JP3545796B2 - Optical device and optical device manufacturing method - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to an optical device and an optical device manufacturing method.
[0002]
[Prior art]
A special surface shape represented by an aspherical surface has been used for a lens or a mirror. It is not easy to create a special surface shape such as an aspherical surface by mechanical polishing, and usually, it is often produced by molding using a mold.
[0003]
For this reason, for example, most lenses having an aspherical refracting surface are manufactured as plastic molded products using a plastic material, and there is a problem in that there is little room for material selection.
[0004]
As a technique for creating a desired surface shape on a glass surface using a mold, a “glass press method” is known, but the mold used is a high temperature (650 ° C. or higher) and high pressure when molding into glass. And it must also be resistant to oxidation at high temperatures. For this reason, mold materials are limited to special metals and ceramics. Such special materials are very difficult to process the mold, and in order to add oxidation resistance, the surface of the mold must be made of Si._ThreeN_Four, SiC, Au, Pt, etc. need to be formed.
[0005]
For this reason, the "mold" used in the glass pressing method is expensive and used under high temperature and high pressure, so that the "life as a mold" is not so long regardless of the material selected.
[0006]
On the other hand, as a method of creating a refraction surface or a reflection surface without using molding or polishing, a layer of photoresist is formed on the surface of an optical material, and this layer is patterned into, for example, a circle or an ellipse. The layer is heated, and the surface of the photoresist is curved by heat flow of the photoresist. Thereafter, the photoresist and the optical material are anisotropically etched to form the curved surface of the photoresist surface. A method of engraving on an optical material has been proposed (for example, Japanese Patent Laid-Open No. 5-173003: Claim 16).
[0007]
Although this method is suitable as a method for forming a refraction surface of a microlens, it is not always easy to control the surface shape generated on the photoresist surface by heating, and it is difficult to accurately form a curved surface as intended.
[0008]
[Problems to be solved by the invention]
The present invention has been made in view of the above circumstances, and has as its object to provide a novel optical device having a desired surface shape accurately.Claims 11 and 12).
[0009]
Another object of the present invention is to provide a novel optical device manufacturing method capable of easily and reliably manufacturing an optical device having a desired surface shape (Claims 1 to 10).
[0010]
Various optical device materials are used in the optical device manufacturing method.
[0011]
[Means for Solving the Problems]
First, an optical device material used in the optical device manufacturing method will be described.
An optical device material used in the optical device manufacturing method according to claim 1.Is formed by forming one or more convex curved shapes on a planar surface of a device material using a transfer material.
The “device material” is a material that finally becomes an optical device, and has a “planar surface” as described above in the first aspect of the present invention.
The “one or more convex curved surface shapes” are transferred and formed on a transfer material using a “mold” having a concave curved surface shape corresponding to a predetermined convex curved surface shape.
[0012]
An optical device material used in the optical device manufacturing method according to claim 2.Is formed by forming at least one curved surface shape with a transfer material on a “surface having a predetermined curvature” in a device material. The “surface having a predetermined curvature” is not limited to a spherical surface, and may be a cylinder surface (a maximum curvature and a minimum curvature: 0 are uniquely defined), a spheroidal surface, and the like.
The one or more “curved surface shapes” are formed by transferring the above-mentioned transfer surface shape to a transfer material from a mold having a predetermined curved surface shape as the transfer surface shape.
[0013]
Material for an optical device used in the invention according to claim 2As the “device material” in the above, a “sphere” or a “cylindrical body” can be used (claim 3), and a “material formed in a lens shape” can be used (claim 4). The lens shape in this case is not limited to the spherical lens shape, but may be a cylinder lens shape or a toroidal lens shape.
[0014]
An optical device material used in the optical device manufacturing method according to claim 5.In the flat part of the device material, which is a shape obtained by processing a part of a sphere by plane processing and cutting a part of a sphere by a plane, a `` molding die formed with a predetermined curved surface shape as a transfer surface shape '' The transfer material on which the transfer surface shape has been transferred is formed into a curved surface shape. In this case, another curved surface shape (transferred from another mold) can be formed by the transfer material also on the spherical portion on the opposite side of the planar portion of the device material.
[0015]
An optical device material used in the optical device manufacturing method according to claim 6.Is a device in which a part of a sphere is processed into a plane and a part of the sphere is cut by a pair of parallel planes. It is formed by forming a curved surface shape from a transfer material on which the above-mentioned transfer surface shape is transferred from a “forming mold formed as a shape”.
thisThe material for an optical device according to claim 6.In the case where a curved surface shape is formed by a transfer material on each of a pair of planar portions, both curved surface shapes may be the same or different.
[0016]
An optical device material used in the optical device manufacturing method according to claim 7.In the planar material of the device material that was `` a shape obtained by processing the peripheral surface of the cylindrical body into a plane and cutting a part of the cylinder along a plane parallel to the axis, '' a `` predetermined curved surface shape was formed as a transfer surface shape A curved surface shape is formed by a transfer material on which the transfer surface shape is transferred from the “formed mold”. In this case, another curved surface shape (transferred from another mold) can be formed by the transfer material also on the cylindrical surface portion of the device material opposite to the planar portion.
[0017]
An optical device material used in the optical device manufacturing method according to claim 8.In at least one of the planar portions of the device material, "a peripheral surface of the columnar body is processed into a plane, and a part of the cylinder is cut along a pair of planes parallel to the axis and parallel to each other." It is formed by forming a curved surface shape from a transfer material on which the above-mentioned transfer surface shape is transferred from a “mold having a predetermined curved surface shape as a transfer surface shape”. In this case, when a curved surface shape is formed by the transfer material on each of the pair of planar portions, both curved surface shapes may be the same or different.
[0018]
According to the invention of claims 2 to 8,InAs the “curved surface shape” formed by the transfer material on the device material, various curved surface shapes such as a convex or concave spherical surface, a convex or concave aspheric surface, and a convex or concave cylinder surface are possible.
[0019]
Also,An optical device material used in the optical device manufacturing method according to claim 1.In the above, as the “transfer material”, a material which is cured by light and / or heat and can be physically etched can be used as appropriate. That is, as the transfer material, a “photo-curable material” or a “thermo-curable material that cures at a temperature of 200 ° C. or lower” is preferable.
[0020]
As the “photo-curable material”, an epoxy resin, an acrylic resin, a urethane resin, a modified silicone resin, or a material composed of a compound based on these resins can be used. In particular, those prepared by combining an epoxy resin and an acrylic resin are suitable as a transfer material. Of course, a commercially available ultraviolet curable resin or the like can be suitably used as the transfer material.
As the “thermosetting material that cures at a temperature of 200 ° C. or less”, an epoxy resin, a phenol resin, a urea resin, a melamine resin, or the like can be used.
[0021]
Also,Material for an optical device used in the invention according to claims 1 to 9Can be used without particular limitation as long as it can be physically etched, but of course, when manufacturing a light-transmitting optical device, a “transparent optical material” is used. (Claim 10).
[0022]
The “optical device manufacturing method” of the present inventionAny of the materials for optical devices described aboveThe feature is that "the surface shape of the transfer material is engraved on the device material by performing anisotropic physical etching on the transfer material and the device material" (Claims 1 to 10). As “physical etching”, dry etching such as RIE or ECR plasma etching is preferable.
[0023]
The “optical device” of the present inventionAn optical device itself manufactured by the optical device manufacturing method according to any one of claims 1 to 10.Is (Claim 11).Claim 11An optical device in which a reflection film is formed on a curved surface portion of the optical device can be referred to as an “optical device” (Claim 12). As described above, when forming the reflection film to form an optical device, it is needless to say that the device material does not have to be transparent.
[0024]
If an appropriate device material is selected, the optical device itself according to claim 11 manufactured as described above isThe material for an optical device according to claim 1.It should be noted that it can also be used as a "mold" for transferring a transfer surface shape to a transfer material.
[0025]
[Action]
As described above, in the optical device manufacturing method according to the present invention, the optical device material has a curved surface shape by the transfer material, and the device material and the transfer material are subjected to anisotropic physical etching, whereby the transfer is performed. The curved surface shape, which is the surface shape of the material, is engraved on the device material.
[0026]
The curved surface shape formed as the surface shape of the transfer material is accurately formed by transferring the transfer surface shape of the mold.
[0027]
【Example】
FIG. 1 (a)Claim 11 shows an example of the optical device material of Example 1.
[0028]
The optical device material 10 is a material in which a plurality of convex curved surfaces formed by a transfer material 12 are formed in an array on one surface of a parallel-plate device material 11. The convex curved surface shape of the transfer material 12 is accurately formed by transferring the convex curved shape onto the transfer material 12 using a molding die 300 having a “concave curved shape corresponding to a predetermined convex curved shape”. It is.
[0029]
The surface of the optical device material 10 shown in FIG. 1A on which the convex curved surface shape is formed by the transfer material 12 is physically etched, and the surface shape of the transfer material 12 is engraved on the device material 11. For example, as shown in FIG. 1B, it is possible to obtain an optical device 1A in which a desired convex curved shape is formed in an array on one surface.Claims 1 and 11).
[0030]
If a “transparent material” is used as the device material 11, the optical device of FIG. 1B has a lens array or a microlens array having the formed convex curved surface as a refraction surface (when the formed refraction surface is small). Available as
[0031]
Of course, an optical device material in which the convex shape of the transfer material is formed on both sides of the device material 11 of FIG. 1 in correspondence with each other is also possible.Claim 1By applying the described manufacturing method, it is possible to obtain an “optical device having a refracting surface on both surfaces of a parallel plate”.
[0032]
Also, if a reflective film is formed on the surface of the optical device 1A of FIG. 1B on which the convex curved surface is formed, an optical device that can be used as a convex mirror array or a micro-convex mirror array can be realized (Claim 12).
[0033]
FIG. 2A shows one embodiment of the optical device material according to the second and third aspects. The optical device material 20 has a predetermined surface shape (aspherical surface) formed by a transfer material 22 on the surface of a spherical device material 21. The surface shape of the transfer material 22 is accurately formed by transferring the transfer surface shape from the “mold having a predetermined curved surface shape as the transfer surface shape” to the surface of the transfer material 22.
[0034]
2A, anisotropic physical etching is performed on the transfer material 22 and the device material 21 to engrave the surface shape of the transfer material 22 on the device material 21. An optical device 2A as shown in b) can be obtained. If a transparent material is used as the device material 21, the optical device 2A can be used as a lens or a micro lens (when the sphere 21 is small) having “one surface is spherical and one surface is aspheric”.
[0035]
The “curved surface shape” engraved on the device material 21 is a shape obtained by engraving the surface shape of the transfer material 22 as it is or a similar shape to the above surface shape. The "transfer surface shape that becomes a curved surface shape" is formed in the mold.
[0036]
In FIG. 2A, if the device material 21 is a “cylindrical body” that is long in a direction perpendicular to the drawing, the obtained optical device has a specially shaped surface on one side and a cylindrical surface on the other side. It can be used as a cylinder lens or a micro cylinder lens.
[0037]
FIG. 3 (a)Claims 2 and 41 shows an example of the optical device material of Example 1.
The optical device material 30 has a predetermined curved shape formed by a transfer material 32 on one surface of the lens-shaped device material 30. Of course, the curved surface shape, which is the surface shape of the transfer material 32, can be accurately obtained by transferring the transfer surface shape to the surface of the transfer material 22 from a "mold having a predetermined curved surface shape as the transfer surface shape". It is formed.
[0038]
In the state shown in FIG. 3A, the transfer material 32 and the device material 31 are subjected to anisotropic physical etching, and the surface shape of the transfer material 32 is engraved on the device material 31 to obtain the structure shown in FIG. An optical device 3A as shown in b) can be obtained. If a transparent material is used as the device material and the device material 31 has a spherical lens shape, the optical device 3A is used as a lens or a microlens having “one surface is spherical and one surface is aspheric” (when the device material is small). it can.
[0039]
Further, if a cylindrical lens shape long in a direction orthogonal to the drawing is used as the device material 31, the optical device 3A has a cylinder surface on one side and an aspherical cylinder lens or toroidal lens on one side, or a micro cylinder lens or the like. It can be used as a micro toroidal lens.
[0040]
The “curved surface shape” engraved on the device material 31 becomes a shape obtained by engraving the surface shape of the transfer material 32 as it is or a similar shape to the above surface shape. A transfer surface shape that becomes a curved surface shape is formed in a molding die in advance.
[0041]
FIG. 4 (a)Claims 2 and 5Of materials for optical devicesOne caseIs shown.
The optical device material 40 has a predetermined curved shape formed as a transfer surface shape on a planar portion of a device material 41 in which a part of a sphere is flattened and a part of a sphere is cut in a plane. The configuration is such that a curved surface shape is formed by a transfer material 42 to which the transfer surface shape has been transferred from a molding die (not shown).
[0042]
In the state of FIG. 4A, anisotropic physical etching is performed on the transfer material 41 and the device material 42, and the surface shape of the transfer material 42 is engraved on the device material 41. An optical device 4A as shown in b) can be obtained. If a transparent material is used as the device material, the optical device 4A can be used as a lens or microlens having one surface spherical and one surface aspherical or spherical.
[0043]
In FIG. 4A, if the device material 41 has a shape obtained by cutting a part of a long cylinder in a direction perpendicular to the drawing by a plane parallel to the axis, the obtained optical device has a predetermined surface on one side. It can be used as a cylinder lens or a micro-cylinder lens having a curved surface shape and the other side being a cylinder surface (claim 7).
[0044]
FIG. 5 (a)Claims 2 and 6Of materials for optical devicesOne caseIs shown.
The optical device material 50 is formed by processing a part of a sphere into a plane and forming a part of the sphere into a shape obtained by cutting the sphere by a pair of planes parallel to each other. A curved surface shape (both are aspherical surfaces in the example in the figure) formed by transfer materials 52 and 53 onto which the transfer surface shape has been transferred from a molding die (not shown) formed as a transfer surface shape. Has become.
[0045]
In the state shown in FIG. 5A, anisotropic physical etching is performed on the transfer material 51 and the device materials 52 and 53, and the surface shapes of the transfer materials 52 and 53 are engraved on the device material 51. An optical device 5A as shown in FIG. 5B can be obtained. If a transparent material is used as the device material, the optical device 5A can be used as a lens or a micro lens having both aspheric surfaces.
[0046]
When the aspherical surface made of the transfer material is formed only on one plane portion of the device material 51, the obtained optical device can be used as a lens or microlens having a plano-convex or plano-concave shape and an aspherical curved surface. .
[0047]
In FIG. 5A, the device material 51 can be obtained if the device material 51 has a shape obtained by cutting a part of a long cylinder in a direction perpendicular to the drawing by a pair of planes parallel to the axis and parallel to each other. The optical device can be used as a cylinder lens or a micro cylinder lens having a predetermined curved surface on both surfaces (claim 8).
[0048]
FIG. 6 shows the optical device material of the present invention.Another exampleAre shown as three examples.
The optical device material 60 shown in FIG. 6A has a configuration in which a predetermined convex curved surface shape is formed by a transfer material 62 on a planar surface of a prism-shaped device material 61.Claim 11 is an example of the material for an optical device. The optical device material 70 shown in FIG. 4B is obtained by forming a curved surface shape by transfer materials 72 and 73 on the surface of a spherical or cylindrical device material 71.Claims 2 and 3Of materials for optical devicesOne caseIt is. The optical device material 80 shown in FIG. 3C is a material in which a predetermined curved surface shape is formed by transfer materials 82 and 83 on both surfaces of a lens-shaped device material 81.Claims 2 and 4Of materials for optical devicesOne caseIt is.
[0049]
The optical device obtained by physically etching the device material and the transfer material of these optical device materials and engraving the surface shape of each transfer material on the device material will have any form. This will be apparent in light of the above description.
[0050]
FIGS. 7 and 8 show an example in which a plurality of “optical communication couplers (high-efficiency coupling module of LD and optical fiber)” as optical devices are “manufactured simultaneously”.
Since optical devices for optical communication are required to have severe environmental resistance, a glass material having excellent environmental resistance is required. In this example, the optical communication coupler to be manufactured is a “biconvex lens”, and each lens surface is “aspheric”.
[0051]
In FIG. 7A, reference numeral 1 indicates a “sphere” made of glass. A plurality of spheres 1 of the same shape are fixed and held in a dedicated jig 2 in a one-dimensional or two-dimensional array. The size (diameter) and material of the sphere 1 at this time are determined by design according to the size, optical performance, and the like of the final target optical device (coupler for optical communication).
[0052]
The dedicated jig 2 is manufactured so that the thickness of one side of the biconvex lens can be easily increased in consideration of the post-process as well as fixing the glass sphere 1. In other words, for this purpose, the portion at the center of the sphere 1 indicated by the “dashed line” is set close to the upper surface of the jig 2. Also, both surfaces of the jig 2 satisfy the required processing accuracy so that the optical surface of the finally formed biconvex lens is not damaged and the optical axis can be secured. The jig 2 may also serve as a lens holder (barrel) for a biconvex lens to be manufactured.
[0053]
FIG. 7B illustrates a state in which a reference plane 110 on the first surface side of the “biconvex lens” to be manufactured is formed by planar processing based on the result of the optical design. This planar processing can be performed by “normal glass surface planar polishing”.
The planar processing is performed by collectively planar polishing the first surface side of the plurality of spheres 1 together with the jig 2, and the “polishing amount” is set based on the result of the optical design.
[0054]
FIG. 7 (c) shows an aspherical shape 310 of a mold 300A, which is a "mold" manufactured in advance based on the result of the optical design, on the second surface side of the spherical body 1 (the first surface side is flattened). (A lower spherical portion in the figure). The aspheric surface 310 of the mold 300A can be manufactured by applying a micromachining technology using ultraprecision machining or photolithography technology.
[0055]
The material of the mold 300A is not particularly limited, but in consideration of a later peeling step, the portion of the aspherical surface 310 is subjected to “treatment for enhancing peelability”, for example, “fluorine plasma treatment” or the like. It is desirable to keep.
[0056]
FIG. 7D shows a plane of the spherical body 1 in a photocurable material 400 quantitatively sandwiched as a “transfer material” between the aspherical surface 310 of the mold 300A and the spherical surface on the second surface side of the spherical body 1. The state where the photocurable material 400 is cured by irradiating ultraviolet rays 410 from the processed side is shown. The curing of the photocurable material 400 may be performed by “irradiation of ultraviolet rays only” as described above, or “curing by heating” may be performed after precuring is performed by ultraviolet rays.
[0057]
As the transfer material, a “thermoplastic material” may be used instead of the photo-curable material 400, however, in the vicinity of room temperature so that an excessively high temperature does not act on the mold 300A or the sphere 1 during the heat curing. Preferably, the resin cures at a relatively low temperature (200 ° C. or lower).
[0058]
When the photocurable material 400 is cured, the photocurable material 400 is separated from the aspheric surface 310 of the mold 300A. The peeling is easy if the above-described fluorine plasma treatment or the like is performed on the mold 300A, but may be performed by a physical method such as “heat shock”.
[0059]
Thus, the predetermined aspherical surface is formed by the photocurable material 400 as the transfer material on the surface of the spherical body 1 as the device material having the predetermined curvature. Therefore, the “combined body of the sphere 1 and the photocurable material 400” in the state of FIG.Claim 2Of "materials for optical devices"One caseIt has become.
[0060]
FIG. 7E shows the photo-curable material 400 as the “transfer material” and the sphere 1 as the “device material” in the “optical device material” formed as described above at the stage of FIG. An anisotropic physical etching is performed on the second surface side and the aspherical shape formed as the surface shape of the photocurable material 400 is engraved on the second surface side of the spherical body 1. I have. Reference numeral 130 indicates the “engraved aspherical shape”.
[0061]
The physical etching is desirably performed by dry etching such as RIE or ECR plasma etching.
[0062]
FIG. 8 (f) (in order to clarify that this is a step following FIG. 7 (e), is referred to as (f)). A state is shown in which the side plane 110 faces downward and faces the aspherical surface 510 formed on the mold 500.
[0063]
The mold 500 is manufactured in advance based on an optical design, separately from the mold 300A in FIG. 7C. The method of manufacturing the mold 500 is the same as the method of manufacturing the mold 300A.
[0064]
FIG. 8G quantitatively sandwiches the photocurable material 400 as a transfer material between the aspherical surface 510 of the mold 500 and the flat surface 110 of the sphere 1, and irradiates with ultraviolet rays 410 to cure the material. The state is shown.
When the photocurable material 400 is cured, the photocurable material 400 is separated from the mold 500. In this manner, a convex shape made of the photocurable material 400 is formed on the flat surface 110 of the sphere 1. Therefore, at this stage,Claim 1 or claim 3This means that “material for optical device” was obtained.
[0065]
FIG. 8H shows that the photocurable material 400 of the optical device material thus obtained and the plane 110 of the sphere 1 are etched by an anisotropic physical etching method. The surface shape (convex aspherical surface corresponding to the aspherical surface 510 of the mold 500) of the photocurable material 400 is shown in an engraved state. Reference numeral 150 indicates an engraved “aspherical shape”.
Steps (f), (g), and (h) in FIG. 8 are the same as steps (c), (d), and (e) in FIG.
[0066]
In this manner, a plurality of lenses 1A (couplers for optical communication) whose first surface and second surface are both aspherical can be manufactured at once using the sphere 1 as a "starting material".
[0067]
The lens 1A, which is a completed optical device, may be removed from the jig 2 as necessary, and may be used as individual optical devices, or the entire lens may be used as a lens array while being held by the jig 2. Is also good.
[0068]
The "anisotropic etching" in the steps of FIG. 7E and FIG. 8H is based on the ratio of the etching rate of the ball lens material to the etching rate of the photosensitive material according to the result of the optical design. A certain selectivity may be shifted from 1, or may be changed during etching. When the selection ratio is not 1 or the selection ratio is changed in the middle, the transfer surface shapes of the curved surfaces 300A and 500 of the mold need not be aspherical shapes, and may be spherical shapes. That is, it is important to appropriately form a predetermined curved surface shape on the surface of the device material, which is a starting material, with a transfer material using a molding die.
[0069]
The “etching conditions” such as the selectivity can be easily changed by physical etching by adjusting the pressure in the reaction chamber, the type of the introduced gas, the substrate temperature (the temperature of the optical device material), and the like. In physical dry etching, the surface shape before etching was deformed by engraving the above surface shape at a selectivity of 1 from the surface shape before etching, or by shifting the selectivity from 1 or changing it during the etching. When a desired surface shape is formed, "reproducibility", that is, realization of a target shape is extremely high.
[0070]
FIG. 9 shows an example in which the lens 1A manufactured as described above is used as an optical communication coupler. In this case, a micro-optical element for coupling one channel “between the LD 600 and the optical fiber 610” is shown. Reference numeral 200 indicates a lens holder.
[0071]
Example 1
A lens whose first surface is spherical and whose second surface is aspheric was designed as an optical communication coupler. The effective beam diameter is 1.6 mm and the coupling efficiency is 58%. Based on the design results, the lens as an optical device was manufactured as follows.
[0072]
Material: SF60 (having a refractive index of 1.78278 with respect to infrared light having a wavelength of 0.83 μm) and a sphere having a diameter of 3.0 mm were prepared as a device material.
This sphere was fixed to a jig as described with reference to FIG.
[0073]
On a second surface side of a sphere which is a device material, a curved surface shape was formed by a transfer material obtained by transferring an aspherical shape from a molding die to obtain a material for an optical device.
A mold as a molding die was manufactured by performing a super precision processing and a photolithography process on a metal material to form a predetermined transfer surface shape.
In the transfer surface shape, the “aspherical shape” finally formed on the surface of the device material is a well-known aspherical formula:
Z = Ch^Two/ [1 + √ ｛1- (K + 1) C^Twoh^Two｝] + Ah^Four+ Bh⁶
C = 1 / R (curvature on optical axis)
K: conical constant
A, B: aspherical constant (A is a fourth-order term, B is a sixth-order term)
Z: distance from lens vertex
, K = −0.9995306, A = −0.8403612 × 10^-2, B = 0.2488880 × 10^-1, C = −1 / (1.5000 mm), and formed in a mold.
[0074]
In addition, plasma fluorine treatment (Ar, CF_FourWas introduced to increase the mold release property. As a surface treatment instead of the plasma fluorine treatment, "fluorine water generation treatment with an organic substance (fluorine derivative substance of triazinethiol)" is also effective.
[0075]
As a transfer material, an "anaerobic ultraviolet curable material" in which an acrylic material: 9 is blended with an epoxy material: 1 is used, and the transfer surface shape is transferred as described with reference to FIG. Was done. Curing of transfer material is 2500mJ / cm^TwoUV irradiation was performed from the side of the sphere at an energy density of. At this time, if necessary, post-baking may be performed at 120 ° C. for 30 minutes.
[0076]
After the transfer material is cured, the mold and the transfer material are separated. Of course, the transfer material adheres to the sphere with sufficient adhesion by "surface treatment with a silane coupling agent or the like" applied to the sphere surface. At the time of this peeling, it could be easily peeled off by the surface treatment effect of the transfer surface shape portion of the mold. At the time of peeling, if an action such as heat shock is applied, the peeling can be more easily performed.
Thus, the "material for optical device" as described with reference to FIG. 2A is obtained.
[0077]
Subsequently, the optical device material is set in an ECR plasma etching apparatus while being held by a jig, and Ar, CHF_Three, O_TwoIntroduce gas, 3-5 × 10^-Four"Anisotropic etching" was performed for 420 minutes under the condition of Toor, and the surface shape of the transfer material was directly engraved on the sphere surface. The selection ratio at this time is 1.
[0078]
FIG. 10 shows a state in which the lens which is the optical device thus obtained is used as an optical communication coupler. The left side of the figure is the LD side as the light source, and the right side is the optical fiber side. The optical device has a spherical surface on the first surface side (light source side) and an aspherical surface on the optical fiber side.
[0079]
Under the condition that the full width at half maximum of the LD is 32 °, the distance between the LD and the first surface of the lens is 0.55 mm, and the distance between the second surface of the lens and the optical fiber is 8.75 mm, the coupling efficiency is 57%, almost as designed. Was obtained.
[0080]
In the above specific example, the glass sphere made of SF60 used as a device material can itself be used as a “ball lens”. FIG. 12 shows a state in which this ball lens is used as an optical communication coupler. The left side of the figure is the light source side, and the right side is the optical fiber side. The “coupling efficiency” in this case was 15%.
[0081]
Example 2
As a second specific example of the optical device, a case will be described in which a lens whose both surfaces are aspherical is used as an optical communication coupler.
The design conditions are that the effective light beam diameter of the first surface is 0.66 mm, the effective light beam diameter of the second surface is 1.82 mm, and the coupling efficiency is 77.7%.
As a starting material for the production process, a sphere having a material: SF60 and a diameter of 3.0 mm was used as in the specific example 1 above.
[0082]
A sphere as a device material is fixedly held on a jig, and a mold (which has been subjected to a fluorine water emitting treatment with an organic substance) in which a transfer surface shape is previously formed into a target aspherical shape on the first surface side, The anaerobic UV-curable material is applied quantitatively as a transfer material, and the sphere held by the jig is arranged so as to sandwich the UV-curable material, and the transfer material is sandwiched between the mold and the sphere.
[0083]
In this state, in order to cure the transfer material, ultraviolet light is applied at 2500 mJ / cm.^TwoIrradiation at an energy density of At this time, if necessary, post-baking may be performed at 120 ° C. for 30 minutes in the above state. After the resin is cured in this way, when the mold and the transfer material are separated, the optical device material described with reference to FIG. 2A is obtained.
[0084]
Subsequently, while holding the optical device material in the jig, the material was set in an ECR plasma etching apparatus, and Ar, CHF_Three, O_Two3-5 × 10^-FourAnisotropic physical etching is performed for 100 minutes under the condition of Toor (selection ratio: 1), and the aspherical shape of the transfer material surface is directly engraved on the first surface side of the sphere.
[0085]
In the same process, an aspherical shape is formed on the second surface by the transfer material, and the optical device material thus obtained is anisotropically treated for 480 minutes under the same conditions as the first surface. Physical etching was performed, and the aspherical shape of the transfer material surface was directly engraved on the second surface side of the sphere. In this way, an optical device was obtained as a lens having both a first surface and a second surface having an aspherical surface.
[0086]
The aspherical surface formed on the first surface and the second surface side is
Regarding the aspheric surface of the first surface, C = 1 / (1.5000 mm), K = −0.266972 × 10^Two, A = B = 0
Regarding the aspheric surface of the second surface, C = −1 / (1.5000 m), K = −0.99
96278, A = −0.8063241 × 10^-2, B = 0
The transfer surface shape in each mold was formed based on this data.
[0087]
FIG. 11 shows a state in which the lens thus obtained is used as a coupler for optical communication, in a manner similar to FIG. The coupling efficiency (full width at half maximum of LD: 32 °) measured in the illustrated state was 75%, which was almost as designed.
[0088]
Modified example
In the specific example 2, the first and second surfaces are each formed by forming an aspheric surface on a spherical surface of a sphere using a transfer material and then engraving the sphere by physical etching.
In a modified example described below, a part of a sphere is flattened by polishing as a first surface side, and then a curved shape is formed on the flattened portion by a transfer material. The transfer material is a “mold having a transfer surface shape according to the target aspherical shape on the first surface side (the transfer surface shape is the same as the mold for the first surface side in the specific example 2 above, The shape of the portion is different. That is, the effective diameter: φ0.6 mm, the mold shape is the same. The transfer surface shape portion is subjected to fluorine water generation treatment with an organic substance. Transcribed.
[0089]
After that, in the ECR plasma etching apparatus, Ar, CHF_Three, O_Two3-5 × 10^-FourAnisotropic physical etching was performed for 500 minutes under the condition of Toor (selection ratio: 1), and the surface shape of the transfer material was directly transferred to a sphere. The shape creation of the second surface was performed in exactly the same manner as in Example 2.
[0090]
The difference between this modified example and the specific example 2 lies in the method of processing the first surface. Due to the difference in processing method, besides the optical path length is different, the etching margin (dimension) at the time of etching is different.
A smaller processing dimension is a better processing method because the processing time is shorter and can be realized at lower cost. In the above specific example 2 (method for processing from a spherical shape), the processing size is 5 μm and the etching time is 100 minutes. In the modified specific example (method for processing from a planar shape), the processing size is 25 μm and the etching time is 500 minutes. Therefore, the specific example 2 is a more excellent processing method.
[0091]
In the material for an optical device according to the first aspect, instead of forming a convex curved surface shape with a transfer material on a planar surface portion of the device material, a transfer material (a photocurable material or a temperature of 200 ° C. or lower) is used. It is also possible to consider a material for an optical device formed by a molding die with at least one accurate concave curved surface shape by using a thermosetting material that cures). Physical transfer etching and device material in such an optical device material are physically etched. It should be noted that an optical device having one or more desired concave curved shapes can be obtained by engraving the concave curved shapes into a device material.
[0092]
【The invention's effect】
As described above, according to the present invention, a newOptical device manufacturing method (claims 1 to 10), optical device (claims 11 and 12)Can be provided.
[0093]
In the method of manufacturing an optical device according to the present invention, a curved surface shape corresponding to a target surface shape is first accurately formed as a surface shape of a transfer material by using a mold, and thereafter, a different shape having excellent target shape realizability is obtained. Since the device material is engraved by isotropic physical etching, a desired surface shape can be accurately formed on the device material, and an optical device having excellent optical performance can be manufactured. Further, this manufacturing method can be implemented to manufacture a large number of optical devices at once, as in the example described with reference to FIGS. 7 and 8, and the efficiency of manufacturing can be improved. .
[0094]
Also,Optical device material used in the optical device manufacturing method of the present inventionSince the device material has a curved surface shape corresponding to a desired surface shape formed by a transfer material, a desired optical device can be realized only by etching the device material by anisotropic physical etching. Also, by making the surface of the device material a spherical surface, a cylindrical surface, a lens surface, a flat surface, and the like, the device material can be obtained at a low cost, and by selecting the surface shape according to the design result of the optical device. In addition, the amount of etching can be reduced to shorten the etching time, which is suitable for mass production. That is, by setting the surface shape of the device material to a spherical shape or the like, it is possible to perform etching from a target shape, for example, a shape approximate to an aspherical shape, and it is possible to reduce the amount of etching and shorten the etching time.
[0095]
Claim 9In the materials for optical devices described above, a “photo-curable material” or a “thermo-curable material that cures at a temperature of 200 ° C. or less” is used as a transfer material. Since there is no need to apply excessive heat and pressure to the mold and device material, the mold and device material have a wide degree of freedom including plastic, and there is almost no damage to the mold by heat or pressure. The life of the mold is long and the cost can be reduced.
[0096]
The optical device of the present invention is manufactured by the above-mentioned optical device manufacturing method using the above-mentioned optical device material, so that “variation” between devices is small, and good optical characteristics can be achieved by an accurate curved surface shape. .
[Brief description of the drawings]
FIG.An example (a) of the material for an optical device according to claim 1, and an optical device manufactured therefrom.(B) for explaining FIG.
FIG. 2An embodiment (a) of the material for an optical device according to claim 2, and an optical device manufactured therefrom.(B) for explaining FIG.
FIG. 35. An embodiment (a) of the material for an optical device according to claim 2, and an optical device manufactured therefrom.(B) for explaining FIG.
FIG. 4An embodiment (a) of the material for an optical device according to claim 2, 5 or 7, and an optical device manufactured therefrom.(B) for explaining FIG.
FIG. 5An embodiment (a) of the material for an optical device according to claim 2, 6, or 8, and an optical device manufactured therefrom.(B) for explaining FIG.
FIG. 6Optical device material used in the optical device manufacturing method of the present inventionIt is a figure which shows the other example of 3 examples.
FIG. 7 is a diagram for explaining one embodiment of the optical device manufacturing method of the present invention.
FIG. 8 is a diagram for explaining the embodiment.
FIG. 9 is a diagram for explaining a use state of the optical device (coupler for optical communication) manufactured in the above embodiment.
FIG. 10 is a diagram for explaining the optical performance of the optical device (optical communication coupler) of Example 1.
FIG. 11 is a view for explaining the optical performance of the optical device (coupler for optical communication) of Example 2.
FIG. 12 is a diagram for explaining a comparative example with respect to the specific example 1.
[Explanation of symbols]
10 Materials for optical devices
11 Device materials
12 Transfer material
300 Mold

Claims (12)

Using a mold having a concave curved surface shape corresponding to a predetermined convex curved surface shape, one or more convex curved shapes are formed on the planar surface of the device material by a transfer material onto which the convex curved shape has been transferred. Optical device material , by performing anisotropic physical etching on the transfer material and the device material, by engraving the convex curved shape of the transfer material on the device material, from the device material An optical device manufacturing method comprising manufacturing an optical device. One or more curved surfaces are formed on a surface of a device material having a predetermined curvature by using a transfer material on which the transfer surface shape is transferred from a mold having a predetermined curved surface shape formed as a transfer surface shape. By performing anisotropic physical etching on the transfer material and the device material of the optical device material, engraving one or more curved shapes of the transfer material on the device material, An optical device manufacturing method comprising manufacturing an optical device made of a material. An optical device manufacturing method according to claim 2,
  An optical device manufacturing method, wherein a material for an optical device having a spherical or cylindrical body is used. An optical device manufacturing method according to claim 2,
  An optical device material characterized by using a device material in which the device material is formed into a lens shape. A part of a sphere is processed into a plane, and a part of a sphere is cut in a plane. By performing anisotropic physical etching on the transfer material and the device material of the optical device material having a curved shape formed by the transferred transfer material, the curved shape of the transfer material is reduced. An optical device manufacturing method, wherein an optical device made of the device material is manufactured by engraving the device material. A predetermined curved surface shape is formed as a transfer surface shape on at least one of the planar portions of a device material in which a part of the sphere is formed into a plane by cutting a part of the sphere by a pair of parallel planes. By performing anisotropic physical etching on the transfer material and the device material of the optical device material having the curved surface shape formed by the transfer material obtained by transferring the transfer surface shape from the molding die. An optical device manufacturing method, wherein an optical device made of the device material is manufactured by engraving the curved shape of the transfer material on the device material. A molding die in which a predetermined curved surface shape is formed as a transfer surface shape in a planar portion of a device material in which a peripheral surface portion of a cylindrical body is processed into a plane and a part of the cylinder is cut along a plane parallel to an axis. By performing anisotropic physical etching on the transfer material and the device material of the optical device material having the curved surface shape formed by the transfer material transferred from the transfer surface shape , An optical device manufacturing method, wherein an optical device made of the device material is manufactured by engraving a curved surface shape of a transfer material on the device material. A predetermined curved surface is formed on at least one planar portion of a device material in which a peripheral surface portion of a cylindrical body is formed into a plane and a part of the cylinder is cut by a pair of planes parallel to an axis and parallel to each other. An optical device material having a curved surface shape formed by a transfer material having the transfer surface shape transferred from a molding die having a transfer surface shape formed thereon is anisotropic with respect to the transfer material and the device material. An optical device made of the device material by engraving the curved surface shape of the transfer material on the device material by performing physical etching of the transfer material. The optical device manufacturing method according to claim 1, 2 or 3 or 4 or 5 or 6 or 7 or 8,
An optical device manufacturing method, wherein a photocurable material or a thermosetting material that cures at a temperature of 200 ° C. or lower is used as a transfer material for an optical device material . The optical device manufacturing method according to claim 1, 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9,
  An optical device manufacturing method, wherein a transparent optical material is used as a device material of an optical device material. An optical device manufactured by the optical device manufacturing method according to claim 1, 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9 or 10. An optical device comprising the optical device according to claim 11, wherein a reflective film is formed on a curved surface portion.

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