JP5435590B2 - Amorphous film crystallization apparatus and method - Google Patents

Description

  The present invention relates to an amorphous film crystallization apparatus and method for sequentially performing side surface crystallization by irradiating an amorphous film with laser light.

  As a semiconductor thin film used for a flat panel display substrate or the like, a semiconductor thin film using an amorphous film or a crystalline thin film is known. With respect to this crystalline thin film, a method of manufacturing an amorphous film by annealing and crystallizing has been proposed. In addition, SLS (sequential lateral solidification) technology is proposed in Patent Document 1 and Patent Document 2 in which a large single crystal silicon is manufactured by inducing lateral growth of a silicon crystal using an energy source as a laser. ing.

The SLS technology is based on the phenomenon that silicon grains grow in a direction perpendicular to the boundary surface between liquid silicon and solid phase silicon. By appropriately adjusting the intensity of the laser energy and the movement of the scanning range of the laser beam, the silicon grain is laterally grown to a predetermined length to crystallize the amorphous silicon thin film.
Furthermore, in the conventional apparatus, it is proposed in Patent Document 3 to provide a method with improved production efficiency when sequentially using a lateral crystallization (SLS) method to crystallize silicon.

In the apparatus shown in Patent Document 3, in order to improve the efficiency of the above process, as shown in FIG. 6, two blocks 40 and 41 having transmission regions 40a and 41a and blocking regions 40b and 41b on the optical member are placed sideways as shown in FIG. In addition, an activation region 42 in which a large number of small rectangular slits 42a are formed in the blocks is provided.
In the optical member, the laser beam is transmitted through the transmission region, and the laser beam is not transmitted through the shielding region, and the laser beam is absorbed and changed into heat, whereby a patterned laser beam is obtained.

International Publication No. 97/45827 Pamphlet Korean Patent Application Publication No. 2001-004129 JP 2005-5722 A

As described above, the optical member used in the conventional apparatus is composed of the laser light transmission region and the laser light shielding region. The laser light shielding region completely shields the laser beam, so that the pattern of the laser light transmission region can be accurately projected as an image on the amorphous film as the irradiation object.
The laser light shielding region is composed of a metal such as Cr or CrO film attached to quartz glass, etc., and absorbs the incident laser light and converts the light into heat to shield the laser light. Therefore, there is a problem that high-temperature heat is generated and the Cr film or the CrO film is damaged. Further, when heat is generated in the optical member, air convection is generated, which causes distortion of the pattern image by the optical member.
A method of cooling the optical member is also conceivable in order to prevent the above-described adverse effects caused by the generation of heat. For example, it is conceivable to cool the optical member by blowing air on the optical member. However, turbulent flow may occur in the air that has cooled the optical member, which may cause distortion of the pattern image. Although a method using a coolant such as water is conceivable, there is a problem that it is difficult to control the flow rate of the coolant or to control the vapor by evaporation of the coolant.

  The present invention has been made to solve the above-described problems of the prior art, and reduces the generation of heat in the optical member during laser light irradiation without taking a cooling means, thereby preventing adverse effects due to temperature rise. An object is to provide an amorphous film crystallization apparatus and a crystallization method that can be eliminated.

That is, among the amorphous film crystallization apparatuses of the present invention, the first present invention is
A laser light source that outputs laser light to irradiate the amorphous film;
An optical system for guiding the laser light to the amorphous film;
An objective lens that constitutes a part of the optical system and condenses the laser light applied to the amorphous film;
A laser light transmission region that is disposed on the laser beam path of the optical system on the front side of the objective lens and transmits a part of the laser beam, and a laser beam shielding area that blocks a part of the laser beam And an optical member that forms an image pattern by the laser light transmitting region and the laser light shielding region,
The optical member is smaller than a value (R / M) obtained by a product of a resolution (R) of the objective lens and a reciprocal of a magnification (M) of the objective lens in the laser light shielding region, and the laser light. A temperature increase suppressing laser beam transmitting portion that has a regulation dimension larger than the wavelength of the laser beam and allows the laser beam to pass therethrough is provided. The temperature increase suppressing laser beam transmitting portion is irradiated with the laser beam. characterized that you have a circular shape for the regulation size and diameter in the plane, however, the magnification of the objective lens (M), the distance between the amorphous film and the objective lens (b) and between the optical member and the objective lens It is equal to the ratio (b / a) to the distance (a) or the ratio (d / D) of the pattern image size (d) on the amorphous film to the pattern image size (D) of the optical member.
The amorphous film crystallization apparatus of the second invention is
A laser light source that outputs laser light to irradiate the amorphous film;
An optical system for guiding the laser light to the amorphous film;
An objective lens that constitutes a part of the optical system and condenses the laser light applied to the amorphous film;
A laser light transmission region that is disposed on the laser beam path of the optical system on the front side of the objective lens and transmits a part of the laser beam, and a laser beam shielding area that blocks a part of the laser beam And an optical member that forms an image pattern by the laser light transmitting region and the laser light shielding region,
The optical member is smaller than a value (R / M) obtained by a product of a resolution (R) of the objective lens and a reciprocal of a magnification (M) of the objective lens in the laser light shielding region, and the laser light. A plurality of temperature rise suppressing laser light transmitting portions that allow transmission of the laser light having a regulation dimension larger than the wavelength of the plurality of temperature rising suppressing laser light transmitting portions, The laser light shielding region is arranged with the same interval.
However, the magnification (M) of the objective lens is the ratio (b / a) between the distance (b) between the amorphous film and the objective lens and the distance (a) between the optical member and the objective lens, or on the amorphous film. It is equal to the ratio (d / D) of the pattern image size (d) and the pattern image size (D) of the optical member.

In the amorphous film crystallization apparatus according to the third aspect of the present invention, in the second aspect of the present invention, the laser beam transmitting portion for suppressing temperature increase is a strip having the restriction dimension on the short side on the laser light irradiation surface. It has a shape.
In the amorphous film crystallization apparatus according to a fourth aspect of the present invention, in the second aspect of the present invention, the laser beam transmission part for suppressing temperature increase has a circular shape with the regulation dimension as a diameter on the laser light irradiation surface. It is characterized by that.
According to a fifth aspect of the present invention, there is provided the amorphous film crystallization apparatus according to any one of the first to fourth aspects of the present invention, wherein the laser beam transmitting part for suppressing temperature rise has a relative penetration rate or relative transmittance of the laser beam. It is characterized by comprising a high part.
The amorphous film crystallization apparatus according to a sixth aspect of the present invention is characterized in that, in any of the first to fifth aspects of the present invention, the optical member has an unirradiated region where the laser beam is not irradiated.
An amorphous film crystallization apparatus according to a seventh aspect of the present invention is the amorphous film crystallization apparatus according to any one of the first to sixth aspects of the present invention, wherein the amorphous film is sequentially subjected to side surface crystallization by irradiation with the laser beam. To do.

The amorphous film crystallization method according to the eighth aspect of the present invention irradiates a laser beam through an optical member having a laser beam transmission region and a laser beam shielding region, and the optical according to the laser beam transmission region and the laser beam shielding region. A crystallization method of condensing a laser beam of a pattern transmitted through a member with an objective lens and irradiating the amorphous film, and sequentially crystallizing the amorphous film by side crystallization,
A restriction that a part of the laser light irradiated to the laser light shielding area is smaller than the product of the resolution of the objective lens and the reciprocal of the magnification in the laser light shielding area and larger than the wavelength of the laser light. The optical member is transmitted through a circular laser beam transmitting portion for suppressing temperature rise having a size, and at least a part of the laser beam transmitting the laser beam transmitting region is irradiated to the irradiation region where the amorphous film is irradiated. It is characterized by doing.
The amorphous film crystallization method of the ninth aspect of the present invention irradiates a laser beam through an optical member having a laser beam transmission region and a laser beam shielding region, and the optical according to the laser beam transmission region and the laser beam shielding region. A crystallization method of condensing a laser beam of a pattern transmitted through a member with an objective lens and irradiating the amorphous film, and sequentially crystallizing the amorphous film by side crystallization,
A restriction that a part of the laser light irradiated to the laser light shielding area is smaller than the product of the resolution of the objective lens and the reciprocal of the magnification in the laser light shielding area and larger than the wavelength of the laser light. The laser having a size and transmitting the optical member through a laser beam transmitting portion for suppressing temperature increase arranged at the same interval in the laser beam shielding region, and at least a part of the laser beam transmitting the laser beam transmitting region The irradiation area where the amorphous film is irradiated is irradiated with light.

According to the present invention, the laser light applied to the laser beam transmission part for suppressing temperature increase in the laser beam shielding area is transmitted through the region of the laser beam transmission part for suppressing temperature increase in the laser beam shielding area. However, it does not irradiate with sufficient energy on the amorphous film by passing through a region having a regulation dimension smaller than the product of the resolution of the objective lens and the reciprocal of the magnification.
The resolution of the objective lens is the minimum dimension that allows the pattern of the optical member to be patterned on the amorphous film by laser light irradiation. That is, it is the minimum dimension (in terms of the amorphous film surface) at which the amorphous film is not crystallized under the conditions used for the SLS process (energy density used for crystallization and the focal position of the objective lens).
The magnification (M) of the objective lens can be determined as follows.
That is, the magnification (M) of the objective lens = (distance (b) between the amorphous film and the objective lens) / (distance (a) between the optical member and the objective lens), or
Magnification of objective lens (M) = (pattern image size on amorphous film (d)) / (pattern image size of optical member (D))
Therefore, the magnification of the objective lens varies depending on the positional relationship among the optical member, the objective lens, and the amorphous film. The distance between the objective lens and the optical member is the distance between the optical center of the objective lens on the optical axis and the surface of the optical member. The distance between the objective lens and the amorphous film is the optical center of the objective lens on the optical axis and the surface of the amorphous film. It can be shown by the distance.

  In addition, when the region of the laser beam transmitting portion for suppressing temperature increase does not have a size smaller than the product of the resolution of the objective lens and the reciprocal of the magnification, the laser beam transmitted through the region has sufficient energy. In this state, the amorphous film is irradiated to impair the function as a laser light shielding region. Note that the temperature rise suppression laser beam transmitting portion has a regulation size smaller than the product in any direction (in the plane direction) at any position of the temperature increase suppression laser beam transmission portion in the plane direction. It has a dimension smaller than the product.

In addition, if the regulation dimension of the laser beam transmitting part for suppressing temperature rise does not have a dimension larger than the wavelength of the laser beam, diffraction is conspicuous when the laser beam is transmitted through the laser beam transmitting part for temperature increase suppression. And is scattered outside the irradiated surface of the amorphous film. For this reason, it is necessary for the laser beam transmission part for temperature rise suppression to have a regulation dimension larger than the wavelength of the laser beam.
Incidentally, the fact that the laser beam transmitting part for suppressing temperature increase has a regulation dimension larger than the wavelength of the laser beam indicates that the regulation dimension satisfies this condition.
In addition, since the resolution of the objective lens and the wavelength of the laser beam are not uniform, the regulation size required for the laser beam transmission part for suppressing the temperature increase is not limited to a specific numerical value. Usually, the required regulation dimension is exemplified by a dimension of 0.5 to 1.0 μm on the amorphous film.

The optical member in the present invention is not limited to a specific material, and any optical member can be used as long as a laser light irradiation region and a laser light shielding region can be obtained. It can also be formed by film formation or the like.
The laser beam transmitting region may be any region that can impart energy to the amorphous film to such an extent that the laser beam is transmitted and the side surface crystallization is sequentially performed by irradiating the amorphous film with the laser beam. The laser light transmission region may be formed by a penetrating portion, or may be configured by a portion having a relatively high transmittance.
On the other hand, the laser light shielding region may be a region where the laser light is transmitted with relatively lower energy than the laser light transmitting region, in addition to the region where the laser light is not transmitted. In other words, it is only necessary that the energy of the laser light that passes through the laser light shielding region is distinguished from the energy of the laser light that passes through the laser light transmitting region, and the side crystallization is performed sequentially.

  The laser beam transmission part for temperature rise suppression according to the present invention allows the transmission of the laser beam partially in the laser beam shielding region when the laser beam is not transmitted in the laser beam shielding region. The transmission of the laser light only gives small energy to the amorphous film as compared with the laser light transmission region. Further, when laser light is transmitted while being limited in the laser light shielding region, the laser light transmitting portion for temperature rise suppression transmits the laser light with a higher transmittance than the laser light shielding region. However, the amount of energy given to the amorphous film of the transmitted laser beam in the laser beam transmitting portion for suppressing temperature rise is much smaller than that of the laser beam transmitted through the laser beam transmitting region, so that the side crystallization is not hindered sequentially.

In addition, the shape of the laser beam transmission part for temperature rise suppression is not particularly limited as long as it satisfies the above-mentioned regulation dimension. For example, a strip shape having the prescribed regulation dimension in the short width direction can be used. In the case where the laser beam transmitting portion for suppressing temperature increase is formed of a penetrating portion, it can be said to be a slit shape. A plurality of the strips can be arranged in parallel at a predetermined interval, or arranged vertically and horizontally, and the temperature rise of the optical member can be effectively suppressed.
Further, the shape of the laser beam transmitting portion for suppressing temperature increase can be a circular shape having the above-mentioned regulated size as a diameter. In the case where the laser beam transmitting portion for suppressing the temperature increase is constituted by a penetrating portion, it can also be said to be a hole shape. By increasing the number of the circular shapes, the temperature of the optical member can be effectively suppressed. The laser beam transmitting portion for suppressing the temperature increase may be provided on the optical member with a different shape.

  INDUSTRIAL APPLICABILITY The present invention can be suitably used as an SLS crystallization method and apparatus for manufacturing a polycrystalline or single crystal semiconductor film of a thin film transistor used in a pixel switch or a drive circuit of a liquid crystal display or an organic EL display.

  As described above, according to the present invention, the laser beam is transmitted through the laser beam transmitting portion for suppressing temperature increase provided in the laser beam shielding region of the optical member so that there is no hindrance to crystallization. Suppresses the generation of heat, effectively prevents damage due to temperature rise, and improves durability. Moreover, generation | occurrence | production of the distortion of a pattern image can be prevented by suppressing generation | occurrence | production of the heat | fever in an optical member.

It is the schematic which shows the amorphous film crystallization apparatus of one Embodiment of this invention. Similarly, it is a top view which shows an optical member. Similarly, it is the enlarged top view which shows an optical member. Similarly, it is a figure which shows the positional relationship of an optical member, an objective lens, and an amorphous film. Similarly, it is the enlarged top view which shows the example of a change of an optical member. It is a top view which shows the conventional optical member. It is a figure explaining the damage state by the laser beam irradiation in the conventional optical member.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a schematic view showing a laser annealing apparatus 1 corresponding to the amorphous film crystallization apparatus of the present invention.
The laser annealing apparatus 1 has a stage 3 on which a substrate 2 on which an amorphous silicon film is formed is placed. Further, an X movement motor 4a that moves the stage 3 in the X axis direction and a Y movement motor 4b that can move in the Y axis direction are provided. An X movement driver 5a and a Y movement driver 5b are electrically connected to each motor. It is connected to the. Each driver is connected to a system controller 6 composed of a computer, and can control each moving motor.

  Further, the laser annealing apparatus 1 includes a laser light source 10 that outputs laser light 10a having a predetermined wavelength. The silicon film is in an amorphous state before processing. As the laser light source 10, for example, a laser oscillator LS2000 (1) or LSX315 (wavelength 308 nm, repetition frequency 300 Hz) manufactured by Coherent Co., Ltd. can be used. However, the laser light source 10 is not limited to a specific one in the present invention.

An attenuator 11 is disposed in the irradiation direction of the laser light 10 a oscillated by the laser light source 10, and an optical system 15 including a mirror 12, a beam shaper 13, an objective lens 14 and the like is disposed in the emission direction of the attenuator 11. Has been. Laser light 10 a is guided through the optical system 15 and is irradiated onto the silicon film of the substrate 2.
The attenuator 11 attenuates the laser beam 10a and adjusts it to a predetermined energy. As the attenuator 11, a variable attenuator capable of adjusting the attenuation rate can be used. In the attenuator 11 adjusts the attenuation factor of the laser beam 10a so as for example of about 600 mJ ^/ cm 2 energy density of -1000mJ / cm ² on the silicon film.

The mirror 12 deflects the irradiation direction of the laser light 10a output from the laser light source 10. For example, the laser light 10a output in the horizontal direction from the laser light source 10 is applied to the substrate 2 on which the silicon film is formed. Therefore, the direction is changed vertically.
The beam shaper 13 shapes the laser beam 10a into a beam cross-sectional shape such as a rectangular shape or a circular shape.
The objective lens 14 condenses the laser beam 10a and irradiates the vicinity of the silicon film surface on the substrate 2. The distance between the optical center of the objective lens 14 and the silicon film surface on the optical axis is b in the figure. It is shown.

Further, on the light path of the laser beam 10a, there is a laser beam shielding region 20a and a laser beam transmission region 20b on the incident side of the objective lens 14, and the laser beam transmission region 20a and the laser beam shielding region 20b An optical member 20 for forming a pattern is disposed. The distance between the optical member 20 and the objective lens 14 on the optical axis is indicated by a in the figure.
In this embodiment, the silicon film is an object of processing. However, the present invention processes an amorphous film into a crystal film or a crystal film, and the material is limited to silicon. It is not something.

  As shown in FIG. 2A, the optical member 20 has a rectangular shape, and in the surface direction, the strip-shaped laser light transmission region 20a is arranged in parallel so that the long sides are adjacent to each other. The adjacent laser light transmission regions 20a are provided at a small interval. The optical member 20 is a laser light shielding region 20b in the plane direction except for the laser light transmitting region 20a.

The manufacturing method of the optical member 20 having the laser light transmission region 20a and the laser light shielding region 20b is not particularly limited as the present invention. For example, an optical member is composed of a material that transmits laser light, and a metal thin film is coated by vapor deposition or the like on a region other than the laser light transmitting region 20a using a shadow mask that covers a portion of the laser light transmitting region 20a. The light shielding region 20b can be formed. Further, the optical member 20 may be obtained by removing the metal thin film by etching or the like in a region corresponding to the laser light transmitting region 20a with respect to the metal thin film coated on the surface of the optical member.
In this embodiment, the optical member 20 body is made of a material that transmits laser light, and a metal film made of Cr or CrO is formed on the laser light shielding region 20b excluding the laser light transmitting region 20a.

Further, in the laser light shielding region 20b of the optical member 20, as shown in FIG. 3, a narrow laser beam transmitting part 21 for suppressing temperature rise is arranged at intervals along the edge of the laser beam transmitting region 20a. Are in parallel. In this embodiment, the width of the laser beam transmitting portion 21 for suppressing temperature increase and the interval width between the laser beam transmitting portions 21 for suppressing temperature increase are substantially the same width. Accordingly, in the laser light shielding region 20b, the total area of the laser beam transmitting portion 21 for suppressing the temperature increase and the other total area are about ½ each.
The width of the laser beam transmitting portion 21 for suppressing the temperature increase is smaller than the product (R / M) of the resolution (R) of the objective lens and the inverse of the magnification (M) of the objective lens described below. Furthermore, the width of the laser beam transmitting portion 21 for suppressing temperature increase is larger than the wavelength of the laser beam 10a. In this embodiment, the width exceeds, for example, 308 nm, which is the wavelength of the laser beam 10a.
As shown in FIG. 4, the magnification of the objective lens is the ratio (b / a) between the distance (b) between the amorphous film on the substrate 2 and the objective lens 14 and the distance (a) between the optical member 20 and the objective lens 14. ) Or the ratio (d / D) of the pattern image size (d) on the amorphous film on the substrate 2 and the pattern image size (D) of the optical member 20. Each distance can be evaluated on the optical axis, and the base point of the distance in the objective lens 14 is the optical center.

Next, the operation of the laser annealing apparatus 1 will be described.
Laser light 10a is output from the laser light source 10. In this embodiment, excimer laser light having a wavelength of 308 nm is output. The laser light 10 a is adjusted to energy suitable for crystallized silicon by the attenuator 11, deflected by the mirror 12, and enters the beam shaper 13. The beam shaper 13 forms the desired beam cross-sectional shape. For example, it is shaped into a beam cross-sectional shape having a major axis of 125 mm and a minor axis of 6 mm.

  The laser beam 10 a that has passed through the beam shaper 13 reaches the optical member 20, is patterned by a pattern according to the shape and arrangement of the laser beam transmission region 20 a, and reaches the objective lens 14. The laser beam 10a is condensed when passing through the objective lens 14, and is irradiated on the silicon film on the substrate 2 in a predetermined pattern image. Side crystallization can be performed sequentially by changing the position of the optical member 20 and irradiating the silicon film on the substrate 2 with a laser beam 10a in a predetermined pattern image. Further, the relative position between the laser beam 10a and the silicon film can be changed by moving the stage 2 while feeding the pitch by the X moving motor 4a and the Y moving motor 4b.

Although there is a shutter (not shown) between the objective lens 14 and the substrate 2, it is for blocking the laser beam at the end surface of the substrate not coated with a silicon (amorphous silicon) film. The reason why the shutter is arranged after the objective lens 14 is as follows.
Depending on whether or not the laser beam 10a passes through the objective lens 14, a temperature change occurs and is affected by a focus shift of the objective lens 14 and the like. Even when the shutter is closed, the influence can be reduced by passing the laser beam 10a through the objective lens 14. The shutter is provided with a mirror tilted at 45 °, so that the energy of the laser beam 10a can be consumed toward a beam dump (not shown) without being reflected by the optical system.

FIG. 2B is a view showing the periphery of the laser light transmission region 20a irradiated with the laser light 10a, and shows a part of the optical member 20. FIG.
Note that the laser beam 10a cannot enter the optical member 20 with a size suitable for the laser beam transmission region 20a due to the vibration of the apparatus and the fluctuation of the position of the laser beam 10a. Therefore, the laser beam 10a is shaped to be larger than the pattern size and is incident on the optical member 20, so that the laser beam 10a is not only irradiated to the laser beam shielding region 20b between the laser beam transmitting regions 20a but also the laser beam transmitting region. Laser light 20a is also irradiated around 20a, and high temperature is generated. In the laser light shielding region 20b, the region that is not irradiated with laser light is also a non-irradiated region.
In the conventional optical member, as shown in FIG. 7, a part of the laser light shielding region 20b around the laser light transmitting region 20a becomes particularly high temperature, and damage is likely to occur over time. Further, even before the damage occurs, air convection occurs, and the pattern image by the optical member 20 is damaged.

On the other hand, in the optical member 20 of this embodiment, half the area of the original laser light shielding region 20b is the laser light transmitting portion 21 for suppressing the temperature rise, and this portion is irradiated with the laser light 10a. Heating during heating is suppressed. Thereby, the temperature rise of the whole optical member 20 becomes small.
As described above, according to this embodiment, since the generation of heat can be suppressed by minimizing the metal portion of the laser light shielding region 20b of the optical member 20, damage to the optical member 20 is reduced. can do. Furthermore, the pattern of the optical member 20 can be accurately projected onto the amorphous silicon film.

Note that the laser beam transmitting portion for suppressing the temperature increase provided in the laser beam shielding region of the optical member is not limited to the narrow shape described above, and the shape is specified as long as the regulation dimensions of the present invention are satisfied. It is not limited to those.
FIG. 5 shows an optical member 30 of another form, and the optical member 30 has a laser light transmission region 30a and a laser light shielding region 30b as in the above embodiment. In the optical member 30, instead of the laser beam transmission part 21 for suppressing temperature increase, circular laser beam transmission parts 31 for suppressing temperature increase are scattered in the laser beam shielding region 30b. The diameter of the transmission part 31 is smaller than the resolution of the objective lens 14 and larger than the wavelength of the laser beam 10a. The total area of the remaining portions of the laser beam transmitting portion 30a for suppressing temperature increase and the laser beam shielding region 30b is substantially the same.
Also in this embodiment, when the laser beam 10a is irradiated, the generation of heat in the laser beam shielding region 30b is suppressed, and the occurrence of damage or distortion of the pattern image due to the temperature rise of the optical member 30 is prevented.

DESCRIPTION OF SYMBOLS 1 Laser annealing apparatus 2 Substrate 3 Stage 4a X movement motor 4b Y movement motor 10 Laser light source 10a Laser light 11 Attenuator 12 Mirror 13 Beam shaper 14 Objective lens 20 Optical member 20a Laser light transmission area 20b Laser light shielding area 21 Temperature rise suppression Laser light transmission part 30 Optical member 30a Laser light transmission area 30b Laser light shielding area 31 Laser light transmission part for temperature rise suppression

Claims (9)

A laser light source that outputs laser light to irradiate the amorphous film;
An optical system for guiding the laser light to the amorphous film;
An objective lens that constitutes a part of the optical system and condenses the laser light applied to the amorphous film;
A laser light transmission region that is disposed on the laser beam path of the optical system on the front side of the objective lens and transmits a part of the laser beam, and a laser beam shielding area that blocks a part of the laser beam And an optical member that forms an image pattern by the laser light transmitting region and the laser light shielding region,
The optical member is smaller than a value (R / M) obtained by a product of a resolution (R) of the objective lens and a reciprocal of a magnification (M) of the objective lens in the laser light shielding region, and the laser light. A temperature increase suppressing laser beam transmitting portion that has a regulation dimension larger than the wavelength of the laser beam and allows the laser beam to pass therethrough is provided. The temperature increase suppressing laser beam transmitting portion is irradiated with the laser beam. amorphous film crystallizer However characterized that you have a circular shape that the diameter of the regulating dimension in the plane, the magnification of the objective lens (M), the optical member and the distance (b) between the amorphous layer and the objective lens and the ratio of the distance between the objective lens (a) (b / a) , or, equal to the ratio of the pattern image size of the pattern image size on the amorphous film (d) and the optical member (D) (d / D) . A laser light source that outputs laser light to irradiate the amorphous film;
An optical system for guiding the laser light to the amorphous film;
An objective lens that constitutes a part of the optical system and condenses the laser light applied to the amorphous film;
A laser light transmission region that is disposed on the laser beam path of the optical system on the front side of the objective lens and transmits a part of the laser beam, and a laser beam shielding area that blocks a part of the laser beam And an optical member that forms an image pattern by the laser light transmitting region and the laser light shielding region,
The optical member is smaller than a value (R / M) obtained by a product of a resolution (R) of the objective lens and a reciprocal of a magnification (M) of the objective lens in the laser light shielding region, and the laser light. A plurality of temperature rise suppressing laser light transmitting portions that allow transmission of the laser light having a regulation dimension larger than the wavelength of the plurality of temperature rising suppressing laser light transmitting portions, Amorphous film crystallization apparatus characterized by being arranged in the laser light shielding region with the same interval. However, the magnification (M) of the objective lens is the distance (b) between the amorphous film and the objective lens and the optical The ratio (b / a) of the distance (a) between the member and the objective lens, or the ratio (d / D) of the pattern image size (d) on the amorphous film and the pattern image size (D) of the optical member Equal . 3. The amorphous film crystallization apparatus according to claim 2 , wherein the laser beam transmission part for suppressing temperature increase has a strip shape having the regulation dimension on a short side on an irradiation surface of the laser beam. 3. The amorphous film crystallization apparatus according to claim 2 , wherein the laser beam transmission part for suppressing temperature increase has a circular shape having a diameter of the restriction dimension on an irradiation surface of the laser beam. The amorphous film crystal according to any one of claims 1 to 4 , wherein the laser beam transmitting part for temperature rise suppression is configured by a penetrating part or a part having a relatively high transmittance of the laser light. Device. The optical member, an amorphous film crystallization apparatus according to any one of claims 1 to 5, wherein the laser beam is characterized by having a non-irradiated region which is not irradiated. The amorphous film crystallization apparatus according to any one of claims 1 to 6 , wherein the amorphous film is sequentially subjected to side crystallization by irradiation with the laser beam. Laser light is irradiated through an optical member having a laser light transmission region and a laser light shielding region, and laser light having a pattern transmitted through the optical member in accordance with the laser light transmission region and the laser light shielding region is collected by an objective lens. A crystallization method of irradiating an amorphous film with light and sequentially crystallizing the amorphous film by side crystallization,
A restriction that a part of the laser light irradiated to the laser light shielding area is smaller than the product of the resolution of the objective lens and the reciprocal of the magnification in the laser light shielding area and larger than the wavelength of the laser light. The optical member is transmitted through a circular laser beam transmitting portion for suppressing temperature rise having a size, and at least a part of the laser beam transmitting the laser beam transmitting region is irradiated to the irradiation region where the amorphous film is irradiated. A method for crystallizing an amorphous film, comprising: Laser light is irradiated through an optical member having a laser light transmission region and a laser light shielding region, and laser light having a pattern transmitted through the optical member in accordance with the laser light transmission region and the laser light shielding region is collected by an objective lens. A crystallization method of irradiating an amorphous film with light and sequentially crystallizing the amorphous film by side crystallization,
A restriction that a part of the laser light irradiated to the laser light shielding area is smaller than the product of the resolution of the objective lens and the reciprocal of the magnification in the laser light shielding area and larger than the wavelength of the laser light. The laser having a size and transmitting the optical member through a laser beam transmitting portion for suppressing temperature increase arranged at the same interval in the laser beam shielding region, and at least a part of the laser beam transmitting the laser beam transmitting region An amorphous film crystallization method comprising irradiating an irradiation region where light is irradiated to the amorphous film.

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