can be adjusted to be completely parallel to each other.

  Next, when the installation angle of the mirror 4 and / or the mirror 5 is intentionally shifted from the maximum power state and the relative angle of the mirrors 4 and 5 is set to about 1 mrad, for example, the parasitic oscillation power rapidly decreases. . At this time, if the parasitic oscillation power is set to be minimum, the parasitic oscillation can be surely prevented.

  FIG. 6 is a graph showing the relationship between mirror parallelism and parasitic oscillation. The vertical axis represents the parasitic oscillation power (linear, arbitrary unit) detected by the power detector 41, and the horizontal axis represents the relative angle (mrad) of the mirrors 4 and 5. Here, the alignment state in which the parasitic oscillation power is maximized is defined as the origin (0 mrad). From this graph, it can be seen that if the relative angle of the mirrors 4 and 5 is set to about 1 mrad or more, the parasitic oscillation power is minimized and the parasitic oscillation is suppressed.

  By such a method, the optical axis of the gas laser amplifying apparatus can be adjusted so that parasitic oscillation can be suppressed with a simple procedure.

Embodiment 5 FIG.
FIG. 7 is a perspective view showing Embodiment 5 of the present invention. Here, the optical axis adjustment method of the gas laser amplifier according to the present invention will be described. Hereinafter, the gas laser amplifying apparatus according to the first embodiment will be described as an example, but the present invention can be similarly applied to the gas laser amplifying apparatus according to the second and third embodiments.

  In the housing 1, two apertures 31 and 32 are installed in parallel with each other at a predetermined interval, for example, 1 m along the optical path of the laser beam. The aperture 31 has two openings 33 and 34, and the aperture 32 also has two openings 35 and 36. These openings 33 to 36 have a function of mechanically limiting the space through which the laser light passes, and the number of openings increases as the number of optical paths in the housing 1 increases.

  A light source 51 that generates guide light (for example, helium neon laser light) 28 is installed outside the housing 1.

  FIG. 9 is a perspective view showing an example of the shape of the apertures 31 and 32. The aperture 31 and the aperture 32 have the same shape except for the position of the opening. The centers of the openings 33 and 34 of the aperture 31 are provided on the axis of symmetry of the aperture 31. On the other hand, the position of the opening 36 with respect to the aperture 32 is the same as the position of the opening 34 with respect to the aperture 31, but the position of the opening 35 with respect to the aperture 32 is, for example, 2 mm to the right of the position of the opening 35 with respect to the aperture 31 (FIG. 7). In a direction opposite to the A direction).

  FIG. 8 is a side view of the relative positions of the openings 33 and 34 of the aperture 31, the openings 35 and 36 of the aperture 32, the mirrors 4 and 5, and the window members 2 and 3, as viewed from the direction A in FIG. 7. The center of the opening 35 with respect to the aperture 31 is located 2 mm before the paper surface of FIG. Therefore, the first straight line connecting the center of the opening 33 and the center of the opening 35 is a twisted position with respect to the second straight line connecting the center of the opening 34 and the center of the opening 36. At this time, the twist angle corresponds to 2 mm / 1 m = 2 mrad.

  Next, guide light 28 is introduced along the optical axis of each mirror. When the installation angle of the two mirrors 4 and 5 is adjusted so that the guide light 28 passes through the center of the opening 34, the center of the opening 36, the center of the opening 33, and the center of the opening 35, the relative angle of the mirrors 4 and 5 (Mrad) is set to about 1 mrad.

  By such a method, the optical axis of the gas laser amplifying apparatus can be adjusted so that parasitic oscillation can be suppressed with a simple procedure.

1 housing, 2, 3 window member, 4, 5, 6 mirror,
11, 12 ceramic plate, 15, 16 discharge electrode, 19 discharge area,
21 incident laser light, 22 outgoing laser light, 23 parasitic oscillation light,
24, 25 diffracted light, 28 guide light, 31, 32 aperture,
33, 34, 35, 36 opening, 41 power detector, 42 damper,
51 Light source.

Claims (5)

A housing for enclosing the laser gas;
A discharge electrode provided in the housing for exciting the laser gas;
At least two mirrors provided in the housing for reflecting the laser light amplified by the laser gas;
A window member that is provided in the housing and allows the passage of laser light between the inside and outside of the housing;
The first mirror is a folding mirror that is disposed so as to reflect light that has passed through a discharge region determined by a certain pair of discharge electrodes of the discharge electrodes and to guide the light again into the discharge region;
The second mirror is a folding mirror installed so as to reflect the light reflected by the first mirror and guide it again into the discharge region,
The gas laser amplifying apparatus, wherein the first and second mirrors are installed non-parallel to each other. A housing for enclosing the laser gas;
A discharge electrode provided in the housing for exciting the laser gas;
At least one mirror provided in the housing for reflecting the laser light amplified by the laser gas;
A window member that is provided in the housing and allows the passage of laser light between the inside and outside of the housing;
The first mirror is a folding mirror that is disposed so as to reflect light that has passed through a discharge region determined by a certain pair of discharge electrodes of the discharge electrodes and to guide the light again into the discharge region;
A gas laser amplifying apparatus, wherein an optical axis of laser light incident on a first mirror and an optical axis of laser light emitted from the first mirror are not coaxial with each other. A housing for enclosing the laser gas;
A discharge electrode provided in the housing for exciting the laser gas;
At least three mirrors provided in the housing for reflecting the laser light amplified by the laser gas;
A window member that is provided in the housing and allows the passage of laser light between the inside and outside of the housing;
The first mirror is a folding mirror that is disposed so as to reflect light that has passed through a discharge region determined by a certain pair of discharge electrodes of the discharge electrodes and to guide the light again into the discharge region;
The second mirror is a folding mirror installed so as to reflect the light reflected by the first mirror and guide it again into the discharge region,
The third mirror is a folding mirror that is installed so as to reflect the light reflected by the second mirror and guide it back into the discharge region.
The gas laser amplifier according to claim 1, wherein the first, second and third mirrors are installed non-parallel to each other. A housing for enclosing the laser gas;
A discharge electrode provided in the housing for exciting the laser gas;
At least one mirror provided in the housing for reflecting the laser light amplified by the laser gas;
An optical axis adjustment method for a gas laser amplifying apparatus, which is provided in a housing and includes a window member for allowing passage of laser light between the inside and outside of the housing,
Detecting the power of parasitic oscillation generated between the mirrors in a state where the laser gas is excited;
Adjusting the installation angle of each mirror so that the detected parasitic oscillation power is maximized;
A method of adjusting the optical axis of the gas laser amplifying apparatus, comprising: shifting an installation angle of at least one mirror so that the detected parasitic oscillation power is minimized. A housing for enclosing the laser gas;
A discharge electrode provided in the housing for exciting the laser gas;
At least one mirror provided in the housing for reflecting the laser light amplified by the laser gas;
An optical axis adjustment method for a gas laser amplifying apparatus, which is provided in a housing and includes a window member for allowing passage of laser light between the inside and outside of the housing,
A first aperture having two openings and a second aperture having two openings are arranged at predetermined intervals along the optical path of the laser beam, and one opening center of the first aperture and one opening center of the second aperture Adjusting the first straight line connecting the second aperture center of the first aperture and the second straight line connecting the other aperture center of the second aperture to a twisted position;
Introducing guide light along the optical axis of each mirror;
Adjusting the installation angle of each mirror so that the introduced guide light can pass through all the openings, and a method for adjusting the optical axis of the gas laser amplifying apparatus.