JP4763979B2 - Pulsed light irradiation device - Google Patents

Description

  The present invention relates to a pulsed light irradiation apparatus and a pulsed light irradiation method for irradiating an irradiation target with pulsed light.

In recent years, the development of an ultrashort pulse laser light source in the femtosecond region has been advanced in the pulse laser light source. In order to apply femtosecond pulsed light generated by such a laser light source to various industrial fields, pulsed light transmission using an optical fiber has been studied from the viewpoint of simplifying the optical system or improving operability. ing. Regarding the transmission of laser light using a general optical fiber, Patent Documents 1 and 2 describe the transmission of CW laser light using a multimode fiber.
JP-A-8-167754 Japanese Patent Laid-Open No. 11-14869

  One field of application of pulsed laser light is a laser processing apparatus. As described above, in a processing apparatus using pulsed laser light such as femtosecond pulsed light, it may be necessary to irradiate a processing object with high-intensity pulsed light in order to improve processing efficiency. On the other hand, when high-intensity pulsed light is transmitted through an optical fiber, damage to the optical fiber due to spatially and temporally high-density pulsed light becomes a problem.

  That is, in short pulsed light such as femtosecond pulsed light, the peak intensity of light is very large, so that the optical fiber is damaged due to thermal damage or the like. In addition, such a pulsed light has a high intensity, so that a refractive index change occurs due to a nonlinear optical effect in a quartz material of an optical fiber used for transmission. When the refractive index change occurs in the optical fiber, the pulsed light cannot be transmitted under good transmission conditions, for example, the pulsed light undergoes extra phase modulation. Such a problem also occurs in a pulsed light irradiation apparatus other than the processing apparatus.

  The present invention has been made to solve the above problems, and it is possible to suitably irradiate an irradiation object with pulsed light such as femtosecond pulsed light using an optical transmission means such as an optical fiber. An object of the present invention is to provide a pulse light irradiation apparatus and a pulse light irradiation method.

In order to achieve such an object, a pulsed light irradiation device according to the present invention includes (1) a pulsed light source that supplies pulsed light having a predetermined wavelength, and (2) an optical transmission means that transmits the pulsed light to an irradiation object. And (3) an input-side pulsed light control unit that is installed on the input side with respect to the optical transmission unit and widens the time waveform of the pulsed light input from the pulse light source to the optical transmission unit, and (4) the optical transmission unit Output side pulse light control means for generating irradiation pulse light having a desired waveform by reducing the time waveform of the output pulse light output from the light transmission means and installed on the output side. , along with a multi-mode fiber, the input-side pulse light control means, after dispersed by the spectroscopic element input pulse light, spatially separate each spectral component on the Fourier plane by a cylindrical concave mirror Imaged in a state, the arrangement spatial light modulator on the Fourier plane with respect to the respective spectral component, after applying an independent phase modulation, as for multiplexing the spectral components by a cylindrical concave mirror and the spectral element The waveform shaper configured in the above and a spectral element for controlling the waveform of the pulsed light that broadens the time waveform and correcting the secondary phase dispersion generated in the optical transmission means for each spectral component of the pulsed light And a stretcher configured to provide phase modulation.

  The pulsed light irradiation method according to the present invention includes: (a) a pulsed light supplying step for supplying pulsed light to a light transmitting unit that transmits pulsed light having a predetermined wavelength to an irradiation target; and (b) a light transmitting unit. An input side pulse light control step for widening the time waveform of the pulsed light input to the optical transmission means on the input side of the optical transmission means, and (c) the output pulse light output from the optical transmission means on the output side of the optical transmission means And an output-side pulsed light control step for generating irradiation pulsed light having a desired waveform by shortening the time waveform.

  In the above-described pulsed light irradiation apparatus and irradiation method, optical transmission means such as an optical fiber is used for transmission of pulsed light. Thereby, pulse light can be efficiently and reliably transmitted from the pulse light source to the irradiation object. Further, pulse light control means are provided on the input side and output side of the optical transmission means, respectively. By providing the pulse light control means on the input side of the light transmission means, the light transmission means is transmitted in a state where the time waveform of the pulse light is widened and the temporal density of the light is reduced, and the light by the high intensity pulse light is transmitted. It is possible to prevent the transmission means from being damaged or the refractive index from changing. Further, by providing the pulse light control means on the output side of the light transmission means, the time waveform of the pulse light transmitted through the light transmission means in the spread state is reduced again to a desired waveform, and then the irradiation object Can be irradiated. With the above configuration, it is possible to suitably irradiate the irradiation target with pulsed light such as femtosecond pulsed light using an optical transmission means such as an optical fiber.

  Here, the pulsed light source is preferably a pulsed laser light source that emits pulsed laser light having a pulse width of 1 ps or less as pulsed light. The pulsed light irradiation apparatus and irradiation method with the above configuration are particularly effective for transmission and irradiation of such short pulse width and temporally high-density pulsed light. Further, the optical transmission means for transmitting the pulsed light is preferably a multimode fiber in terms of the intensity of the transmittable pulsed light.

  In the pulsed light irradiation apparatus, it is preferable that the input side pulsed light control unit and the output side pulsed light control unit control transmission conditions including dispersion compensation conditions for pulsed light transmitted through the optical transmission unit. Thereby, the final irradiation pulse light with respect to an irradiation object can be made into the pulse light of a suitable characteristic.

  The pulsed light irradiation device preferably includes an input optical system that inputs the pulsed light emitted from the pulsed light source to the optical transmission unit under input conditions for transmission in a predetermined propagation mode. By providing such an input optical system, it becomes possible to suitably transmit pulsed light using optical transmission means such as a multimode fiber. Further, on the output side of the optical transmission means, the optical system may be configured so that the output pulse light output from the optical transmission means is spatially expanded and incident on the output-side pulse light control means. In this case, it is possible to prevent the output side pulse light control means from being damaged by the pulse light.

  According to the pulsed light irradiation apparatus and the irradiation method of the present invention, optical transmission means such as an optical fiber is used for transmission of pulsed light, and pulsed light control means are installed on the input side and output side of the optical transmission means, respectively. By adopting a configuration in which the optical transmission means is transmitted in a state where the time waveform of light is widened, pulsed light such as femtosecond pulsed light is suitably irradiated to the irradiation object using optical transmission means such as an optical fiber. Is possible.

  Hereinafter, preferred embodiments of a pulsed light irradiation apparatus and a pulsed light irradiation method according to the present invention will be described in detail with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted. Further, the dimensional ratios in the drawings do not necessarily match those described.

  FIG. 1 is a block diagram schematically showing a configuration of a first embodiment of a pulsed light irradiation device according to the present invention. The pulsed light irradiation device 1A is a device that irradiates an irradiation target with pulsed light after transmitting pulsed light such as femtosecond pulsed light using optical transmission means such as an optical fiber. 1 A of pulsed light irradiation apparatuses by this embodiment are provided with the pulsed laser light source 10, the multimode fiber 15, the input optical system 20, the input side pulsed light control part 30, and the output side pulsed light control part 40. . Moreover, in FIG. 1, the irradiation target object of the irradiation pulse light output from this irradiation apparatus 1A is typically shown with the code | symbol S. In FIG.

  The pulsed laser light source 10 supplies a pulsed light having a predetermined wavelength (pulsed light having a spectral component in a predetermined wavelength band) that is a source of the pulsed light irradiated to the irradiation target S using the present irradiation apparatus 1A. It is. In addition, as an optical transmission means for transmitting the pulsed light emitted from the pulsed light source 10 to the irradiation object S, a multimode fiber 15 that is an optical fiber is arranged along a predetermined transmission path.

  An input optical system 20 is provided between the pulse light source 10 and the multimode fiber 15. The input optical system 20 is an optical system that inputs pulsed light emitted from the pulsed light source 10 to the multimode fiber 15 from the input end 15a under predetermined input conditions. Further, the optical element constituting the input optical system 20 and the predetermined portion on the input end 15a side of the multimode fiber 15 are preferably positioned in a state where they are positioned as shown in FIG. Control mechanism) 20a is integrally held.

  The input optical system 20 is a single-mode pulse in which the pulsed light input condition to the multimode fiber 15 is such that the multimode fiber 15 can transmit pulsed light in a predetermined propagation mode, and preferably only the fundamental mode propagates. It is configured to satisfy the conditions that allow optical transmission. Further, an output optical system is provided on the output end 15b side of the multimode fiber 15 as necessary.

  Further, in the present irradiation apparatus 1A, pulse light control units 30 and 40 are respectively installed on the input side and the output side of the multimode fiber 15 that is an optical transmission means. These pulsed light control units 30 and 40 are control means for controlling transmission conditions of pulsed light transmitted through the multimode fiber 15 toward the irradiation object S. Thus, by controlling the transmission conditions of the pulsed light with the pulsed light control units 30 and 40, the characteristics of the pulsed light irradiated from the irradiation apparatus 1A to the irradiation target S can be controlled to desired characteristics. .

  In the configuration shown in FIG. 1, an input-side pulse light control unit 30 is provided between the pulse light source 10 and the input optical system 20 on the input side of the multimode fiber 15. The pulsed light control unit 30 controls the waveform of the pulsed light so as to widen the time waveform of the pulsed light input from the pulsed light source 10 to the multimode fiber 15. On the other hand, an output-side pulsed light control unit 40 is provided on the output side of the multimode fiber 15. The pulsed light control unit 40 reduces the time waveform of the output pulsed light output from the multimode fiber 15 and generates irradiation pulsed light having a desired waveform. And the irradiation pulse light produced | generated in this pulse light control part 40 is irradiated to the irradiation target object S. FIG. The configuration of the pulsed light control units 30 and 40 will be specifically described later.

  The pulse light irradiation method in the pulse light irradiation apparatus 1A shown in FIG. 1 will be schematically described. First, the pulsed light emitted from the pulsed light source 10 is supplied to the multimode fiber 15 which is an optical transmission means for transmitting pulsed light of a predetermined wavelength to the irradiation object S (pulsed light supply step). The pulsed light from the pulse light source 10 input to the multimode fiber 15 is expanded in time waveform by the pulsed light control unit 30 on the input side of the multimode fiber 15 (input side pulsed light control step). Thereby, the pulsed light from the pulsed light source 10 is reduced in its temporal light density (corresponding to the spatial light density along the transmission direction of the pulsed light in the multimode fiber 15). The signal is input to the multimode fiber 15 via the input optical system 20.

  The pulsed light input from the input end 15a to the multimode fiber 15 through the input optical system 20 is transmitted through the fiber 15 and then output from the output end 15b. The time waveform of the pulsed light output from the multimode fiber 15 is shortened by the output-side pulsed light control unit 40, and the waveform is controlled to be a desired waveform (output-side pulsed light control step). ). Thereby, irradiation pulse light having a waveform corresponding to a suitable irradiation condition of the pulse light with respect to the irradiation target S is generated, and the irradiation target light S is irradiated with the irradiation pulse light.

  The effects of the pulsed light irradiation apparatus 1A and the pulsed light irradiation method according to the above embodiment will be described.

  In the pulsed light irradiation apparatus 1A and the pulsed light irradiation method shown in FIG. 1, a multimode fiber 15 that is an optical fiber is used for transmission of pulsed light. Thus, by transmitting pulsed light using an optical fiber, pulsed light can be efficiently and reliably transmitted from the pulse light source 10 to the irradiation object S. Further, in such a configuration using an optical transmission means such as an optical fiber, it is not necessary to install a complicated transmission optical system of pulse light between the pulse light source 10 such as a pulse laser light source and the irradiation object S, and irradiation is performed. The configuration of the apparatus 1A can be simplified and downsized.

  Further, pulse light control units 30 and 40 are provided on the input side and the output side of the multimode fiber 15 as the optical transmission means, respectively. By providing the pulsed light control unit 30 on the input side of the multimode fiber 15, the multimode fiber 15 is transmitted with the temporal waveform of the pulsed light emitted from the pulsed light source 10 widened to reduce the temporal density of the light. Can be made. In addition, by providing the pulsed light control unit 40 on the output side of the multimode fiber 15, the time waveform of the pulsed light transmitted through the multimode fiber 15 in the expanded state is again reduced to a desired waveform, The irradiation object S can be irradiated.

  As described above, according to the configuration in which the optical transmission means such as the multimode fiber 15 is transmitted in a state where the time waveform of the pulsed light is widened, the optical transmission means is damaged by the high-intensity pulsed light or the refractive index is changed. Can be prevented.

  That is, the peak intensity of pulse light with a short pulse width such as femtosecond pulse light becomes very large. When such pulsed light is transmitted in an optical fiber, the optical fiber may be damaged by high-density spatially and temporally pulsed light.

  In order to avoid such damage, it is preferable to adopt a configuration that avoids an increase in light density in the optical fiber and in the vicinity of both end faces on the input side and output side. Such damage to the optical fiber is particularly likely to occur at the input end and output end of the optical fiber where the refractive index changes greatly. In addition, when high-intensity pulsed light is transmitted in an optical fiber, there is a problem in that the characteristics of the pulsed light change due to the nonlinear optical effect in addition to damage to the optical fiber. In addition, regarding the light density in the transmission of pulsed light, spatial density and temporal density can be considered, but in pulsed light transmission using an optical fiber, the spatial structure of the light transmission path It is difficult to control the density.

  On the other hand, in the configuration in which the time waveform of the pulsed light is expanded on the input side of the multimode fiber 15 as described above and the multimode fiber 15 is transmitted in that state and then returned to the desired waveform on the output side, It is possible to prevent the optical transmission means from being damaged by the irradiation, and to irradiate the irradiation object S with higher intensity pulsed light. In addition, since the occurrence of the nonlinear optical effect in the optical transmission means is reduced, the stability of the irradiation pulse light transmitted through the multimode fiber 15 can be improved. Therefore, it becomes possible to suitably irradiate the irradiation object with pulsed light such as femtosecond pulsed light using an optical transmission means such as an optical fiber.

  Such a pulsed light irradiation apparatus and irradiation method can be applied to various apparatuses that irradiate an irradiation target with pulsed light. Examples of such an apparatus include a processing apparatus that irradiates a workpiece with pulse light, and a reaction apparatus that irradiates a sample with pulse light to cause a desired reaction. By applying the above configuration to such an apparatus, it becomes possible to use pulsed light having a short pulse width and high intensity.

  Here, it is preferable to use an optical fiber as the light transmission means used for transmitting the pulsed light to the irradiation object S in view of light transmission efficiency. In particular, it is preferable to use a multimode fiber as shown in the configuration of FIG. In this case, compared with the case where a single mode fiber is used, for example, pulsed light irradiation under various conditions such as transmission and irradiation of higher intensity pulsed light becomes possible. This is very useful in applying short pulse light such as femtosecond pulse light to various forms of pulsed light irradiation devices such as processing devices and expanding their application range. As the multimode fiber, either a graded index type or a step index type can be used.

  However, as this optical transmission means, a single mode fiber may be used according to the intensity of pulsed light required for irradiation. A bundle fiber in which a plurality of optical fibers are bundled may be used. Alternatively, it is possible to use other than the optical fiber. An example of such an optical transmission means is a hollow fiber.

  Various pulse light sources for supplying the pulsed light to be irradiated onto the irradiation object S may be applied depending on the application of the pulsed light irradiation device, and in particular, the pulse width is 1 ps or less. It is preferable to use a pulsed laser light source that emits laser light. The pulsed light irradiation apparatus 1A having the above-described configuration is particularly suitable for irradiation with pulsed light having a short pulse width in such a femtosecond region, for example, transmission of femtosecond pulsed light having a broadband spectral component, and irradiation to an irradiation object S. It is effective against. An example of such a pulsed laser light source is a titanium sapphire laser. Such a pulse light source may be configured to emit a single pulsed light, or may be configured to synthesize and emit a plurality of pulsed lights.

  Further, as the pulse light source, the laser light source is the primary light source, and the pulsed light that irradiates the irradiation target S with the secondary light generated by propagating the laser light supplied from the primary light source in the medium. May be used. Examples of the medium used for generating such secondary light include a photonic crystal and a nonlinear optical crystal.

  Moreover, in the said embodiment, since the pulsed light transmission to the irradiation target S using the multimode fiber 15 is performed, the input condition of the pulsed light to the multimode fiber 15 is set to a condition that enables transmission in a predetermined propagation mode. An input optical system 20 is installed. By providing such an input optical system 20, it is possible to suitably transmit short pulse light such as femtosecond pulse light using the multimode fiber 15. For example, a pulse in which only the fundamental mode propagates is obtained by matching the input axis of the pulsed light with sufficient accuracy to the optical axis of the multimode fiber 15 and inputting the pulsed light at a position near the center of the multimode fiber 15. It is also possible to realize single mode transmission of light.

  Specifically, the input conditions of the pulsed light controlled by the input optical system 20 to the multimode fiber 15 include, for example, the input position (condensing position) of the pulsed light at the input end 15a, the condensing diameter, There are numerical aperture, light intensity, propagation direction, spatial distribution, wavefront slope when inputting, or a combination thereof. However, such an input optical system 20 may be installed as necessary in consideration of the constraint condition on the characteristics of the pulsed light irradiated on the irradiation target S.

  In the pulsed light irradiation apparatus 1A having the above configuration, the input-side pulsed light control unit 30 and the output-side pulsed light control unit 40 control transmission conditions including dispersion compensation conditions for pulsed light transmitted through the multimode fiber 15. It is preferable. As described above, by performing dispersion compensation of the pulsed light using the pulsed light control units 30 and 40, the pulsed light irradiated onto the irradiation object S can be changed to pulsed light with suitable characteristics.

  In addition, in the pulsed light control units 30 and 40, an optical modulation unit that applies modulation to the pulsed light may be provided. By using such a light modulation unit, it is possible to control various pulsed light irradiations. Specifically, the modulation of the pulsed light by the light modulation unit is preferably configured to modulate at least one of the amplitude (intensity), phase, and polarization of each pulsed light wavelength. As for the configuration of the input side of the multimode fiber 15, the entire input optical system 20 and the pulsed light control unit 30 can be configured from a single optical system having both functions.

  FIG. 2 is a block diagram schematically showing the configuration of the second embodiment of the pulsed light irradiation apparatus according to the present invention. The pulsed light irradiation apparatus 1B according to the present embodiment includes an irradiation evaluation unit 50 and an irradiation control unit 55 in addition to the configuration shown in FIG.

  The irradiation evaluation unit 50 is an evaluation unit that evaluates the irradiation state of the pulsed light on the irradiation target S. Further, the evaluation result of the irradiation state in the irradiation evaluation unit 50 is input to the irradiation control unit 55. The irradiation control unit 55 is based on the evaluation result of the irradiation state of the pulsed light on the irradiation target S by the irradiation evaluation unit 50, the input optical system 20, the input side pulsed light control unit 30, and the output side pulsed light control unit 40. Is a control means for controlling at least one of the operations.

  As described above, in the configuration including the irradiation evaluation unit 50 and the irradiation control unit 55, the pulsed light irradiation can be accurately controlled in accordance with the actual irradiation state of the pulsed light on the irradiation target S. Note that various methods may be used for the specific evaluation method of the irradiation state by the irradiation evaluation unit 50. For example, one or both of the pulsed light input to the input end 15a of the multimode fiber 15 or the pulsed light transmitted through the multimode fiber 15 and output from the output end 15b is measured, and the measurement result is referred to. Thus, a configuration for evaluating the irradiation state of the pulsed light can be used. Moreover, it is good also as a structure which measures the light which pulsed light reflected and scattered by the irradiation target S, and refers the measurement result. Or it is good also as a structure which measures the change of the state of the irradiation target S by pulse light irradiation, and refers the measurement result.

  When controlling the input conditions of pulsed light to the multimode fiber 15 in the input optical system 20, it is preferable to control the incident position and incident angle of the pulsed light to the multimode fiber 15. Such control of input conditions can be realized by adding an adjustment mechanism to each optical element constituting the input optical system 20. As such an adjustment mechanism, for example, a mechanism for adjusting the three-dimensional position and inclination of the optical element may be added. Or it is good also as a structure which adjusts the position and inclination of the multimode fiber 15 instead of the input optical system 20 side.

  The specific configuration of the pulsed light irradiation apparatus according to the present invention will be further described.

  FIG. 3 is a configuration diagram illustrating an example of an input optical system used in the pulsed light irradiation device. In the present configuration example, a plano-convex lens 22 for condensing the pulsed light emitted from the pulsed light source 10 and inputting it to the multimode fiber 15 is used as an optical element constituting the input optical system 20. In FIG. 3, the illustration of the pulsed light control units 30 and 40 is omitted.

  Specifically, in FIG. 3, of the two lens surfaces of the plano-convex lens 22, the lens surface on the multimode fiber 15 side is a flat surface (flat surface) 22a, and the lens surface on the pulse light source 10 side is a convex surface 22b. Yes. Further, between the pulse light source 10 and the plano-convex lens 22, an aperture 21 through which the pulsed light from the pulse light source 10 to the multimode fiber 15 passes through the opening 21c is installed. The input optical system 20 is configured by 22.

  With such a configuration, pulsed light from the pulsed light source 10 can be input to the multimode fiber 15 under suitable input conditions. Such a plano-convex lens 22 is also useful for adjusting and setting pulse light input conditions to the multimode fiber 15 and pulse light transmission conditions in the multimode fiber 15.

  Specifically, in the method for adjusting the transmission condition of pulsed light using the plano-convex lens 22 of the input optical system 20, first, each optical element of the irradiation apparatus 1A including the pulse light source 10, the multimode fiber 15, and the plano-convex lens 22 is used. Are installed at initial positions that have a predetermined positional relationship (installation step). Subsequently, pulse light is emitted from the pulse light source 10 to the multimode fiber 15, and a plane reflection image in which a part of the pulse light is reflected by the flat surface 22a of the plano-convex lens 22, and a part of the pulse light is reflected by the convex surface 22b. The projected convex reflection image is observed (observation step).

  Then, the input condition of the pulsed light to the multimode fiber 15 is adjusted based on the observation result of the planar reflection image and the convex reflection image. Specifically, the center position of the plane reflected image from the plane 22 a of the plano-convex lens 22 and the center position of the convex reflected image from the convex surface 22 b coincide with the central axis of the pulsed light input to the multimode fiber 15. As described above, the positional relationship among the pulse light source 10, the plano-convex lens 22, and the multimode fiber 15 is adjusted. Thereby, the transmission conditions of the pulse light in the multimode fiber 15 such as the propagation mode of the transmission of the pulse light are adjusted (adjustment step).

  As described above, according to the adjustment method of adjusting the input condition of the pulsed light using the reflected image from the plano-convex lens 22, the short pulse light such as femtosecond pulsed light is irradiated with the irradiation object S using the multimode fiber 15. It is possible to adjust the input conditions and the transmission conditions such as the propagation mode in the multimode fiber 15 so that the transmission is suitably performed. However, such adjustment of the input conditions of the pulsed light may be performed as necessary according to a desired waveform or the like with the irradiation pulsed light.

  As for the method of observing the reflected image of the pulsed light from the plano-convex lens 22, it is preferable to observe the plane reflected image and the convex reflected image using the aperture 21 disposed between the pulse light source 10 and the plano-convex lens 22. According to such a configuration, it is possible to perform the adjustment of the input condition of the pulsed light to the multimode fiber 15 by the input optical system 20 including the plano-convex lens 22 by a reliable and simple method. In general, it is preferable that the planar reflection image and the convex reflection image are observed using a plate-like member disposed at a predetermined position between the pulse light source 10 and the plano-convex lens 22. Further, such a plate-like member may have a mechanism that can be removed after the adjustment of the input condition of the pulsed light and the like is completed.

  FIG. 4 is a schematic diagram showing a method for adjusting the transmission condition of pulsed light performed using the input optical system 20 including the plano-convex lens 22 shown in FIG. In FIG. 4, the aperture 21 provided with the circular opening 21c at the center position is shown as viewed from the plano-convex lens 22 side, and the reflected image observation surface 21a and the observation surface 21a are the downstream surfaces. The plane reflection image A from the plane 22a of the plano-convex lens 22 projected on the top and the convex reflection image B from the convex surface 22b projected on the observation surface 21a are illustrated. In the drawing, each of the reflected images A and B is schematically shown with diagonal lines.

  In a state where the input condition of the pulsed light to the multimode fiber 15 via the plano-convex lens 22 is suitably adjusted, both the plane reflection image A and the convex reflection image B have the aperture 21 as shown in FIG. A circular optical image centered on the position on the central axis is obtained. Of these reflection images A and B, the convex reflection image B is incident while spreading from the plano-convex lens 22 to the aperture 21 due to the shape of the convex surface 22b of the plano-convex lens 22 serving as the reflection surface. Is larger than the planar reflection image A. By using these two types of reflection images A and B and adjusting the reflection images A and B so as to form a concentric pattern on the observation surface 21a of the aperture 21, the input of pulsed light to the multimode fiber 15 is performed. Condition adjustment can be realized with a simple configuration and adjustment method of the input optical system 20. As for specific input conditions of the pulsed light to the multimode fiber 15, it is preferable to input the pulsed light at a position near the center of the multimode fiber 15.

  When the pulse light source 10 and the multimode fiber 15 are connected under the input conditions described above, transmission of pulse light in the higher-order propagation mode in the multimode fiber 15 is suppressed, and the multimode fiber 15 is used as an optical fiber. Nevertheless, it is possible to realize single-mode transmission of pulsed light in which only the fundamental mode propagates. Regarding the spatial mode of the pulsed light, it is considered preferable that the spatial mode of the pulsed light output from the multimode fiber 15 has a favorable distribution shape close to a Gaussian intensity distribution. Therefore, it is desirable to adjust the input condition of the pulsed light by the input optical system 20 in consideration of such a spatial mode.

  In addition, when the end surface of the input end 15a of the multimode fiber 15 is polished into a planar shape, in addition to the reflected image of the pulsed light from the plane 22a and the convex surface 22b of the plano-convex lens 22, the input of the multimode fiber 15 The reflected image from the end 15a may also be used for adjusting the input conditions. Thereby, the input condition can be adjusted with higher accuracy.

  Further, as a configuration of the input optical system for adjusting the input conditions in this way, generally, the input optical system 20 has a lens for inputting the pulsed light to the multimode fiber 15 while condensing the pulsed light. What is necessary is just composition. Even with such a configuration, the adjustment of the input condition of the pulsed light to the multimode fiber 15 can be realized with a simple configuration and adjustment method of the input optical system 20. The lens in this case is not limited to a plano-convex lens, and a lens having convex surfaces on both sides may be used.

  In addition, regarding the observation of the reflected image from the lens in this case, the input optical system has a plate-like member such as an aperture installed at a predetermined position between the pulse light source and the lens. The first reflected image in which a part of the pulsed light is reflected on the surface on the light emitting side (multimode fiber side), and a part of the pulsed light is reflected on the surface on the light incident side (pulse light source side) of the lens What is necessary is just to be comprised so that it can be used for observation of a 2nd reflected image.

  In the above example, it is assumed that the pulsed light supplied from the pulsed light source 10 is a substantially uniform plane wave. However, if the wavefront of the pulsed light is not uniform, the wavefront is passed through a spatial filter or the like. It is preferable to input to the multimode fiber 15 after uniformizing the optical fiber. In the above configuration, the input condition of the pulsed light to the multimode fiber 15 has been described. However, in the adjustment of the transmission condition of the pulsed light to the optical transmission means other than the multimode fiber, the configuration and transmission of the input optical system 20 described above are also included. Condition adjustment methods can be applied.

  FIG. 5 is a configuration diagram illustrating an example of an input-side and output-side pulsed light control unit used in the pulsed light irradiation device. In this configuration example, the input-side pulsed light control unit 30 includes a waveform shaper 36 and an expander 37.

  For example, the waveform shaper 36 divides the input pulsed light with a spectral element such as a diffraction grating or a prism, and modulates each spectral component (wavelength component) with a modulating element, and then combines the spectral components. Configured to do. In FIG. 5, the waveform shaper 36 includes a diffraction grating 36 a that separates the pulsed light from the pulse light source 10, a cylindrical concave mirror 36 b that forms the dispersed light, and each spectrum of the pulsed light that is incident from the concave mirror 36 b. From a spatial light modulator 36c that applies phase modulation to the component, a cylindrical concave mirror 36d that condenses the modulated light, and a diffraction grating 36e that combines the collected light into pulse light after modulation. It is configured.

  The expander 37 is configured to apply linear phase modulation to each spectral component of the pulsed light by a spectroscopic element such as a diffraction grating or a prism. In FIG. 5, the expander 37 separates the pulsed light from the waveform shaper 36 from diffraction gratings 37 b and 37 c and a total reflection mirror 37 d for applying phase modulation to each spectral component of the pulsed light. It is configured.

  In addition, a partial reflection mirror 37 a is disposed in the expander 37 between the diffraction grating 36 e of the waveform shaper 36 and the diffraction grating 37 b of the expander 37. The partial reflection mirror 37 a is used for transmitting the light input from the waveform shaper 36 to the diffraction grating 37 b and for reflecting the light from the diffraction grating 37 b and outputting it to the input optical system 20. .

  Control of the pulsed light waveform and the like using the pulsed light control unit 30 having the configuration shown in FIG. 5 will be described. First, pulse light from the pulse light source 10 input to the waveform shaper 36 is dispersed by the diffraction grating 36a, and then imaged in a state where each spectral component is spatially separated on the Fourier plane by the cylindrical concave mirror 36b. Is done. In the spatial light modulator 36c arranged on the Fourier plane, independent phase modulation is given to the spectral components of these pulsed lights. The spectral components of the modulated pulsed light are combined by the cylindrical concave mirror 36d and the diffraction grating 36e. The waveform shaper 36 mainly corrects third-order or higher-order phase dispersion that cannot be corrected by the expander 37.

  The pulse light from the waveform shaper 36 input to the expander 37 is subjected to linear phase modulation by the diffraction gratings 37b and 37c, then reflected by the total reflection mirror 37d, and again by the diffraction gratings 37c and 37b. The light is diffracted and output through the reflection mirror 37a. In the expander 37, the control of the waveform of the pulsed light that broadens the time waveform as described above and the correction for the secondary phase dispersion that occurs in the optical fiber at the subsequent stage are performed. In such a configuration, by placing the total reflection mirror 37d in a direction perpendicular to the paper surface, the position of the pulsed light is separated vertically at the input and output at the positions of the diffraction gratings 37b and 37c. The subsequent extraction of pulsed light becomes easy. In this case, for example, the reflection mirror 37a may be a total reflection mirror and may be arranged only for the output optical path of the pulsed light.

  On the other hand, as the output-side pulsed light control unit 40, a dispersion medium 41 having a predetermined wavelength dispersion characteristic is used. Thus, since the output side pulse light control unit 40 is disposed near the irradiation object S, it is preferable to use a small configuration in view of convenience in handling and the like. Specifically, a glass block, a glass rod, or the like can be used as the dispersion medium 41. Alternatively, a dispersion optical system such as a diffraction grating pair may be used.

  In addition to the configuration example shown in FIG. 5, various configurations may be used for these pulsed light control units 30 and 40. For example, in the input side pulsed light control unit 30 in FIG. 5, the installation order of the waveform shaper 36 and the expander 37 may be reversed, or only one of them may be installed. Further, as the optical modulator used in the pulsed light control unit 30, a phase modulation element such as a spatial light modulator capable of controlling the phase pattern or an optical modulator having a fixed phase pattern can be used. Alternatively, intensity modulation can be applied to each spectral component of the pulsed light by arranging polarizers before and after the spatial light modulator.

  In FIG. 5, the dispersion medium 41 is used as the output-side pulsed light control unit 40, but other optical elements may be used, or there is no problem with spatial restrictions even in the vicinity of the irradiation target S. In this case, an optical system as shown for the input side pulsed light control unit 30 can be used. Further, in order to reduce the spatial light density on the output side of the multimode fiber 15, the pulsed light is once spatially expanded when it is output from the output end 15b of the multimode fiber 15, and output side pulse light control is performed. An output optical system configured to condense spatially using a lens or the like while compressing pulsed light temporally in the unit 40 may be installed.

  Further, a dispersion medium or the like may be used in the input side pulse light control unit 30. Further, considering the degree of freedom in changing the irradiation condition of the pulsed light on the irradiation target S, it is preferable that at least one of the pulsed light control units 30 and 40 be configured to be controllable or replaceable. In addition, as the pulsed light control units 30 and 40, for example, elements such as an E / O modulator and an A / O modulator that can be subjected to different phase modulation depending on time may be used.

  The control of the pulse light transmission conditions, the waveform of the irradiation pulse light, and the like by the input side pulse light control unit 30 and the output side pulse light control unit 40 will be further described.

  First, control of dispersion compensation conditions for pulsed light transmitted through the multimode fiber 15 by the input-side pulsed light control unit 30 and the output-side pulsed light control unit 40 will be described. FIG. 6 is a graph showing the phase dispersion characteristics of the multimode fiber 15, where the horizontal axis indicates the wavelength (nm) and the vertical axis indicates the phase dispersion (rad). The phase dispersion characteristic shown in FIG. 6 shows the calculated chromatic dispersion in a quartz transmission line having a length of 100 m, considering the multimode fiber 15 as a synthetic quartz block.

  FIG. 7 shows a phase dispersion characteristic for canceling the dispersion characteristic of the multimode fiber 15. When controlling the dispersion compensation conditions of the pulsed light in the pulsed light control units 30 and 40, it is preferable to set the phase dispersion characteristic as a whole of the pulsed light control units 30 and 40 to the characteristic shown in FIG. Thereby, the phase dispersion of the multimode fiber 15 shown in FIG. 6 and the phase dispersion shown in FIG. 7 cancel each other, and the irradiation pulse light having a suitable characteristic is obtained in which the chromatic dispersion generated in the multimode fiber 15 is compensated. It is done.

  Such dispersion compensation is realized as a whole by combining both of the pulsed light control units 30 and 40 after satisfying the above-mentioned conditions in which the pulsed light is transmitted in a spread state in the multimode fiber 15. Just do it. In this case, since the contribution of chromatic dispersion can be added linearly, the pulse light control units 30 and 40 positioned on the input side and the output side with respect to the multimode fiber 15 are shown in FIG. What is necessary is just to divide and give the chromatic dispersion amount divided | segmented by arbitrary ratios.

  As shown in FIG. 5, in the configuration using the dispersion medium 41 as the output-side pulsed light control unit 40, the physical size of the dispersion medium 41 is smaller when considering the convenience of handling as described above. preferable. In this case, it is preferable to set the distribution of the chromatic dispersion amount in the pulse light control units 30 and 40 in consideration of the size of the dispersion medium 41.

  For example, when pulse light with a pulse width of 100 fs spreads to 300 ps by pulse light transmission through a 100 m optical fiber, the spread of the pulse width is about 3000 times. Here, assuming that the amount of spread of the pulsed light is approximately proportional to the length of the dispersion medium, it is converted to 30 times / m. At this time, for example, if a 1 m long dispersion medium is installed on the output side, the pulse width of the pulsed light at the output end of the optical fiber is 30 times 100 fs, that is, 3 ps. In such a configuration, the damage threshold at the output end of the optical fiber can be increased by 30 times. In general, the distribution of the dispersion amount may be arbitrarily set according to the use condition of the pulsed light irradiation device, the specific configuration of the pulsed light control units 30 and 40, and the like.

  Even when dispersion compensation is performed in these pulsed light control units 30 and 40, it is not always necessary to cancel the chromatic dispersion generated in the multimode fiber 15. That is, the waveform of the irradiation pulse light generated by the output-side pulse light control unit 40 does not have to be the same as the waveform of the pulse light supplied from the pulse light source 10, and the specific type and irradiation of the irradiation object S A suitable waveform of the irradiation pulse light may be selected according to the purpose.

  In this case, examples of parameters of the waveform of the irradiation pulse light controlled by the pulse light control units 30 and 40 include the shape of the time waveform of the pulse light itself, the pulse width, and the pulse intensity. For example, the irradiation pulse light may be configured to be pulse light having a wider pulse width than the pulse light supplied from the pulse light source 10. Or it is good also as irradiation pulse light of the waveform which has a some pulse light component according to the irradiation conditions of the suitable pulse light to the irradiation target S, etc. Pulse light having such a waveform is useful for a processing apparatus using a pulse train type, a double pulse, or the like.

  FIG. 8 is a graph showing an example of a time waveform of the pulsed light irradiated to the irradiation object. Of the three graphs shown in FIG. 8, graph (a) shows a time waveform when a single pulse is used, and graphs (b) and (c) show time waveforms when a multi-pulse is used. In these graphs, the horizontal axis represents time (fs), and the vertical axis represents intensity.

The above-described pulsed light irradiation apparatus is applied to a processing apparatus, and the processing target is irradiated with pulsed light having a time waveform shown in each graph of FIG. FIG. 9 is a schematic diagram illustrating a processing state of the processing object by the pulsed light having the time waveform illustrated in FIG. In this figure, machined portion P _A machining situation with pulsed light shown in the graph above (a), machining area P _B is machining status by pulsed light shown in the graph (b), the processing portion P _C the graph (c The processing situation by the pulsed light shown in FIG.

  Here, processing is performed by pulsed light irradiation using a transparent acrylic material as an object to be processed, and FIG. 9 is a side view of the processing state of the acrylic material irradiated with pulsed laser light from above. Further, graphs (a) to (c) shown in FIG. 8 show the waveform of the pulsed light at the processing point.

In the processing result of the acrylic material shown in FIG. 9, as shown schematically by the region S surrounded by the broken line, relative machining area P _A in the case of using a pulse light of a single pulse, the surrounding region S Distortion occurs. In contrast, as shown in machining area P _B and P _C, by using a pulsed light of the multi-pulse, the occurrence of distortion in the machining area near is improved.

  As described above, the waveform of the pulsed light applied to the irradiation target differs depending on the purpose of the pulsed light irradiation, the material of the irradiation target, and the like. Therefore, what is necessary is just to set suitably about the waveform of the irradiation pulse light produced | generated in the output side pulse light control part 40 and irradiated to the irradiation target object S according to specific irradiation conditions. In addition, when it is preferable to use multi-pulse pulse light as the irradiation pulse light, the pulse light supplied from the pulse laser light source is generally a single pulse, and therefore, on the path along which the pulse light propagates. What is necessary is just to make the waveform of a multipulse as final irradiation pulse light by the effect | action of each optical element, such as a certain multimode fiber 15 and the pulse light control parts 30 and 40. FIG.

  The pulsed light irradiation apparatus and the pulsed light irradiation method according to the present invention are not limited to the above-described embodiments and examples, and various modifications are possible.

  For example, as shown in FIG. 2, in the configuration in which the pulsed light irradiation is controlled using the irradiation evaluation unit 50 and the irradiation control unit 55, the pulsed light can be controlled while observing the irradiation target S or the like in real time. However, the present invention is not limited to this. That is, when the control conditions for pulsed light that gives effective irradiation conditions to a predetermined irradiation object are determined, the above-mentioned control system is turned off, the irradiation conditions are fixed, and the irradiation object is irradiated with pulsed light. It is good also as a structure to perform.

  Further, as described above, in the configuration shown in FIG. 5, in order to reduce the spatial light density on the output side of the multimode fiber 15, a pulse is generated when it is output from the output end 15 b of the multimode fiber 15. An output optical system having a configuration in which the light is spatially spread and the pulsed light is temporally compressed by the output-side pulsed light control unit 40 and is condensed spatially using a lens or the like may be installed.

  FIG. 10 is a configuration diagram illustrating a modified example of the pulsed light irradiation device illustrated in FIG. 5. In this configuration, the light propagated through the multimode fiber 15 and temporarily output is spatially expanded. Then, after the output pulse light that has been spread is converted into substantially parallel light by an optical system having an NA substantially equal to the NA of the multimode fiber 15, for example, a lens, a dispersion medium 41 that is the output side pulse light control unit 40, for example, Incident on the glass.

  By making the dispersion of the pulsed light at the output of the multimode fiber 15 opposite to the dispersion received when propagating through the dispersion medium 41 such as the glass block, the pulsed light gradually propagates through the glass block. It will be compressed. At this point of time, it is in a state where it is not easily damaged by light when entering the glass block due to the spatial expansion. The pulsed light output from the glass block of the dispersion medium 41 is spatially reduced by the subsequent lens, and is further compressed in time by the dispersion of the lens, and is irradiated onto the irradiation object S. In general, on the output side of an optical transmission means such as a multimode fiber, an optical system is configured so that the output pulse light output from the optical transmission means is spatially expanded and incident on the output-side pulse light control means. Preferably it is. In this case, it is possible to prevent the output side pulse light control means from being damaged by the pulse light.

  Note that the optical system on the output side of the multimode fiber 15 uses a lens in FIG. 10, but is not limited to this. For example, a concave mirror may be used. When dispersion compensation can be realized only by the amount of dispersion by the lens, the dispersion medium 41 may be omitted by causing the lens to function as the output-side pulsed light control unit 40. Alternatively, an optical system such as that shown for the input-side pulsed light control unit 30 can also be used when spatial constraints do not matter even in the vicinity of the irradiation object S. Further, the dispersion medium 41 is not limited to a glass block, and a bundle fiber or a liquid sealed in a container can also be used. A tapered fiber or glass block may be used instead of the lens.

  INDUSTRIAL APPLICABILITY The present invention can be used as a pulsed light irradiation apparatus and a pulsed light irradiation method capable of suitably irradiating an irradiation target with pulsed light such as femtosecond pulsed light using an optical transmission means such as an optical fiber. is there.

It is a block diagram which shows the structure of 1st Embodiment of a pulsed light irradiation apparatus. It is a block diagram which shows the structure of 2nd Embodiment of a pulsed light irradiation apparatus. It is a block diagram which shows an example of the input optical system used for an irradiation apparatus. It is a schematic diagram shown about the adjustment method of the transmission condition of pulsed light using the input optical system shown in FIG. It is a block diagram which shows an example of the pulsed light control part used for an irradiation apparatus. It is a graph which shows the phase dispersion characteristic of a multimode fiber. It is a graph which shows the phase dispersion characteristic for negating the dispersion characteristic shown in FIG. It is a graph which shows the example of the time waveform of the pulsed light irradiated to an irradiation target object. It is a schematic diagram which shows the processing condition of the process target object by the pulsed light of the time waveform shown in FIG. It is a block diagram which shows the modification of the pulsed light irradiation apparatus shown in FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1A, 1B ... Pulse light irradiation apparatus, 10 ... Pulse laser light source, 15 ... Multimode fiber (light transmission means), 15a ... Input end, 15b ... Output end, 20 ... Input optical system, 20a ... Holding mechanism, 21 ... Aperture 21a ... reflected image observation surface, 21c ... aperture, 22 ... plano-convex lens, 22a ... plane, 22b ... convex surface, 30 ... input side pulsed light control unit, 36 ... waveform shaper, 37 ... stretcher, 40 ... output side Pulse light control unit, 41... Dispersion medium, 50... Irradiation evaluation unit, 55.

Claims (5)

A pulsed light source that supplies pulsed light of a predetermined wavelength;
An optical transmission means for transmitting the pulsed light to the irradiation object;
An input-side pulsed light control unit that is installed on the input side with respect to the optical transmission unit and widens the time waveform of the pulsed light input from the pulse light source to the optical transmission unit;
An output-side pulsed light control unit that is installed on the output side with respect to the optical transmission unit and that reduces the time waveform of the output pulsed light output from the optical transmission unit and generates irradiation pulsed light having a desired waveform; Prepared,
The optical transmission means is a multimode fiber,
The input side pulsed light control means includes:
After dispersed by the spectroscopic element entered the pulsed light, the respective spectral components and imaged in a state of spatially separated on the Fourier plane by a cylindrical concave mirror, on the Fourier plane with respect to the respective spectral component the arrangement spatial light modulator, after applying an independent phase modulation, the waveform shaper configured to multiplex the spectral components by a cylindrical concave mirror and the spectral element,
A phase modulation is applied to each spectral component of the pulsed light by a spectroscopic element to control the waveform of the pulsed light that expands the time waveform and to correct for secondary phase dispersion generated in the optical transmission means. A pulsed light irradiation apparatus comprising: a stretcher configured as described above.   2. The pulsed light irradiation apparatus according to claim 1, wherein the pulsed light source is a pulsed laser light source that emits pulsed laser light having a pulse width of 1 ps or less as the pulsed light.   3. The input side pulse light control means and the output side pulse light control means control transmission conditions including dispersion compensation conditions for the pulse light transmitted through the optical transmission means. Pulsed light irradiation device.   The input optical system which inputs the said pulsed light radiate | emitted from the said pulse light source to the said optical transmission means on the input conditions transmitted in a predetermined | prescribed propagation mode is provided. The pulsed light irradiation device according to item.   An optical system is configured on the output side of the optical transmission means so that the output pulse light output from the optical transmission means is spatially expanded and incident on the output-side pulse light control means. The pulsed light irradiation device according to any one of claims 1 to 4.

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