JP5419770B2 - Laser oscillator - Google Patents

Description

  The present invention relates to a laser oscillator that generates an axially symmetric polarized beam.

  FIG. 3 is a block diagram showing an example of a conventional laser oscillator. This laser oscillator is proposed in the following Non-Patent Document 1, and includes an output mirror 51 including a partial reflection mirror, folding mirrors 52 and 53, and a rear mirror 54. The rear mirror 54 generates radial polarization. The reflection type diffractive optical element is used. The laser light oscillates by reciprocating between the rear mirror 54 and the output mirror 51 via the folding mirrors 52 and 53, and a part of the laser light passes through the output mirror 51 and is extracted outside the resonator as laser light LB.

  The reflection type diffractive optical element constituting the rear mirror 54 has a radial polarization reflectivity Rr and an azimuth polarization reflectivity Ra different from each other. For example, when the radially polarized laser beam LB is generated, Rr> Ra. Designed as such.

J. Phys. D: Appl. Phys. 32 (1999) 2871-2875

  In the laser oscillator shown in FIG. 3, a reflection type diffractive optical element for generating radial polarization is employed as a rear mirror at the end of the resonator. When light reciprocates in the resonator, it is reflected by the reflective diffractive optical element only once per reciprocation. For this reason, if the difference ΔR between the reflectance Rr of the radial polarization and the reflectance Ra of the azimuth polarization is small, the radial polarization may not be sufficiently selected, and the desired radial polarization may not be obtained. Further, in order to increase ΔR and increase the selectivity of the radial polarization, it is difficult to design and manufacture the reflective diffractive optical element, which may increase the manufacturing cost.

Further, in a general CO ₂ laser oscillator, a rear mirror is not a plane mirror but a mirror with a certain degree of curvature is often used. In this case, it is necessary to form a diffractive optical element having polarization selectivity on the surface of the curvature mirror, which makes it extremely difficult to manufacture.

  It is also conceivable to manufacture a diffractive optical element that selects radial polarization with a transmissive medium. However, in this case, another influence appears that the heat distribution is generated by the laser beam passing through the medium and the beam diameter varies depending on the output. The influence of such a thermal lens increases as the output of the laser beam increases.

  An object of the present invention is to provide a laser oscillator capable of generating an axially symmetric polarized beam having an excellent polarization extinction ratio.

In order to achieve the above object, a laser oscillator according to the present invention comprises:
A reciprocating optical resonator having a rear mirror and an output mirror;
A laser medium provided in the optical resonator for amplifying the light;
One or more folding mirrors for folding the optical axis of the optical resonator,
At least one of the folding mirrors is composed of a reflective diffractive optical element having different reflectances for radial polarization and azimuth polarization ,
The reflective diffractive optical element is characterized in that it is installed at a laser beam incident angle at which the reflectance of radial polarization is 0.8% or more greater than the reflectance of azimuth polarization .

  According to the present invention, by using a reflective diffractive optical element having axially symmetric polarization dependence as a folding mirror of an optical resonator, the number of times the light is reflected by the reflective diffractive optical element when reciprocating in the resonator. Is twice as large as when used as a rear mirror of an optical resonator, and the polarization selectivity by the reflective diffractive optical element can be greatly increased. As a result, an axially symmetric polarized beam having an excellent polarization extinction ratio can be generated. In addition, the reflective diffractive optical element can be easily designed and manufactured, and the cost of the entire apparatus can be reduced.

It is a block diagram which shows the laser oscillator by Embodiment 1 of this invention. FIG. 2A is a plan view showing an example of a reflective diffractive optical element, and FIG. 2B is a partial cross-sectional view along the radial direction. It is a block diagram which shows an example of the conventional laser oscillator.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a laser oscillator according to Embodiment 1 of the present invention. The laser oscillator includes an output mirror 1, folding mirrors 2 and 3, a rear mirror 4, a pair of discharge electrodes 5, and the like, and a reciprocating optical resonator is configured between the output mirror 1 and the rear mirror 4. The optical resonator is classified into a parallel plane type, a concentric type, a confocal type, a semi-confocal type, and the like according to the respective radii of curvature of the output mirror 1 and the rear mirror 4. It can also be applied to a resonator.

  The output mirror 1 is composed of a partial reflection mirror, has a function of extracting a part of the laser light amplified inside the optical resonator, and generates the laser light LB outside the resonator. The rear mirror 4 is preferably composed of a complete reflecting mirror, and has a function of reflecting the laser light amplified inside the optical resonator in the coaxial direction.

  The folding mirrors 2 and 3 are generally constituted by plane mirrors and have a function of folding the optical axis of the optical resonator, thereby ensuring a large resonator length as well as miniaturization of the device. Here, a so-called Z-type resonator using two folding mirrors 2 and 3 will be described as an example. However, a V-type resonator or L-type resonator using one folding mirror, and three or more folding mirrors are used. The present invention is also applicable to the W-type resonator used.

The discharge electrode 5 has a function of exciting the laser medium supplied into the optical resonator by discharge. Here, a laser medium flow direction 7 (perpendicular to the paper surface), a discharge direction of the discharge electrode 5, and a three-axis orthogonal laser oscillator in which the optical axes of the optical resonators are orthogonal to each other will be described as an example. The present invention is also applicable to a coaxial flow type laser oscillator and other laser oscillators. Generally, CO ₂ , CO, excimer, etc. can be used as the laser medium.

  In the present embodiment, at least one of the folding mirrors, for example, the folding mirror 3 is formed of a reflective diffractive optical element having different reflectance Rr for radial polarization and reflectance Ra for azimuth polarization.

  FIG. 2A is a plan view showing an example of a reflective diffractive optical element, and FIG. 2B is a partial cross-sectional view along the radial direction. The reflective diffractive optical element has a flat surface on a copper substrate or a silicon substrate that is formed by lathing with a lathe to form a ridge portion RG and then deposited with gold vapor deposition or a dielectric multilayer film, or on a silicon substrate. The Ti layer and the Cu layer that forms the ridge portion RG are stacked. When oscillating radial polarization predominantly, as shown in FIG. 2A, a reflective diffractive optical element having a grating structure in which a number of ridges RG are concentrically formed and satisfying Rr> Ra is used. To do. Here, it is possible to make a reflective diffractive optical element satisfying Rr <Ra by appropriately selecting the period, height, etc. of the ridge portion, and to oscillate azimuth polarized light predominantly. Here, d is the width of the ridge, h is the height of the ridge, and Λ is the period of the ridge.

  Next, the operation will be described. The optical resonator is filled with a laser gas in which a laser medium and a buffer gas are mixed. The laser gas is excited by discharge while being continuously supplied to the space between the discharge electrodes 5 along the direction 7 using a blower (not shown). The light is amplified by the excited laser gas by reciprocating the optical path of the optical resonator while being reflected by the output mirror 1, the folding mirrors 2 and 3, and the rear mirror 4. A part of the amplified laser beam is taken out through the output mirror 1 and generates a laser beam LB.

  At this time, when a reflection type diffractive optical element having a concentric grating as shown in FIG. 2 is used as the folding mirror 3, the reflectance Rr of the radial polarization exceeds the reflectance Ra of the azimuth polarization. Specifically, when the width d of the ridge portion RG of the grating of the reflective diffractive optical element is set to about the wavelength or less, the cut-off current on the upper surface of the ridge portion tends to flow in the direction along the ridge portion (circumferential direction). However, it becomes difficult to flow in the direction (radial direction) perpendicular to the ridge portion. As a result, the ridge portion has a property of reflecting (disturbing) the polarized light along the ridge portion well. Here, depending on the height of the ridge portion, a phase difference occurs between the reflection from the substrate surface and the reflection from the upper surface of the ridge portion. Therefore, by appropriately selecting the height of the ridge part, the reflected light from the ridge part can act cooperatively or destructively with the reflected light from the substrate surface, and the polarization-dependent reflectance. Can be controlled. In the case of the reflective diffractive optical element shown in FIG. 2, the azimuth-polarized reflected light can be caused to act destructively to oscillate radial polarized light predominantly. Although a concentric grating is illustrated here, the same effect can be obtained even if the center of each circle is slightly decentered rather than a complete concentric circle.

The period Λ of the ridge portion of the reflective diffractive optical element is preferably about the length of the wavelength of light, and the width d of the ridge portion is preferably set smaller than that. For example, in a CO ₂ laser, the oscillation wavelength is 10.6 μm, and the width d of the ridge portion is on the order of submicron to micron. Further, in order to improve separation of radial polarization and azimuth polarization, the height h of the ridge portion is on the order of microns, and in some cases is a value larger than the width of the ridge portion. However, producing a ridge having a width of sub-micron to micron order requires a high-precision processing technique and increases the manufacturing cost. Further, when the height h of the ridge portion is larger than the width d of the ridge portion, the processing becomes difficult and the ridge portion becomes fragile and the handling is not easy. If the width d of the ridge portion is increased and the height h is decreased in order to facilitate manufacture or handling, this results in poor separation of radial polarization and azimuth polarization.

  For example, in the reflection type diffractive optical element shown in FIG. 2, the width d of the ridge portion is 0.8 μm, the height h of the ridge portion is 0.8 μm, the period Λ of the ridge portion is 16 μm, and the mirror coat material is gold coat. In this case, the reflectance Rr of radial polarization is 98.9%, and the reflectance Ra of azimuth polarization is 96.7%.

  On the other hand, in the reflection type diffractive optical element shown in FIG. 2, the width d of the ridge portion is 1.6 μm, the height h of the ridge portion is 0.5 μm, the period Λ of the ridge portion is 16 μm, and the mirror coat material is gold coat. In this case, the reflectance Rr of radial polarization is 98.6%, and the reflectance Ra of azimuth polarization is 97.8%.

  In the former, the difference in reflectance between radial polarization and azimuth polarization is 2% or more, but the height h and width d of the ridge are on the same order, making the fabrication difficult and breaking the ridge. Easy to handle.

In the latter, the width d is 3 times or more with respect to the height h of the ridge portion, and the handling becomes easy, but the difference in reflectance between the radial polarization and the azimuth polarization is about 0.8%. This is on the same order as a 45 ° incidence gold-coated mirror used as a normal CO ₂ laser reflecting mirror, and it cannot be said that there is sufficient polarization selectivity. In order to have sufficient polarization selectivity, a reflectance difference of 1% or more is desirable. For this reason, in order to generate radial polarized light by using the reflection type diffractive optical element for the rear mirror of the resonator, the height h of the ridge portion needs to be equal to or greater than the width d of the ridge portion. This causes an increase and difficulty in handling.

Furthermore, a normal CO ₂ laser resonator uses a curvature mirror as a rear mirror, and it is very difficult to form a reflective diffractive optical element on the surface of the curvature mirror.

  In the present invention, by using a reflection type diffractive optical element whose height h of the ridge portion, which is easy to manufacture and handle, is smaller than the width d of the ridge portion, and further adopting this as a folding mirror inside the resonator, The separation of azimuth polarized light is improved, and a high-quality radial polarized beam or azimuth polarized beam can be obtained.

  As shown in FIG. 1, when a reflection type diffractive optical element is used as the folding mirror 3 inside the resonator, light is reflected twice by the reflection type diffractive optical element every time the optical resonator reciprocates once. For this reason, compared with the case where the reflective diffractive optical element is used as a rear mirror, the effect of polarization control due to the difference ΔR between the reflectance Rr of the radial polarization and the reflectance Ra of the azimuth polarization can be expected to increase by the amount reflected twice. .

  For example, when a gold-coated reflective diffractive optical element is used with d = 1.6 μm, h = 0.5 μm, and Λ = 16 μm as described above, the radial polarization reflectivity Rr = 98. The reflectance Ra of the azimuth polarization is 67.8%, and the difference ΔR = 0.8% between the two. On the other hand, in the case of two-time reflection, the reflectance Rr of radial polarization Rr = 97.2% (= 0.986 × 0.986) and the reflectance of azimuth polarization Ra = 95.6% (= 0.978 × 0.978) Thus, the difference ΔR between the two increases to 1.6%, and the polarization selectivity is significantly increased.

  Thereby, separation of radial polarization and azimuth polarization, that is, polarization extinction ratio can be further improved, and a high-quality radial polarization beam with high purity can be obtained. Furthermore, since a normal curvature mirror can be employed as a rear mirror, a laser oscillator that generates radial polarized light can be realized at a lower cost.

  Such a laser oscillator that generates a radially polarized laser beam can be used in a laser processing apparatus. When the laser beam is condensed, all the polarized light of the condensed beam becomes a p component, and efficient cutting and welding can be realized. Radially polarized laser light can also be applied to high-resolution microscopes and optical tweezers.

1 Output mirror, 2, 3 Folding mirror, 4 Rear mirror, 5 Discharge electrode,
7 Flow direction of laser medium, LB laser light, RG ridge part.

Claims (4)

A reciprocating optical resonator having a rear mirror and an output mirror;
A laser medium provided in the optical resonator for amplifying the light;
One or more folding mirrors for folding the optical axis of the optical resonator,
At least one of the folding mirrors is composed of a reflective diffractive optical element having different reflectances for radial polarization and azimuth polarization ,
The reflection type diffractive optical element is installed at a laser beam incident angle at which the reflectance of radial polarization is 0.8% or more greater than the reflectance of azimuth polarization .   2. The laser oscillator according to claim 1, wherein the reflective diffractive optical element has a concentric grating structure in which the reflectance of the radially polarized light exceeds the reflectance of the azimuth polarized light. The grating structure is a structure in which ridges having a predetermined width and a predetermined height are arranged concentrically with a predetermined period,
3. The laser oscillator according to claim 2, wherein the width of the ridge portion is larger than the height of the ridge portion.   4. The laser oscillator according to claim 3, wherein the width of the ridge portion is at least three times the height of the ridge portion.