US20060092516A1 - Method for producing multilayer optical device - Google Patents

Abstract

A film of aluminum2is formed on a glass substrate (BK7)1by vacuum evaporation, and a multilayer optical thin film3is formed by an ion sputtering method on this aluminum film2.Afterwards, such a member is cut into small pieces by means of dicing, and the aluminum2is then etched by a sodium hydroxide solution, so that the glass substrate1and the multilayer optical thin film3are separated. When the aluminum thickness exceeds 90 nm, clouding occurs in the multilayer optical thin film3,and when the aluminum thickness is less than 10 nm, the separation of the glass substrate and multilayer optical thin film cannot be performed cleanly. Accordingly, the aluminum thickness is set in a range of 10 to 90 nm.

Description

• This is a continuation from PCT International Application No. PCT/JP2004/008835 filed on Jun. 17, 2004, which is hereby incorporated by reference.
TECHNICAL FIELD
• The present invention relates to a method for manufacturing a multilayer film optical element that is formed by laminating thin films consisting of substances having different refractive indices.
BACKGROUND ART
• An optical element that is provided with specified optical characteristics such as filtering by laminating thin films consisting of substances with different refractive indices and utilizing interference of light reflected at the boundaries of the thin films is known as a multilayer film optical element, and is used in an interference filter or the like.
• Such a multilayer film optical element has a structure in which thin films of nonmetal optical substances with different refractive indices are successively superimposed on a substrate consisting of glass or the like, and is ordinarily formed by successive film formation of these nonmetal optical substances on a substrate consisting of glass or the like by means of vacuum evaporation.
• In such an optical element, not only does the substrate consisting of glass or the like play no role in determining the optical characteristics, but it also absorbs light, so that it is necessary that the substrate be as thin as possible. Accordingly, such substrates have conventionally been polished following the multilayer film formation to keep the thickness down to approximately several tens of microns.
• However, it is extremely difficult to polish a substrate consisting of glass or the like to a thickness of approximately several tens of microns, and there is a problem in that the yield is lowered due to damage to the glass during polishing.
• A multilayer film optical thin film that does not have a substrate as described, for example, in Japanese Patent Application Kokai No. H3-196001, has been publicly known as an optical element that solves such a problem.
• Such a multilayer film optical thin film is manufactured as follows: For example, aluminum is deposited on a glass substrate, and silicon oxide thin films and titanium oxide thin films are alternately formed on top of this by means of ion sputtering. If the aluminum is dissolved by an aluminum etching liquid at the completion of the film formation, the glass substrate and the multilayer optical thin film are separated, so that a multilayer optical thin film having no glass substrate can be obtained.
• However, as a result of the experiments conducted by the inventor, it was found that there are major problems in the method for manufacturing a multilayer optical thin film of the type described in Japanese Patent Application Kokai No. H3-196001. That is to say, in cases where a multilayer optical thin film is formed by ion sputtering or the like, projections and indentations are produced at the interface between the aluminum and multilayer optical thin film; as a result, the multilayer optical thin film is clouded, leading to a significant drop in the transmissivity of light, so that such an optical thin film cannot withstand practical use. Aside from this, it was also found that aluminum does not adequately play a role as a carrier, so that the problem of incomplete separation of the glass substrate and multilayer optical thin film was encountered.
DISCLOSURE OF THE INVENTION
• The present invention was devised in light of such circumstances; it is an object of the present invention to provide a method for manufacturing a multilayer film optical element which makes it possible to prevent the clouding in the multilayer optical thin film and to cleanly separate the glass substrate and multilayer optical thin film.
• The first invention that is used to achieve the object described above is a method for manufacturing a multilayer film optical element including steps of forming a thin film of a soluble on a substrate, forming a multilayer optical thin film on top of this soluble, and subsequently dissolving the thin film of the soluble so that the substrate and the multilayer optical thin film are separated, wherein the soluble is aluminum, and the thickness of this soluble is set at 10 to 90 nm.
• As a result of investigation of the causes of clouding of a multilayer optical thin film as described above, the present inventor ascertained that recrystallization of aluminum constituting the soluble occurs due to the heat generated when the multilayer optical thin film is formed by ion sputtering; as a result, projections and indentations are created at the interface between the aluminum and multilayer optical thin film, which results in the generation of clouding. When the inventor continued further investigation, it was discovered that the state of this unevenness varies according to the thickness of the aluminum layer, and that if the thickness of the aluminum layer is 90 nm or less, problematic clouding does not occur.
• The present inventor also found that the reason that the separation of the substrate and optical thin film cannot be accomplished cleanly is that if the thickness of the aluminum layer is excessively small, portions where no aluminum layer is formed are generated, and that there are cases in which the substrate and multilayer thin film are directly bonded in these portions. After much experimentation, it was discovered that as long as the thickness of the aluminum layer is 10 nm or more, such a problem does not occur.
• Accordingly, in the present invention, the thickness of the aluminum layer serving as a soluble is limited to a range of 10 to 90 nm. Here, the thickness refers to an average value.
• The second invention that is used to achieve the object described above is the first invention, wherein the step of forming the multilayer optical thin film is an ion sputtering step.
• In cases where the multilayer optical thin film is formed by ion sputtering, the temperature elevation of the aluminum layer is especially great, so that the effect of the first invention is particularly large.
• The third invention that is used to achieve the object described above is the first invention or second invention, wherein the multilayer optical thin film consists of alternately laminated niobium pentoxide thin films and silicon oxide thin films, and the substance in the film formed directly above the soluble is silicon oxide.
• In cases where an optical thin film is formed by laminating niobium pentoxide thin films and silicon oxide thin films, if a film of niobium pentoxide is formed on aluminum, the elevation of temperature causes the niobium pentoxide and aluminum to react, so that aluminum oxide is formed. Since aluminum oxide is not dissolved by a substance that dissolves aluminum, the peeling characteristics of the substrate and multilayer optical thin film deteriorate. In contrast, if a film of silicon oxide is formed directly above aluminum, such a problem can be prevented.
• The fourth invention that is used to achieve the object described above is a multilayer film optical element in which layers having different refractive indices are alternately formed, and the substrate is removed during manufacture, wherein the surface roughness of the optical surfaces of the multilayer film optical element is 3 nm or less in terms of Ra.
• With the present invention, a filter without a substrate which is such that Ra is 3 nm or less can be acquired for the first time, so that a filter that has extremely low loss with respect to transmitted light can be provided.
BRIEF DESCRIPTION OF THE DRAWINGS
• FIG. 1 is a diagram that is used to illustrate a method for manufacturing a multilayer optical thin film in an embodiment of the present invention.
BEST MODE FOR CARRYING OUT THE INVENTION
• As is shown inFIG. 1, a film ofaluminum 2 was formed on a glass substrate (BK7)1 by means of vacuum evaporation, and a multilayer opticalthin film3 consisting of a structure shown in Table 1 and having a total film thickness of approximately 30 μm was formed by an ion sputtering method on this aluminum film2 (the description of the 7th layer to the 107th layer is omitted since the odd-number layers are the same as the fifth layer and the even-number layers are the same as the sixth layer). Afterwards, such a member was cut into small pieces by means of dicing, and thealuminum2 was then etched by an NaOH solution, so that theglass substrate1 and the multilayer opticalthin film3 were separated. A substrate in a mirror surface state was used as theglass substrate1, and the surface roughness was 0.2 to 0.4 nm in terms of Ra.

  TABLE 1
  			Film thickness
  Layer No.	Substance	Refractive index	(nm)

  1	SiO2	1.46	265
  2	Nb2O5	2.23	336
  3	SiO2	1.46	215
  4	Nb2O5	2.23	135
  5	SiO2	1.46	215
  6	Nb2O5	2.23	123
  . . .	. . .	. . .	. . .
  . . .	. . .	. . .	. . .
  . . .	. . .	. . .	. . .
  108	Nb2O5	2.23	170
  109	SiO2	1.46	253
  110	Nb2O5	2.23	174
  111	SiO2	1.46	265

• Table 2 shows the relationship between the occurrence of clouding in the multilayer opticalthin film3 obtained, the peeling characteristics of the multilayer opticalthin film3 andsubstrate1, and the thickness of the aluminum.

  TABLE 2
  Al thickness	Clouding	Peeling characteristics
  5 nm	Absent	Impossible
  10 nm	Absent	Good
  90 nm	Absent	Good
  100 nm	Present	Good

• It is seen from the results in Table 2 that if the aluminum thickness is 10 to 90 nm, no clouding occurs in the multilayer optical thin film, and the separation characteristics of the multilayer optical thin film and substrate are good. Furthermore, the surface roughness on the aluminum side of the multilayer optical thin film was 0.4 nm in terms of Ra when the aluminum thickness was 90 nm, and was 1 nm in terms of Ra when the aluminum thickness was 100 nm. Moreover, the etching time was 40 hours when the aluminum thickness was 10 nm, but when the aluminum thickness was 5 nm, complete peeling was not possible.
• Next, the roughness of the multilayer optical thin film formed on the aluminum layer with a surface roughness Ra of 0.4 nm was measured. As a result of this measurement, it was found that the surface roughness of the frontmost layer on the side opposite from the side of the aluminum layer was 3 nm. In general, in the film formed by a vacuum evaporation method, the surface roughness of the film increases as the total film thickness increases.
• However, in the multilayer optical thin film in the embodiment of the present invention, not only is clouding not confirmed by visual observation, but a surface roughness comparable to that of a conventional filter having a substrate can also be achieved even on the surface whose roughness is thought to be the highest.
• Incidentally, both the surface on the side of the aluminum layer and the surface of the frontmost layer on the side opposite from the side of the aluminum layer become optical surfaces through which light beams pass. By achieving an extremely small degree of roughness on the optical surfaces, the effect of lowering loss that is required in filters used for optical communications is further expanded. Furthermore, the surface roughness Ra in this embodiment is obtained by measuring a 10 μm×10 μm region by means of an atomic force microscope.
• Thus, since the surface roughness of a filter with no substrate is 3 nm or less in terms of Ra within a 100 μm²range, a filter with no substrate having little loss with respect to the transmitted light can be obtained.
• Next, multilayer optical thin films were formed using a method similar to the method described above, but without forming the first layer film shown in Table 1, so that an Nb₂O₅thin film was formed on the aluminum, with the aluminum thickness being set at 10 nm and 90 nm, respectively.
• As a result, in either case, etching by means of an NaOH solution did not work well, and the peeling characteristics of the substrate and multilayer optical thin film were poor, so that it was impossible to obtain a multilayer optical thin film that can withstand practical use.

Claims (5)

1. A method for manufacturing a multilayer film optical element comprising forming a thin film of aluminum having a thickness of 10 to 90 nm on a substrate, forming a multilayer optical thin film on said aluminum thin film, and subsequently dissolving said aluminum thin film so that the substrate and the multilayer optical thin film are separated.

2. The method for manufacturing a multilayer film optical element according toclaim 1, wherein said multilayer optical thin film is formed by ion sputtering.

3. The method for manufacturing a multilayer film optical element according toclaim 1, wherein said multilayer optical thin film consists essentially of a plurality of alternate layers of niobium pentoxide thin film and silicon oxide thin films, and a silicon oxide thin film is positioned directly on said aluminum thin film.

4. The method for manufacturing a multilayer film optical element according toclaim 2, wherein said multilayer optical thin film consists essentially of a plurality of alternate layers of niobium pentoxide thin film and silicon oxide thin film, and a silicon oxide thin film is positioned directly on said aluminum thin film.

5. A multilayer film optical element in which layers having different refractive indices are alternately formed, and the substrate is removed during manufacture, wherein the surface roughness of the optical surfaces of the multilayer film optical element is 3 nm or less.

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