JPS6214487A - Laser apparatus - Google Patents

Abstract

PURPOSE:To obtain a stable laser light with a single mode wavelength, by composing a metal vapor laser oscillator of a first metal vapor laser oscillator having a small diameter and small output for exciting a dye laser oscillator and of a second metal vapor laser oscillator for exciting a dye laser amplifier. CONSTITUTION:A laser unit comprises a metal laser oscillator 3a having a small diameter and small output, a metal vapor laser oscillator 3b having a large diameter and large output, a laser vapor laser amplifier 4 having the same diameter with and connected in series to the oscillator 3b, an optical system distributor 7, a dye laser oscillator 5, three-dye laser amplifiers 6a, 6b and 6c connected in series and trigger electronic circuits 15a, 15b and 15c for exciting the metal vapor laser oscillators and the vapor metal vapor. According to this construction, the laser oscillator 3a is allowed to output stable laser light having a small spectral width and excellent coherence. Consequently, the dye laser oscillator 5 excited by this laser oscillator 3a is also allowed to output laser light having a stable output.

Description

Detailed Description of the Invention [Technical Field of the Invention] The present invention provides a laser*a suitable for isotope separation of uranium, etc.
Regarding.

[Technical background of the invention and its problems] For example, as a method for separating isotopes such as uranium-235 and uranium-238, a specific method is used to separate isotopes such as uranium-235 and uranium-238. A method of separating isotopes has been used, and in recent years this method has attracted attention as a promising method for producing enriched uranium, which is used as fuel for nuclear reactors.

In this method, a group of atoms or molecules containing two or more types of isotopes is irradiated with laser light whose wavelength is precisely adjusted so as to selectively excite only the atoms of the target isotopes. This is a method of exciting and separating isotopes, and a laser device as shown in FIG. 2 is generally used.

This device consists of a laser device 1 for obtaining laser light that selectively excites and ionizes a target isotope, and an isotope that separates and recovers the isotope excited by the laser light irradiation and turned into ion. The body separation and recovery device f2 constitutes its main portion.

The laser equipment Ff1 includes a metal vapor laser oscillator 3.2 metal vapor laser amplifiers 4a and 4b, a dye laser oscillator 5,
Dye laser amplifiers 6a, 6b, optical system distributor 7 and metal vapor laser oscillator 3, metal vapor laser amplifiers 4a, 4
It consists of a power source (not shown) %i for exciting b.

The isotope separation and recovery device 2 also includes a vaporizer 8 for collecting atomic vapor, a separation isotope recovery device 9 having a negatively charged electrode plate, and a vapor recovery trap 10 for recovering the remaining original vapor. is housed in the isotope separation cell 11.

In the laser device configured in this way, the metal vapor laser has a 2! i3, a fully refracting vapor laser amplifier 4a,
The high-power metal vapor shear light 12 multi-stage amplified by 4b is distributed by an optical system distributor 7 to excite the dye laser oscillator 5 and dye laser amplifiers 6a and 6b, and select isotopes to be separated. The excitation dye laser light that excites the isotope and the ionization dye laser light 13 that ionizes the excited isotope are amplified and output.

When such a dye laser beam 13 is irradiated to the vapor of atoms or molecules vaporized by the vaporizer 8 in the isotope separation cell 11, only the target isotope in this vapor is excited. The isotope is then separated and ionized, adheres to the negative electrode plate of the separation isotope recovery device 9, and is separated from other neutral atoms or neutral molecules and recovered. On the other hand, neutral atoms or neutral molecules are not attracted to the negative electrode device of the separated isotope collector 9, but pass between the negative electrode plates and are collected in the vapor recovery trap 10 and removed.

By the way, in this isotope separation method using a laser device, the difference in the absorption spectra of isotopes is very small, so the excitation laser light of the laser device is a beam with a precisely tuned wavelength and a narrow spectral width. There is a need,
Furthermore, high output is required to increase separation efficiency.

Therefore, as the laser vRW1 used for isotope separation, it is desirable that the dye laser oscillator 5 has ll'I-mode oscillation and that can provide stable high output without temporal or wavelength drift.

However, in the conventional laser device 1 described above, the metal vapor laser oscillator 3 and the metal vapor laser amplifiers 4a and 4b are arranged in series to increase the output of the total refractive vapor laser beam 12, which is then transmitted through the optical system distributor 7. Since it is used for excitation of the dye laser oscillator 5 and the dye Rade amplifiers 6a and 6b, there is a problem that although a high output can be obtained, it is unstable and there is also a large variation in wavelength.

In other words, in conventional laser devices, the multi-stage amplification and high output metal vapor laser beam 12 has reduced coherence, expanded spectrum width, and large temporal fluctuations in output. The dye laser beam excited by the laser beam inevitably has a reduced coherence, a broadened spectrum width, and an unstable emitted output.

[Object of the Invention] The present invention was made to solve these conventional difficulties, and it is possible to obtain a stable high-output laser beam with a single mode wavelength and no temporal output drift or wavelength drift. The object of the present invention is to provide a laser device that can improve the efficiency of isotope separation.

[Summary of the Invention] In other words, the laser device of the present invention includes a dye laser oscillator that outputs laser light that selectively excites isotopes to be separated, and a dye that amplifies the laser light output from the dye laser oscillator. A laser amplifier, a metal vapor laser oscillator that outputs a metal vapor laser beam that excites these dye laser oscillators and the dye laser amplifier, and a metal vapor laser amplifier that amplifies the total refraction vapor laser beam output from the metal vapor laser oscillator. and an optical system for adjusting the coupling and output of these C9 oscillators and laser amplifiers, the metal vapor laser oscillator is connected to the metal vapor laser oscillator using a small diameter, small output power that excites the dye laser oscillator. By comprising a first metal vapor laser oscillator with a large diameter and a large output that pumps the dye laser amplifier, it is possible to eliminate temporal output drift and the like at heavy mode wavelengths. This makes it possible to emit 1q of stable, high-output Rayleigh' light without wavelength drift, thereby increasing the efficiency of isotope separation.

[Embodiment 1 of the Invention] Details of the present invention will be described below with reference to embodiments shown in the drawings.

FIG. 1 shows an isotope separation device equipped with a laser device according to an embodiment of the present invention, where 1 indicates a laser device and 2 indicates an isotope separation and recovery device.

The laser device 1 of this embodiment has, for example, 1 to 2 WPi!
A metal vapor laser oscillator 3a with a small diameter and small output such as a copper vapor laser oscillator with an output of
A metal vapor Lep amplifier 4 of the same diameter arranged in series, an optical system distributor 7, a dye laser beam IFI device 5, three dye laser IJ' amplifiers 6a, 6b, 6c arranged in series, and a metal It comprises a vapor laser generator 3a, 3b, a power supply 14 for exciting the metal vapor laser amplifier 4 and tuned respective trigger electronics 15a, 15b, 15c.

The small diameter, small output metal vapor laser oscillator 3a is powered by a power source 1.
4 and trigger electronics 15a, 1-
Outputs a metal vapor laser beam 12a with a low power of about 2W,
The dye laser oscillator 5 is excited by this total refraction vapor laser beam 12a and emits a low output dye laser beam 1 of 10 WSa.
3a to oscillate.

On the J side, a large diameter, high output metal vapor laser oscillator 3b excited by the power supply 14 and the trigger electronic circuit 15b oscillates a high output metal vapor laser beam 12b. The laser amplifier 4 further amplifies the output to about 200W.

This amplified high-power metal vapor laser beam 12b is transmitted by an optical system distributor 7 to, for example, 10W, 50W, 140W,
W and excites the dye laser amplifiers 5a, ab, and 6C, respectively. As a result, dye laser emission! i device 5
The dye laser I laser beam 13a oscillated from the isotope laser beam 13a is multi-stage amplified, for example, ~1W, ~10W, 1~40W, and is amplified step by step as a high-power dye laser beam 13a for isotope separation. The device af2 is irradiated. Note that the isotope separation and recovery device 2 has the same configuration and the same functions as the isotope separation and recovery device 2 shown in FIG.
The same parts are given the same reference numerals and redundant explanations will be omitted.

In the laser device 1 configured as described above, the metal vapor laser oscillator 3a having a small diameter and a small output outputs a stable laser beam with a narrow spectrum width and excellent coherence. Therefore, the dye laser oscillator 5 excited by the metal vapor laser oscillator 3a outputs a laser beam with a narrow spectrum width, excellent coherence, and stable output, thereby increasing the separation efficiency of the isotope separation and recovery device. be able to.

[Effect of the invention 1 As explained above, according to the laser device of the present invention, it is possible to obtain stable high-output laser light with a single mode wavelength and no output drift between Vts or wavelength drift. . Therefore, if the present invention is applied to isotope separation, for example, high isotope separation efficiency can be obtained.

[Brief explanation of drawings]

Fig. 1 is an illustration of an embodiment of the laser device of the present invention;
The figure shows a conventional isotope separation laser device and isotope separation and recovery device. 1...Laser V4ff 2...Isotope separation and recovery device 3...
...Metal vapor laser oscillator 3a...Small diameter, low output gold IO vapor laser oscillator 3b...Large diameter, high output metal vapor laser oscillator 4...・Metal vapor laser amplifier 5...
...Dye laser oscillator 6...Dye laser amplifier 12...Bottom vapor laser beam 13...Dye laser light substitute Kensuke Chika, a private patent attorney (and 1 other person)

Claims (1)

[Claims] (1) a dye laser oscillator that outputs laser light that selectively excites isotopes to be separated; a dye laser amplifier that amplifies the laser light output from the dye laser oscillator;
A metal vapor laser oscillator that outputs metal vapor laser light that excites these dye laser oscillators and dye laser amplifiers, a metal vapor laser amplifier that amplifies the metal vapor laser light output from this metal vapor laser oscillator, and these lasers. In a laser device comprising an oscillator and an optical system for adjusting coupling and output of a laser amplifier, the metal vapor laser oscillator is a first metal vapor laser oscillator with a small diameter and a small output that excites the dye laser oscillator. and a large aperture for exciting the dye laser amplifier,
A laser device comprising a high-output second metal vapor laser oscillator.