WO2010074127A1 - 圧電振動デバイス、圧電振動デバイスの製造方法、および圧電振動デバイスを構成する構成部材のエッチング方法 - Google Patents
圧電振動デバイス、圧電振動デバイスの製造方法、および圧電振動デバイスを構成する構成部材のエッチング方法 Download PDFInfo
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- WO2010074127A1 WO2010074127A1 PCT/JP2009/071401 JP2009071401W WO2010074127A1 WO 2010074127 A1 WO2010074127 A1 WO 2010074127A1 JP 2009071401 W JP2009071401 W JP 2009071401W WO 2010074127 A1 WO2010074127 A1 WO 2010074127A1
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- lid member
- bonding
- region
- lower lid
- upper lid
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- H03H9/1007—Mounting in enclosures for bulk acoustic wave [BAW] devices
- H03H9/1035—Mounting in enclosures for bulk acoustic wave [BAW] devices the enclosure being defined by two sealing substrates sandwiching the piezoelectric layer of the BAW device
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- H—ELECTRICITY
- H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
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- H01L31/18—Processes or apparatus specially adapted for the manufacture or treatment of these devices or of parts thereof
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- H10N30/06—Forming electrodes or interconnections, e.g. leads or terminals
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- C23C—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
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- C23C—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
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Definitions
- the present invention relates to a piezoelectric vibration device used in an electronic device or the like, a method for manufacturing the piezoelectric vibration device, and a method for etching a constituent member constituting the piezoelectric vibration device.
- a package having a structure in which a crystal vibrating piece is bonded to the inside of a box-shaped container body having an opening at the top, and then the opening is hermetically sealed with a lid is used. Yes.
- a ceramic fired body is generally used for the container body.
- Patent Documents 1 and 2 disclose a crystal resonator having a configuration in which a pair of crystal plates are sandwiched through the bonding material.
- the surfaces of the upper and lower lid bodies (a pair of the quartz plates) and the surfaces of the quartz diaphragm are mirror-finished, and the lid and the quartz diaphragm Are bonded by direct bonding (interatomic bonding).
- the equipment for performing interatomic bonding here is expensive, and the crystal resonators in Patent Document 1 and Patent Document 2 deteriorate the manufacturing cost.
- the surface of the upper and lower lids and the surface of the quartz crystal vibrating plate are bonded to the bonding material. It becomes difficult to obtain sufficient bonding strength.
- the present invention has been made in view of the above points, and improves the bonding strength between the bonding material and the constituent members constituting the piezoelectric vibration device, and suppresses the manufacturing cost.
- the piezoelectric vibration device manufacturing method It is another object of the present invention to provide an etching method for constituent members constituting a piezoelectric vibration device.
- a piezoelectric vibrating device includes a piezoelectric vibrating plate on which an excitation electrode is formed, and an upper lid member and a lower lid member that hermetically seal the excitation electrode.
- Each of the upper and lower main surfaces of the diaphragm has bonding regions with the upper lid member and the lower lid member, and one main surface of the upper lid member has a bonding region with the piezoelectric diaphragm, and the lower lid member Having a bonding region with the piezoelectric vibration plate on one main surface, and having a bonding region with an external member on the other main surface of the lower lid member, and the bonding region of the piezoelectric vibration plate and the upper lid member
- a bonding layer constituting a bonding material is formed in each of the bonding region and the bonding region of the lower lid member, and the bonding region of the piezoelectric diaphragm and the bonding region of the upper lid member are interposed via the bonding material.
- the piezoelectric diaphragm is bonded to the bonding region of the lower lid member. Bonded via the bonding material, at least one of the substrate of the bonding region of the piezoelectric diaphragm, the substrate of the bonding region of the upper lid member, and the substrate of the bonding region of the lower lid member is roughened It is characterized by being.
- another piezoelectric vibration device includes a piezoelectric diaphragm on which an excitation electrode is formed, and an upper lid member and a lower lid member that hermetically seal the excitation electrode.
- the main surface of the upper lid member has a bonding region with the lower lid member
- the main surface of the lower lid member has a bonding region with the upper lid member
- the other surface of the lower lid member is the other surface of the lower lid member.
- the main surface has a bonding region with an external member, and a bonding layer constituting a bonding material is formed in each of the bonding region of the upper lid member and the bonding region of the lower lid member, and bonding of the upper lid member
- the region and the bonding region of the lower lid member are bonded via the bonding material, and at least one of the substrate of the bonding region of the upper lid member and the substrate of the bonding region of the lower lid member is roughened It is characterized by being.
- the main surface of the lower lid member may have a bonding region with the piezoelectric diaphragm, and a surface of the bonding region with the piezoelectric vibration plate may be roughened.
- the main surface of the lower lid member has a joining region with the piezoelectric diaphragm, and the surface of the joining region with the piezoelectric diaphragm is roughened.
- the minute unevenness formed on the surface of the substrate functions like a “wedge” against the stress in the horizontal direction. That is, by having a so-called anchor (throwing) effect, it is possible to improve the bonding strength between the roughened surface of the bonding region and the piezoelectric diaphragm.
- the surface of the bonding layer formed on the roughened surface of the bonding region may be roughened.
- an electrolytic plating is further applied to the upper layer of the roughened bonding layer on the surface of the bonding region.
- the base material of the joining region of the piezoelectric diaphragm is roughened, and at least one of the base material of the joining region of the upper lid member and the base material of the joining region of the lower lid member is roughened.
- the surface of the base material of the joining region of at least one of the upper lid member and the lower lid member may be formed to be rougher than the surface of the base material of the joining region of the piezoelectric diaphragm.
- a rough surface is formed on at least one of the upper cover member and the lower cover member, rather than performing a roughening process on the piezoelectric diaphragm on which the excitation electrode or the like is formed.
- the roughening treatment process can be simplified by performing the roughening treatment.
- a metal film (electrode film) such as the excitation electrode is formed on the piezoelectric diaphragm, and it is necessary to protect the electrode film at the time of the roughening treatment, and further various thermal histories are added, The film state of the electrode film may be affected.
- the excitation electrode is not formed on the upper lid member and the lower lid member, the influence on various characteristics of the piezoelectric vibration device can be reduced, and the bonding region of the upper lid member can be reduced.
- the piezoelectric vibration device having good characteristics can be obtained in combination with the anchor effect on the bonding material.
- At least one of the joining regions of the upper lid member and the lower lid member is roughened, and the roughened joining region is more planar than the joining region of the piezoelectric diaphragm. And may be formed widely in the inner direction of the one main surface.
- the fillet of the bonding material is easily formed toward the bonding region (rough surface region) that is widely formed in at least one inner direction of the upper lid member and the lower lid member.
- At least one whole main surface of the upper lid member and the lower lid member may be roughened.
- the electrode electrically connected with the external connection terminal connected with an external apparatus
- the pattern is formed on at least one main surface side of the upper cover member and the lower cover member, if the entire main surface is roughened, the adhesion between the electrode pattern and the main surface is improved. Can be improved. Further, the surface roughening process is simplified and productivity is improved as compared with the case where only the surface where the electrode pattern is formed is selectively roughened.
- the bonding region of the piezoelectric diaphragm is roughened, and a plurality of bonding materials having different surface directions are disposed in the vicinity of at least one of the bonding regions of the upper lid member and the lower lid member.
- a multi-surface bonding portion that is bonded by a surface may be provided, and an expansion preventing portion that prevents an expansion of a bonding region with the bonding material may be provided outside the multi-surface bonding portion.
- the bonding material includes the multi-surface bonding portion and the expansion preventing portion. It is possible to prevent the upper cover member and the lower cover member provided from spreading on at least one joint surface (the one main surface) in the main surface direction (plane direction).
- the joint material is joined by a plurality of surfaces having different surface directions.
- the anchor effect can be generated and the bonding strength with the bonding material can be increased.
- the bonding material spreads (wet) in the bonding portion is a phenomenon that naturally occurs.
- the multi-surface joint portion is provided in the vicinity of at least one joint region of the upper lid member and the lower lid member, and the expansion preventing portion is provided outside the multi-surface joint portion. Therefore, even when the bonding material spreads at the bonding site after bonding by the bonding material, the bonding material flows (wet) to the end face of the piezoelectric vibration device. It is possible to prevent the bonding material from entering the internal space of the piezoelectric vibration device.
- a method of manufacturing a piezoelectric vibrating device includes a piezoelectric vibrating plate on which an excitation electrode is formed, and an upper lid member and a lower lid member that hermetically seal the excitation electrode. Provided on the front and back main surfaces of the piezoelectric diaphragm, each having a bonding region with the upper lid member and the lower lid member, and on one main surface of the upper lid member with a bonding region with the piezoelectric diaphragm.
- a main surface of the lower lid member has a bonding area with the piezoelectric diaphragm, and the bonding area of the piezoelectric diaphragm and the bonding area of the upper lid member are bonded via a bonding material.
- a method for manufacturing a piezoelectric vibration device in which a bonding region of a plate and a bonding region of the lower lid member are bonded via a bonding material, the substrate of the bonding region of the piezoelectric vibration plate, and the substrate of the bonding region of the upper lid member And at least the base material of the joining region of the lower lid member
- a metal film forming step of laminating a metal film made of at least two kinds of metals a diffusion step for promoting metal diffusion inside the metal film by heat treatment after the metal film forming step, and after the diffusion step And an etching step of roughening the substrate by forming a large number of micropores in the substrate surface by performing wet etching by infiltrating an etching solution into the metal film.
- the manufacturing method it is possible to partially form a rough surface on one main surface of a structural member having a surface state with very few irregularities as in mirror surface processing. Specifically, the region not desired to be roughened is protected by coating with a resist or the like, and the region desired to be roughened is not formed with a protective film such as a resist, but the metal film in which metal diffusion has occurred is provided. Then, a large number of the micropores are formed on the surface of the substrate by infiltrating the etching solution to the substrate of the member. Thereby, a selective roughening process becomes possible.
- the bonding strength between the bonding material and the constituent member of the piezoelectric vibration device can be improved, and the airtightness can be increased.
- it since it is not essential to perform interatomic bonding, it is possible to reduce the manufacturing cost of the piezoelectric vibration device.
- the thickness of the metal film may be varied in the above configuration.
- the amount of metal diffused by heat treatment can be controlled, and the perforation state of the micropores in the surface of the substrate can be controlled by the penetration of the etching solution into the metal film after the diffusion step. That is, the surface state of the rough surface can be controlled.
- the upper lid member and the lower lid member are made of crystal or glass, and the piezoelectric diaphragm is made of crystal.
- the metal film forming step the upper lid member, the lower lid member, and the piezoelectric member are formed.
- a Cr layer is formed on at least one of the substrates with a diaphragm, an Au layer is stacked on the Cr layer, the metal film is formed, and a two-layer configuration including the Cr layer and the Au layer is formed.
- the substrate may be roughened by forming a large number of micropores on the surface.
- the upper lid member and the lower lid member are made of quartz or glass and the piezoelectric diaphragm is made of quartz, it is easy to form an outer shape by wet etching.
- the metal film has a two-layer structure in which the Au layer is stacked on the Cr layer. With such a film configuration, for example, when quartz is used for the upper lid member and the lower lid member, the adhesion with the piezoelectric diaphragm can be improved. Further, since Au having resistance to the etching solution is used, the etching solution is not etched by the metal film without corroding the metal film even when wet etching is performed through the metal film in which the Cr is diffused. It can be penetrated to the base of the formed member. As a result, a large number of the micropores can be formed on the surface of the substrate under the metal film where the metal diffusion has occurred to be roughened.
- a method for etching a constituent member constituting the piezoelectric vibrating device is an etching method for a constituent member having each joining region with an external member on at least one main surface.
- the etching method it is possible to partially form a rough surface on at least one main surface of the constituent member having a surface state with very little unevenness as in mirror finishing. Specifically, the region not desired to be roughened is protected by coating with a resist or the like, and the region desired to be roughened is not formed with a protective film such as a resist, but the metal film in which metal diffusion has occurred is provided. Then, a large number of the micropores are formed on the surface of the substrate by allowing the etching solution to penetrate into the substrate of the constituent member. Thereby, a selective roughening process becomes possible.
- the piezoelectric diaphragm, the upper lid member, and the lower lid member are used as the constituent members, and the piezoelectric diaphragm is sandwiched between the upper lid member and the lower lid member via the bonding material.
- the bonding strength between the piezoelectric vibration plate and the bonding material, the bonding strength between the upper lid member and the bonding material, and the bonding strength between the lower lid member and the bonding material are improved.
- the manufacturing cost of the piezoelectric vibration device can be reduced.
- the bonding member and the constituent members constituting the piezoelectric vibration device (for example, The bonding strength of the piezoelectric vibrating piece, the upper lid member, and the lower lid member) can be improved, and the manufacturing cost of the piezoelectric vibrating device can be reduced.
- the cross-sectional schematic diagram along the long side direction of the crystal oscillator which shows the 1st Embodiment of this invention The schematic block diagram which showed each structural member of the crystal oscillator which shows the 1st Embodiment of this invention.
- the flowchart which shows the roughening process in the 1st Embodiment of this invention The schematic diagram which shows the roughening process in the 1st Embodiment of this invention.
- the schematic diagram which shows the roughening process in the 1st Embodiment of this invention. The schematic diagram which shows the roughening process in the 1st Embodiment of this invention.
- the schematic diagram which shows the roughening process in the 1st Embodiment of this invention The schematic diagram which shows the roughening process in the 1st Embodiment of this invention.
- the schematic diagram which shows the roughening process in the 1st Embodiment of this invention The schematic diagram which shows the roughening process in the 1st Embodiment of this invention.
- the schematic diagram which shows the roughening process in the 1st Embodiment of this invention The schematic diagram which shows the roughening process in the 1st Embodiment of this invention.
- the cross-sectional schematic diagram along the long side direction of the crystal resonator which shows the modification of the 1st Embodiment of this invention.
- the schematic block diagram which showed each structural member of the crystal oscillator which shows the modification of the 1st Embodiment of this invention.
- the schematic diagram which shows the roughening process in the modification of the 1st Embodiment of this invention The schematic diagram which shows the roughening process in the modification of the 1st Embodiment of this invention.
- the schematic diagram which shows the roughening process in the modification of the 1st Embodiment of this invention The schematic diagram which shows the roughening process in the modification of the 1st Embodiment of this invention.
- the cross-sectional schematic diagram along the long side direction of the crystal oscillator which shows the 2nd Embodiment of this invention The cross-sectional schematic diagram along the long side direction of the crystal oscillator which shows the 3rd Embodiment of this invention.
- the cross-sectional schematic diagram along the long side direction of the crystal oscillator which shows the 4th Embodiment of this invention The cross-sectional schematic diagram along the long side direction of the crystal oscillator which shows the 5th Embodiment of this invention.
- the cross-sectional schematic diagram along the long side direction of the crystal resonator which shows the modification of each embodiment of this invention The schematic plan view of the lower cover member of the crystal oscillator which shows the modification of each embodiment of this invention.
- FIG. 1 is a cross-sectional view of the crystal resonator 1 along the long side direction of the crystal diaphragm 2 showing the first embodiment
- FIG. 2 is a schematic diagram showing each component of the crystal resonator 1 shown in FIG. It is a block diagram.
- the crystal diaphragm 2 pieoelectric diaphragm in the present invention
- the excitation formed on one main surface 21 of the crystal diaphragm 2 constitute a main component member.
- the crystal unit 1 includes a crystal diaphragm 2 and a lower lid member 3 that are bonded together by a bonding material 5, and a crystal vibration plate 2 and an upper lid member 4 that are bonded together by a bonding material 5 to form a package 11. .
- a bonding material 5 a crystal vibration plate 2 and an upper lid member 4 that are bonded together by a bonding material 5 to form a package 11.
- the lower lid member 3 and the upper lid member 4 have substantially the same shape and substantially the same outer dimensions.
- the lower lid member 3 has an external connection terminal 34 formed on the bottom surface (other main surface) 37, and a conduction path (via) 35 electrically connected to the external connection terminal 34 is formed in the thickness direction.
- the main surfaces 31 and 37 are penetrated.
- the crystal diaphragm 2 is an AT-cut quartz plate cut out at a predetermined angle.
- the quartz crystal diaphragm 2 includes a vibrating portion 20 in a thin area where the excitation electrode 23 is formed, a bank portion 26 around the vibrating portion 20, a frame portion 28, and a thin portion 27, which are integrally formed.
- the frame portion 28 surrounds the vibrating portion 20 and the bank portion 26 in an annular shape, and is formed thicker than the vibrating portion 20 and the bank portion 26.
- the thin portion 27 is formed between the bank portion 26 and the frame portion 28 and is formed thinner than the bank portion 26.
- the crystal diaphragm 2 (vibrating part 20, bank part 26, thin part 27, frame part 28) is formed by wet etching, and excitation electrodes 23 are provided on the front and back surfaces (one main surface 21 and the other main surface 22) of the vibrating unit 20. Are formed by vapor deposition.
- the excitation electrode 23 is formed on the front and back main surfaces (one main surface 21 and the other main surface 22) of the vibration unit 20 in a Cr and Au film configuration in order from the bottom.
- membrane structure of the excitation electrode 23 is not limited to this, Other film
- an extraction electrode 24 is led out from the excitation electrode 23, and the extraction electrode 24 extracted from the other main surface 22 is configured so that the vibration portion 20 is separated from the boundary portion between the vibration portion 20 and the bank portion 26 in the thickness direction. It is led out from the main surface 22 to one main surface 21.
- a first bonding electrode 25 is formed at the terminal portion of the extraction electrode 24.
- An Au plating layer 50 is formed on the first bonding electrode 25.
- Both main surfaces 21 and 22 of the crystal diaphragm 2 have a mirror finish and are formed as flat smooth surfaces.
- both main surfaces 201 and 202 of the frame portion 28 are configured as a bonding surface (bonding region) between the lower lid member 3 and the upper lid member 4, and the vibrating portion 20 is configured as a vibration region.
- a first bonding material 51 which is a bonding layer for bonding to the lower lid member 3, is formed on one main surface 201 of the frame portion 28.
- a second bonding material 52 which is a bonding layer for bonding to the upper lid member 4, is formed on the other main surface 202 of the frame portion 28.
- the formation widths of the first bonding material 51 and the second bonding material 52 are substantially the same, and the first bonding material 51 and the second bonding material 52 have the same film configuration, and the first bonding material 51 and the second bonding material 52 are formed. Is configured by laminating a plurality of metal films on both main surfaces 201 and 202 of the frame portion 28.
- a Cr layer (not shown) and an Au layer (not shown) are formed by vapor deposition from the lowermost layer side, and Au plating is formed thereon.
- a layer (not shown) is laminated by an electrolytic plating method.
- the lower lid member 3 is a flat plate having a rectangular shape in plan view, and a Z-plate crystal is used.
- the outer dimension of the lower lid member 3 is substantially the same as the outer dimension of the crystal diaphragm 2 in plan view.
- the lower lid member 3 has a bonding region (specifically, a bonding surface 32) with the crystal diaphragm 2 on one main surface 31.
- the joint surface 32 is an outer periphery along the outer periphery of the one main surface 31 of the lower lid member 3 and a region in the vicinity thereof.
- a second bonding electrode 33 is formed on one main surface 31 of the lower lid member 3. The second bonding electrode 33 is bonded to the first bonding electrode 25 of the crystal diaphragm 2 via the Au plating layer 50.
- a third bonding material 53 which is a bonding layer for bonding to the crystal diaphragm 2, is formed.
- the third bonding material 53 is formed by laminating a plurality of metal films on the bonding surface 32, and a Cr layer (not shown) and an Au layer 531 are formed by vapor deposition from the lowermost layer side.
- An Au—Sn alloy layer 532 is laminated and an Au flash plating layer 533 is further laminated thereon.
- the third bonding material 53 may be formed by depositing a Cr layer and an Au layer from the lower surface side, and sequentially laminating an Sn plating layer and an Au plating layer thereon.
- the third bonding material 53 and the second bonding electrode 33 are formed at the same time, and the second bonding electrode 33 and the third bonding material 53 have the same configuration.
- the third bonding material 53 is formed so that the formation width thereof is substantially the same as the formation width of the first bonding material 51.
- the lower lid member 3 is formed with a via 35 for electrically connecting the excitation electrode 23 of the crystal diaphragm 2 to the outside. Through this via 35, an electrode pattern 36 is patterned from the second bonding electrode 33 on the one main surface 31 of the lower lid member 3 to the external connection terminal 34 on the other main surface 37.
- the bonding region (specifically, the bonding surface 32) and the region where the electrode pattern 36 is formed are rough.
- a region other than the rough surface of the one principal surface 31 is a flat smooth surface (mirror finish).
- One main surface 31 of the lower lid member 3 is a flat smooth surface (mirror finish) in the initial state, and a joining region (base) is a rough surface by a roughening process described later.
- FIGS. 1 and 2 in order to clarify the rough surface state of the one main surface 31 of the lower lid member 3, the unevenness of the rough surface region (joining region) is emphasized. Show.
- the upper lid member 4 is a flat plate having a rectangular shape in plan view, and a Z-plate crystal is used similarly to the lower lid member 3.
- the outer dimension of the upper lid member 4 is substantially the same as the outer dimension of the crystal diaphragm 2 in plan view.
- the upper lid member 4 has a bonding region (specifically, a bonding surface 42) with the crystal diaphragm 2 on one main surface 41.
- the joint surface 42 is an outer periphery along the outer periphery of the one main surface 41 of the upper lid member 4 and a region in the vicinity thereof.
- the joint surface 42 of the one main surface 41 is a rough surface
- the region other than the rough surface of the one main surface 41 is a flat smooth surface (mirror finish).
- One main surface 41 of the upper lid member 4 is a flat smooth surface (mirror finish) in the initial state.
- the bonding region (base) is roughened by a roughening process described later.
- FIGS. 1 and 2 in order to clarify the rough surface state of the one main surface 41 of the upper lid member 4, the unevenness of the rough surface region (joining region) is emphasized and illustrated. ing.
- a fourth bonding material 54 which is a bonding layer for bonding to the crystal diaphragm 2, is formed on the bonding surface 42 of the upper lid member 4.
- the fourth bonding material 54 is formed by laminating a plurality of metal films on the bonding surface 42, and a Cr layer (not shown) and an Au layer 541 are formed by vapor deposition from the lowermost layer side.
- An Au—Sn alloy layer 542 is laminated and an Au flash plating layer 543 is laminated thereon.
- the fourth bonding material 54 may be formed by vapor-depositing a Cr layer and an Au layer from the lower surface side, and sequentially laminating an Sn plating layer and an Au plating layer thereon.
- the fourth bonding material 54 is formed so that the formation width thereof is substantially the same as the formation width of the second bonding material 52.
- the joining region (seal path) of the three joining materials 53 has the same width.
- the seal path) has the same width.
- FIG. 3 is a flowchart showing the roughening process.
- the lower lid member 3 and the upper lid member 4 are made of two kinds of metals (Cr, Au) on the joint surface side (one main surface 31, 41) with the crystal diaphragm 2.
- a metal film (Cr layer and Au layer) is formed by vapor deposition (metal film forming step shown in FIG. 3).
- the metal film formed by the vapor deposition method is made of two kinds of metals, but is not limited to two kinds, and may be made of two or more kinds of metals. .
- a resist is applied on the metal film by spin coating (resist application step 1 shown in FIG. 3), and the resist is exposed to form a predetermined external resist pattern. Then, the metal film is partially exposed by development (outer shape exposure / development step shown in FIG. 3). The exposed metal film is melted by metal etching, and the quartz base of the lower lid member 3 and the upper lid member 4 is exposed (outer metal etching step shown in FIG. 3). Thereafter, the remaining resist is stripped using a stripping solution (step of resist stripping shown in FIG. 3).
- the layer thickness of the metal film (Cr layer and Au layer) which consists of two types of metals (Cr, Au) shown in FIG. 4 is not limited to the thickness of FIG. 4 respectively, As arbitrary layer thickness Also good.
- the amount of Cr diffused by heat treatment is controlled by increasing or decreasing the thickness of Cr as the base metal relative to the thickness of Au, and the minute amount due to penetration of the etching solution into the Cr layer after the diffusion process It is possible to control the drilling state of the holes. That is, the surface state of the rough surface can be controlled.
- a resist is applied again to the diffusion layer (resist application two steps shown in FIG. 3). Then, as shown in FIG. 7, the resist in the region to be roughened is removed by exposure / development (rough surface pattern exposure / development step shown in FIG. 3).
- an etching solution (ammonium fluoride in the first embodiment) is formed on the metal film (diffusion layer) in a state where a region where the resist remains and a region where the resist is removed are mixed. And wet etching is performed (etching step shown in FIG. 3). At this time, in the metal film in the region not covered with the resist, the etching solution penetrates and reaches the crystal substrate under the metal film (diffusion layer), and corrodes the surface of the crystal substrate. As shown in FIG. 6, this is considered to be caused by the fact that a plurality of “conducting paths” of Cr are formed in the metal film by the diffusion process, and Cr is corrosive to the etching solution.
- the etching solution penetrates the metal film through the “conducting path” and a large number of microholes (pinholes) are formed on the surface of the quartz substrate ( (See FIG. 9). In this way, the surface of the quartz substrate under the metal film can be roughened via the metal film (diffusion layer). On the other hand, the portion of the quartz substrate under the metal film covered with the resist remains without being corroded by the etching solution because the resist having a high corrosion resistance against the etching solution is used.
- the resist is stripped using a stripping solution as shown in FIG. 10 (resist stripping two steps shown in FIG. 3). Then, metal etching is performed to remove the metal film remaining on the quartz substrate (entire metal etching step shown in FIG. 3). By this metal etching, the quartz substrate in the rough surface region and the quartz substrate in the mirror region are exposed (see FIG. 11).
- a single crystal vibrating plate 2 is arranged on each of the wafer-like lower lid members 3 on which a large number of lower lid members 3 are formed in a lump, and the crystal vibrating plate 2 is placed on the crystal vibrating plate 2.
- the upper lid member 4 is provided in an individual state, and then the wafer is diced to be separated into a large number of crystal resonators 1.
- a method for manufacturing the crystal unit 1 will be described.
- this invention is not limited to the form of each member demonstrated in 1st Embodiment, All the whole structural members of the package 11 of the lower cover member 3, the crystal diaphragm 2, and the upper cover member 4 are each many.
- the crystal diaphragm 2 is arranged on the lower lid member 3 using the wafer formed in a batch, the upper lid member 4 is arranged on the quartz diaphragm 2, and then the individual pieces of the crystal unit 1 are diced by dicing. In this case, the method is suitable for mass production of the crystal unit 1.
- a wafer on which a large number of lower lid members 3 are formed is placed so that one main surface 31 of the lower lid member 3 faces upward. .., 3 on one main surface 31, 31,..., 31 in the wafer at the position set by the image recognition means, and in an individual state, the crystal diaphragm 2, 2 are arranged such that one principal surface 21 of the crystal diaphragm 2 faces one principal surface 31 of the lower lid member 3.
- the third bonding material 53 formed on the bonding surface 32 of the lower lid member 3 and the first bonding material 51 formed on the one main surface 201 of the frame portion 28 of the crystal diaphragm are substantially coincident in plan view. Arrange to do.
- the second bonding electrode 33 formed on the one main surface 31 of the lower lid member 3 and the Au plating layer 50 formed on the first bonding electrode 25 of the quartz crystal vibration plate 2 are substantially omitted in plan view. Arrange to match.
- the upper lid member 4 in an individual state is placed on the other main surface 202 of the frame portion 28 of the crystal diaphragm 2 at the position set by the image recognition means.
- the second bonding material 52 formed on the other main surface 202 of the frame portion 28 of the crystal diaphragm 2 and the fourth bonding material 54 formed on the bonding surface 42 of the upper lid member 4 are substantially coincident in plan view. Arrange to do.
- the lower lid member 3, the crystal diaphragm 2 and the upper lid member 4 are laminated, the lower lid member 3, the crystal diaphragm 2 and the upper lid member 4 are temporarily joined by joining using ultrasonic waves.
- other manufacturing processes eg, degassing the internal space 12 and adjusting the oscillation frequency
- heating and melting described below The lower lid member 3, the crystal diaphragm 2, and the upper lid member 4 are joined together.
- the lower lid member 3, the crystal diaphragm 2 and the upper lid member 4 which are temporarily bonded are placed in an environment heated to a predetermined temperature, and each member (lower lid member 3, quartz diaphragm 2, upper lid member 4) is placed.
- the main bonding is performed by melting each of the formed bonding materials (first bonding material 51, second bonding material 52, third bonding material 53, and fourth bonding material 54).
- the bonding material 5 is configured by bonding the first bonding material 51 and the third bonding material 53, and the crystal vibrating plate 2 and the lower lid member 3 are bonded by the bonding material 5. As shown in FIG.
- the excitation electrode 23 formed on one main surface 21 of the quartz crystal plate 2 is hermetically sealed by joining the crystal plate 2 and the lower lid member 3 with the bonding material 5.
- the bonding material 5 is formed by heating and melting the second bonding material 52 and the fourth bonding material 54 simultaneously with the bonding of the first bonding material 51 and the third bonding material 53.
- the crystal diaphragm 2 and the upper lid member 4 are joined.
- the excitation electrode 23 formed on the other main surface 22 of the crystal vibrating plate 2 is hermetically sealed by bonding the crystal vibrating plate 2 and the upper lid member 4 with the bonding material 5.
- the lower lid member 3, the crystal diaphragm 2, and the upper lid member 4 are temporarily bonded and permanently bonded in a vacuum atmosphere, but the present invention is not limited to this, and is not limited to nitrogen or the like. Bonding may be performed in an active gas atmosphere.
- the crystal resonator 1 shown in the first embodiment since the base material of the joining region of the constituent members (the lower lid member 3 and the upper lid member 4) constituting the crystal resonator 1 is roughened, the rough surface As a result, the minute unevenness formed on the surface of the base material in the joining region of the lower lid member 3 and the upper lid member 4 functions like a “wedge” against the stress in the horizontal direction. That is, by having a so-called anchor (throwing) effect, the bonding strength between the base material in the bonding region of the roughened lower lid member 3 and upper lid member 4 and the bonding material 5 can be improved.
- anchor throwing
- the etching method of the constituent members constituting the crystal unit 1 shown in the first embodiment includes a metal film forming step, a diffusion step, and an etching step, the surface has very little unevenness like a mirror finish.
- a rough surface can be partially formed on at least one main surface of the constituent member in the state. Specifically, a region not desired to be roughened is protected by coating with a resist or the like, and a protective film such as a resist is not formed on the region desired to be roughened, and a metal film in which metal diffusion occurs (diffusion layer) ), A large number of micropores are formed on the surface of the substrate by infiltrating the etching solution to the substrate of the constituent member. Thereby, a selective roughening process can be performed.
- the surface condition is extremely low as in the case of mirror finishing.
- a rough surface can be partially formed on one main surface 31, 41 of the lid member 3 and the upper lid member 4.
- a region not desired to be roughened is protected by coating with a resist or the like, and a protective film such as a resist is not formed on a region desired to be roughened, and a metal film in which metal diffusion occurs (diffusion)
- a protective film such as a resist
- a metal film in which metal diffusion occurs A large number of micropores are formed on the surfaces of the lower lid member 3 and the upper lid member 4 by allowing the etching solution to penetrate into the base of the lower lid member 3 and the upper lid member 4 via the layer). Thereby, a selective roughening process can be performed.
- the manufacturing cost of the crystal unit 1 since it is not essential to perform interatomic bonding for bonding as in the prior art, the manufacturing cost of the crystal unit 1 can be suppressed.
- the upper lid member 4 and the lower lid member 3 are made of crystal, and the crystal diaphragm 2 is made of crystal, and a Cr layer is formed on the surface of the upper lid member 4 and the lower lid member 3 in the metal film forming step. Then, a metal film is formed by laminating an Au layer on the Cr layer to form a two-layer structure composed of a Cr layer and an Au layer, and in the diffusion process, Cr in the Cr layer is diffused into Au in the Au layer.
- the etching solution can be applied to the upper cover member 4 and the cover member 3 without corroding the metal film. It can be penetrated to the substrate. Thereby, many micropores can be formed on the surface of the base material of the upper lid member 4 and the lid member 3 below the metal film where metal diffusion has occurred, and can be roughened.
- the vibration part 20 has a reverse mesa shape in which a bank part 26 is formed on the outer periphery of the vibration part 20, and has a structure in which a thin part 27 is formed outside the vibration part 20.
- the present invention is not limited to the inverted mesa structure.
- the shape which did not form a thin part but made the inner side of the frame part a flat plate, and provided the through-hole partially may be sufficient.
- the bonding material 5 may be made of, for example, Cr, Au, and Ge. Good.
- a plated laminated film such as Au and Sn or a plated alloy layer such as AuSn is formed on the quartz diaphragm 1 side, and an Au plated layer (single metal element plated layer) is formed on the lower lid member 3 or the upper lid member 4 side. It may be formed.
- quartz is used as the material for the two package substrates, but glass or sapphire may be used in addition to quartz.
- FIG. 12 A modification of the first embodiment of the present invention is shown in FIG.
- the modification shown in FIG. 12 is an example in which the surface of the roughening process is not the bonding region of the lower lid member 3 or the bonding region of the upper lid member 4 but the bonding region of the crystal diaphragm 2. Even with such a structure, the bonding strength between the crystal diaphragm 2 and the bonding material 5 can be improved. In addition, you may give the joining area
- region of the upper cover member 4 is performed, it is not limited to this, As shown in FIG.
- the surface of the third bonding material 53 and the surface of the fourth bonding material 54 formed on the surface of the roughened bonding region between the lower lid member 3 and the upper lid member 4 may be roughened.
- the surface of the 3rd bonding material 53, and the surface of the 4th bonding material 54 are rough surfaces, for example, the roughened bottom
- a plating layer is formed by electrolytic plating on an upper layer of the third bonding material 53 and the fourth bonding material 54 on the substrate between the bonding region of the lid member 3 and the bonding region of the upper lid member 4,
- An anchor effect works between the surfaced third bonding material 53 and the fourth bonding material 54, and a machine at the time of temporary bonding using ultrasonic waves of the upper lid member 4, the lower lid member 3, and the crystal diaphragm 2.
- the mechanical strength is improved.
- the surface of the joint area between the lower lid member 3 and the upper lid member 4 is roughened by the manufacturing process shown in FIGS. 3 to 11, but the present invention is not limited to this.
- the manufacturing method shown in 14 to 17 can also roughen the joint area between the lower lid member 3 and the upper lid member 4.
- a Cr layer is formed by vapor deposition on one main surface 31, 41 of the quartz base plate of the lower lid member 3 and the upper lid member 4, and is put into an etching solution (ammonium fluoride solution). Then, wet etching is performed (see FIG. 14). At this time, surface roughness of the Cr layer is caused by etching, and the degree of surface roughness increases in proportion to the time for performing wet etching (see FIG. 15). Then, by performing wet etching continuously, as shown in FIG. 16, asperities are formed on one main surface 31, 41 of the quartz base plate of the lower lid member 3 and the upper lid member 4, and the lower lid member 3 and the upper lid member The four main surfaces 31 and 41 of the quartz base plate 4 are roughened.
- etching solution ammonium fluoride solution
- Cr layers are formed on the main surfaces 31 and 41 of the quartz base plates of the lower lid member 3 and the upper lid member 4 in a state where they are scattered by a vapor deposition method.
- the lower lid member 3 and the upper lid member 4 shown in FIG. 17 are wet etched by being poured into an etching solution (ammonium fluoride solution). Then, by performing wet etching continuously, irregularities are formed on one main surface 31, 41 of the quartz base plate of the lower lid member 3 and the upper lid member 4 as shown in FIG. 16, and the lower lid member 3 and the upper lid member 4.
- the main surfaces 31, 41 of the quartz base plate are roughened.
- a process for forming a large number of small holes in the Cr layer at random using a vapor deposition method and a photolithography method is added to the manufacture of the lower lid member 3, the upper lid member 4, and the crystal diaphragm 2. May be.
- a large number of small holes can be formed in the lower lid member 3, the upper lid member 4, and the crystal diaphragm 2 by performing etching using a Cr layer in which a large number of small holes are randomly formed as a mask.
- FIG. 18 is a cross-sectional view of the crystal unit 1 along the long side direction of the crystal plate 2 showing the second embodiment.
- the same constituent members as those in the first embodiment are denoted by the same reference numerals and a part of the description is omitted.
- the same configuration as the first embodiment has the same effect. Therefore, hereinafter, the second embodiment will be described focusing on the differences from the first embodiment.
- the joint regions of both the upper lid member 4 and the lower lid member 3 are roughened. And the joining area
- the metal film (the first bonding material 51, the second bonding material 52, the third bonding material 53, and the fourth bonding material 54) constituting the bonding material 5 is heated and melted to lower the lid member. 3, the upper lid member 4, and the quartz crystal vibrating plate 5 are joined together, the fluidized joining material 5 can suppress the movement of the quartz crystal resonator 1 in the internal direction.
- the fillet of the bonding material 5 is likely to be formed toward the bonding region (rough surface region) that is widely formed in the inner direction between the lower lid member 3 and the upper lid member 4.
- the lower lid member 3, the upper lid member 4, and the crystal diaphragm 2 are more firmly joined. That is, the fillet formation region of the bonding material 5 can be controlled by controlling the rough surface region of the lower lid member 3 and the upper lid member 4.
- FIG. 19 is a cross-sectional view of the crystal unit 1 along the long side direction of the crystal plate 2 showing the third embodiment.
- the same constituent members as those in the first embodiment are denoted by the same reference numerals and a part of the description is omitted.
- the same configuration as the first embodiment has the same effect. Therefore, hereinafter, the third embodiment will be described with a focus on differences from the first embodiment.
- the entire main surfaces 31, 41 of the lower lid member 3 and the upper lid member 4 on the side to be joined to the crystal diaphragm 2 are rough. It is faced.
- the entire main surface 31 of the lower lid member 3 is roughened, for example, an electrode pattern electrically connected to an external connection terminal connected to an external device is used as the lower lid member. 3, if the entire main surface 31 is roughened, the adhesion between the electrode pattern and the main surface 31 can be improved. Further, the surface roughening process is simplified and productivity is improved as compared with the case where only the surface where the electrode pattern is formed is selectively roughened.
- the base material of the one main surfaces 31 and 41 whole of the lower cover member 3 and the upper cover member 4 is roughened, it is not limited to this, A lower cover member 3 may be roughened, and as shown in FIG. 20, the substrate in the region where the external connection terminals and electrode patterns are formed may be roughened. That is, the above-described effect is obtained as long as at least the surface of the main surface region where the terminals such as the external connection terminals and the electrode pattern are formed is roughened.
- the roughening of the base material of the joint region in which the external connection terminal of the lower lid member 3 is formed is the same as that in the first embodiment, the second embodiment, the following fourth embodiment, or the fifth embodiment. Applicable.
- FIG. 21 is a cross-sectional view of the crystal unit 1 along the long side direction of the crystal plate 2 showing the fourth embodiment.
- the same constituent members as those in the first embodiment are denoted by the same reference numerals and a part of the description is omitted.
- the fourth embodiment will be described with a focus on differences from the first embodiment.
- the joint regions of both main surfaces 201 and 202 of the frame portion 28 of the crystal plate 2 are roughened.
- the rough surface of the bonding region of the quartz crystal diaphragm 2 is formed by the roughening process described in the first embodiment, and the roughening process is performed between the bonding material 5 and the frame portion 28.
- An anchor effect is produced, and the bonding strength between the crystal diaphragm 2 and the lower lid member 3 and the upper lid member 4 can be improved.
- a multi-surface joint portion for joining the bonding material 5 with a plurality of surfaces having different surface directions is provided in the joint region of the lower lid member 3 in the joint region 13 between the lower lid member 3 and the crystal diaphragm 2 and in the vicinity thereof. It has been. Moreover, the expansion prevention part which prevents that a joining area
- a multi-surface joint portion that joins the bonding material 5 with a plurality of surfaces having different surface directions is provided in and near the bonding region of the upper lid member 4 in the bonding portion 14 between the upper lid member 4 and the crystal diaphragm 2.
- the expansion prevention part which prevents that a joining area
- the multi-surface joint portion and the expansion preventing portion are formed by arranging two groove portions 8 along the outer periphery of one main surface 31, 41 of the lower lid member 3 and the upper lid member 4. Specifically, by forming the two groove portions 8, a protrusion 6 formed between the two grooves is provided as a multi-surface joint portion, and the protrusion 6 continues to the protrusion 6 on the outer side. A depression 7 is formed as an expansion preventing part.
- the protrusion 6 has an end surface 61 and a side surface 62, and the bonding material 5 is bonded to the protrusion 6.
- the recess 7 is formed in the surface direction of the one main surface 31, 41 in a plan view and outside the protrusion 6.
- the lower lid member 3 and the upper lid member 4 are provided with the multi-surface joint portion and the enlargement preventing portion.
- the bonding material 5 is on the bonding surface (one main surface 31, 41) between the lower lid member 3 and the upper lid member 4 in the main surface direction ( Spreading in the plane direction) can be suppressed.
- the lower lid member 3 and the upper lid member 4 are provided with the multi-surface joint portions, and thus have a plurality of surfaces with different surface directions (specifically Specifically, the bonding material 5 can be bonded at the end surface 61 and the both side surfaces 62) of the protrusion 6, and an anchor effect can be generated to increase the bonding strength with the bonding material 5.
- the multi-surface joint portion is a protrusion 6 having a plurality of surfaces, and the bonding material 5 is bonded to a plurality of surfaces including the end surface 61 of the protrusion 6. Can be joined, and an anchor effect is likely to occur.
- the bonding material 5 spreads (wet) in the bonding portions 13 and 14 (bonding regions) is a phenomenon that naturally occurs.
- the multi-surface joint portion is provided in the vicinity of the joint region between the lower lid member 3 and the upper lid member 4 and the vicinity thereof, and is expanded outward of the multi-surface joint portion. Since the prevention portion is provided, the bonding material 5 flows to the end face of the crystal unit 1 even when the bonding material 5 spreads in the bonding portions 13 and 14 after bonding by the bonding material 5 by the expansion prevention portion. (Wetting) can be prevented, and the bonding material 5 can be prevented from entering the internal space 12 of the crystal unit 1.
- the bonding material 5 is heated and melted as shown in FIG.
- the amount of the bonding material 5 is changed to be larger than the amount used in the fourth embodiment, the capacity of the recess 7 is filled.
- the anchor effect since the anchor effect also occurs in the recessed portion 7, it is possible to further increase the bonding strength.
- the multi-surface joint portion and the expansion prevention are provided at both the joint portion 13 between the crystal diaphragm 2 and the lower lid member 3 and the joint portion 14 between the crystal diaphragm 2 and the upper lid member 4.
- the present invention is not limited to this, and is not limited to this.
- the joint portion 13 between the crystal diaphragm 2 and the lower lid member 3, the crystal diaphragm 2 and the upper lid member 4 is provided. If the multi-surface joint portion and the expansion preventing portion are provided in at least one joint portion with the joint portion 14, the above effect is obtained.
- a recess 61 formed continuously from the protrusion 6 is provided as an expansion preventing part outside the protrusion 6 which is a multi-surface joint, but this is one implementation.
- the present invention is not limited to this, and the above-described effect can be obtained if an expansion preventing portion is provided outside the multi-surface joint portion.
- the lower lid member 3 and the upper lid member 4 are provided with one multi-surface joint portion and two expansion prevention portions, but the number of the multi-surface joint portion and the expansion prevention portion is the same.
- the present invention is not limited, and an arbitrary number of multi-surface joint portions and expansion preventing portions may be provided.
- the depression 7 is used for the enlargement prevention portion, but the present invention is not limited to this, and the bonding material 5 is one main surface 31 of the lower lid member 3 or one of the upper lid member 4.
- the enlargement prevention part is perpendicular to the main surface direction (or a direction close to the direct downward direction). It is preferable that the projections and depressions are formed.
- FIG. 22 is a cross-sectional view of the crystal unit 1 along the long side direction of the crystal plate 2 according to the fifth embodiment.
- the same constituent members as those in the first embodiment are denoted by the same reference numerals and a part of the description is omitted.
- the fifth embodiment will be described focusing on the differences from the first embodiment.
- the bases of both main surfaces 201 and 202 of the frame portion 28, which is a joining region of the crystal diaphragm 2 are roughened.
- region (one main surface 31) of the lower cover member 3 are roughened.
- the base material of the joint region of the upper cover member 4 and the base material of the joint region of the lower cover member 3 which are roughened are formed to be rougher than the surface of the base material of the joint region of the crystal diaphragm 2.
- the upper cover member 4 and the lower cover member 3 are roughened as compared with the case where the roughening process is performed on the crystal diaphragm 2 on which the excitation electrode 23 and the extraction electrode 24 are formed.
- the roughening treatment process can be simplified by performing the roughening treatment.
- the quartz diaphragm 2 is formed with a metal film (electrode film) such as the excitation electrode 23 and the extraction electrode 24, and it is necessary to protect the excitation electrode 23 and the extraction electrode 24 during the roughening treatment. Furthermore, since various thermal histories are added, there is a possibility that the film states of the excitation electrode 23 and the extraction electrode 24 will be affected.
- the upper lid member 4 and the lower lid member 3 are not formed with electrode films such as the excitation electrode 23 and the extraction electrode 24, and the influence on various characteristics of the crystal resonator 1 can be reduced.
- the crystal resonator 1 having good characteristics can be obtained in combination with the anchor effect on the joining material 5. .
- the present invention is not limited to this, and the excitation electrode formed on the crystal diaphragm by the two lid members.
- the shape of the lid member may be arbitrarily set.
- a form in which the concave portions of the two lid members formed in a concave shape are hermetically joined so as to face the crystal diaphragm are shown in FIGS. 23 and 24, as shown in FIGS. 23 and 24, a package 11 is composed of an upper cover member 4 of a single plate and a lower cover member 3 of a box-like body, and the crystal diaphragm 2 is placed on the lower cover member 3 in the package 11.
- FIG. 24 is a schematic plan view of the lower lid member 3.
- FIG. 23 shows the lower lid member 3 taken along the line AA in FIG.
- a joining area where the upper lid member 4 is joined to the lower lid member 3 a joining area where the upper lid member 3 is joined to the upper lid member 4, and the crystal diaphragm 2 of the lower lid member 3.
- the joint region that is electromechanically joined to each other and the joint region that forms the external connection terminal that is electrically connected to the external member of the lower lid member 3 are roughened.
- a surface-mount type crystal resonator is taken as an example, but other surface-mount type used in electronic devices such as a crystal oscillator in which a crystal resonator is incorporated in an electronic component such as a crystal filter or an integrated circuit.
- This method can also be applied to a method for manufacturing a piezoelectric vibration device.
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Abstract
Description
2 水晶振動板
20 振動部
23 励振電極
3 下蓋部材
4 上蓋部材
5 接合材
50 Auメッキ層
51 第1接合材
52 第2接合材
53 第3接合材
54 第4接合材
6 突部
7 窪み部
8 溝部
以下、本発明にかかる第1の実施形態について図面を参照しながら説明する。なお、以下に示す第1の実施形態では、圧電振動デバイスとして水晶振動子を本発明に適用した場合を示す。図1は第1の実施形態を示す水晶振動板2の長辺方向に沿った水晶振動子1の断面図であり、図2は図1に示す水晶振動子1の各構成部材を示した概略構成図である。
本発明の第1の実施形態の変形例を図12に示す。図12に示す変形例では、粗面化処理の対象を下蓋部材3の接合領域や上蓋部材4の接合領域ではなく、水晶振動板2の接合領域とした例となっている。このような構造であっても水晶振動板2と接合材5との接合強度を向上させることができる。なお、本構成において粗面化させる接合領域を枠部28の両主面201、202全体に施してもよい。つまり、枠部28の金属膜(接合材5)が形成される領域だけでなく、その外側の領域も粗面化することにより、加熱溶融によって流動化した金属が振動部20に向かう方向に流出するのを防止することができる。このように、枠部28の両主面201、202全体が粗面化されているので、溶融した金属膜(接合材5)の移動に対して粗面が抵抗となって、振動部20に対して溶融する金属の流入を防止することができる。
本発明にかかる第2の実施形態を、上記の第1の実施形態と同様に圧電振動板として水晶振動板を用いた水晶振動子を例に挙げて図18を用いて説明する。図18は、第2の実施形態を示す水晶振動板2の長辺方向に沿った水晶振動子1の断面図である。なお、第2の実施形態では、第1の実施形態と同様の構成部材については同番号を付して説明の一部を割愛する。また、第2の実施形態の構成のうち、第1の実施形態と同様の構成については同様の効果を有する。そのため、以下、第1の実施形態との相違点を中心に、第2の実施形態を説明する。
本発明にかかる第3の実施形態を、上記の第1の実施形態と同様に圧電振動板として水晶振動板を用いた水晶振動子を例に挙げて図19を用いて説明する。図19は、第3の実施形態を示す水晶振動板2の長辺方向に沿った水晶振動子1の断面図である。なお、第3の実施形態では、第1の実施形態と同様の構成部材については同番号を付して説明の一部を割愛する。また、第3の実施形態の構成のうち、第1の実施形態と同様の構成については同様の効果を有する。そのため、以下、第1の実施形態との相違点を中心に、第3の実施形態を説明する。
本発明にかかる第4の実施形態を、上記の第1の実施形態と同様に圧電振動板として水晶振動板を用いた水晶振動子を例に挙げて図21を用いて説明する。図21は、第4の実施形態を示す水晶振動板2の長辺方向に沿った水晶振動子1の断面図である。なお、第4の実施形態では、第1の実施形態と同様の構成部材については同番号を付して説明の一部を割愛する。また、第4の実施形態の構成のうち、第1の実施形態と同様の構成については同様の効果を有する。そのため、以下、第1の実施形態との相違点を中心に、第4の実施形態を説明する。
本発明にかかる第5の実施形態を、上記の第1の実施形態と同様に圧電振動板として水晶振動板を用いた水晶振動子を例に挙げて図22を用いて説明する。図22は、第5の実施形態を示す水晶振動板2の長辺方向に沿った水晶振動子1の断面図である。なお、第5の実施形態では、第1の実施形態と同様の構成部材については同番号を付して説明の一部を割愛する。また、第5の実施形態の構成のうち、第1の実施形態と同様の構成については同様の効果を有する。そのため、以下、第1の実施形態との相違点を中心に、第5の実施形態を説明する。
Claims (11)
- 圧電振動デバイスにおいて、
励振電極が形成された圧電振動板と、前記励振電極を気密封止する上蓋部材および下蓋部材と、が設けられ、
前記圧電振動板の表裏主面に、前記上蓋部材および前記下蓋部材との各接合領域を有し、
前記上蓋部材の一主面に、前記圧電振動板との接合領域を有し、
前記下蓋部材の一主面に、前記圧電振動板との接合領域を有し、前記下蓋部材の他主面に、外部部材との接合領域を有し、
前記圧電振動板の接合領域と、前記上蓋部材の接合領域と、前記下蓋部材の接合領域とには、接合材を構成する接合層がそれぞれ形成され、
前記圧電振動板の接合領域と前記上蓋部材の接合領域とが前記接合材を介して接合され、
前記圧電振動板の接合領域と前記下蓋部材の接合領域とが前記接合材を介して接合され、
前記圧電振動板の接合領域の素地と、前記上蓋部材の接合領域の素地と、前記下蓋部材の接合領域の素地との少なくとも1つが、粗面化されていることを特徴とする圧電振動デバイス。 - 圧電振動デバイスにおいて、
励振電極が形成された圧電振動板と、前記励振電極を気密封止する上蓋部材および下蓋部材と、が設けられ、
前記上蓋部材の一主面に、前記下蓋部材との接合領域を有し、
前記下蓋部材の一主面に、前記上蓋部材との接合領域を有し、前記下蓋部材の他主面に、外部部材との接合領域を有し、
前記上蓋部材の接合領域と、前記下蓋部材の接合領域とには、接合材を構成する接合層がそれぞれ形成され、
前記上蓋部材の接合領域と前記下蓋部材の接合領域とが前記接合材を介して接合され、
前記上蓋部材の接合領域の素地と、前記下蓋部材の接合領域の素地との少なくとも1つが、粗面化されていることを特徴とする圧電振動デバイス。 - 請求項2に記載の圧電振動デバイスにおいて、
前記下蓋部材の一主面に、前記圧電振動板との接合領域を有し、
前記圧電振動板との接合領域の素地が、粗面化されていることを特徴とする圧電振動デバイス。 - 請求項1乃至3のうちいずれか1つに記載の圧電振動デバイスにおいて、
粗面化された前記接合領域の素地上に形成された前記接合層の表面が、粗面化されていることを特徴とする圧電振動デバイス。 - 請求項1乃至4のうちいずれか1つに記載の圧電振動デバイスにおいて、
前記圧電振動板の接合領域の素地が、粗面化され、
前記上蓋部材の接合領域の素地と、前記下蓋部材の接合領域の素地との少なくとも1つが、粗面化され、
前記上蓋部材と前記下蓋部材との少なくとも1つの前記接合領域の素地の表面が、前記圧電振動板の接合領域の素地の表面よりも、粗く成形されていることを特徴とする圧電振動デバイス。 - 請求項1乃至5のうちいずれか1つに記載の圧電振動デバイスにおいて、
前記上蓋部材と前記下蓋部材との少なくとも1つの前記接合領域が、粗面化され、
粗面化された前記接合領域は、前記圧電振動板の接合領域よりも平面視で前記一主面の内側方向に広く形成されていることを特徴とする圧電振動デバイス。 - 請求項1乃至5のうちいずれか1つに記載の圧電振動デバイスにおいて、
前記上蓋部材と前記下蓋部材との少なくとも1つの前記主面全体が、粗面化されていることを特徴とする圧電振動デバイス。 - 請求項1乃至7のうちいずれか1つに記載の圧電振動デバイスにおいて、
前記圧電振動板の接合領域が、粗面化され、
前記上蓋部材と前記下蓋部材の少なくとも1つの前記接合領域の近傍には、前記接合材を面方向が異なる複数の面で接合する複数面接合部が設けられ、
前記複数面接合部の外方に、前記接合材との接合領域を拡大するのを防ぐ拡大防止部が設けられていることを特徴とする圧電振動デバイス。 - 圧電振動デバイスの製造方法において、
励振電極が形成された圧電振動板と、前記励振電極を気密封止する上蓋部材および下蓋部材と、が設けられ、前記圧電振動板の表裏主面に、前記上蓋部材および前記下蓋部材との各接合領域を有し、前記上蓋部材の一主面に、前記圧電振動板との接合領域を有し、前記下蓋部材の一主面に、前記圧電振動板との接合領域を有し、前記圧電振動板の接合領域と前記上蓋部材の接合領域とが接合材を介して接合され、前記圧電振動板の接合領域と前記下蓋部材の接合領域とが接合材を介して接合された前記圧電振動デバイスの製造方法であり、
前記圧電振動板の接合領域の素地と、前記上蓋部材の接合領域の素地と、前記下蓋部材の接合領域の素地との少なくとも1つに、少なくとも2種類の金属からなる金属膜を積層する金属膜形成工程と、
前記金属膜形成工程の後、加熱処理によって前記金属膜の内部の金属拡散を促す拡散工程と、
前記拡散工程後の前記金属膜にエッチング液を浸透させてウエットエッチングを行うことにより、前記素地表面に多数の微小孔を形成して前記素地を粗面化させるエッチング工程とを有することを特徴とする圧電振動デバイスの製造方法。 - 請求項9に記載の圧電振動デバイスの製造方法において、
前記上蓋部材と前記下蓋部材とは、水晶またはガラスからなり、
前記圧電振動板は、水晶からなり、
前記金属膜形成工程において、前記上蓋部材と前記下蓋部材と前記圧電振動板との少なくとも1つの前記素地上にCr層を形成し、前記Cr層上にAu層を積層して前記金属膜を形成して、前記Cr層と前記Au層とからなる2層構成を形成し、
前記拡散工程において、前記Cr層のCrを前記Au層のAuへ拡散させ、前記Crおよび前記水晶に対して腐食性を有するエッチング液を用いてウエットエッチングを行うことにより、前記素地の表面に多数の微小孔を形成して前記素地を粗面化させることを特徴とする圧電振動デバイスの製造方法。 - 圧電振動デバイスを構成する構成部材のエッチング方法において、
少なくとも1つの主面に外部部材との各接合領域を有した前記構成部材のエッチング方法であり、
前記構成部材の接合領域の素地に、少なくとも2種類の金属からなる金属膜を積層する金属膜形成工程と、
前記金属膜形成工程の後、加熱処理によって前記金属膜の内部の金属拡散を促す拡散工程と、
前記拡散工程後の前記金属膜にエッチング液を浸透させてウエットエッチングを行うことにより、前記素地表面に多数の微小孔を形成して前記素地を粗面化させるエッチング工程と、を有することを特徴とするエッチング方法。
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Also Published As
Publication number | Publication date |
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JP5370371B2 (ja) | 2013-12-18 |
EP2381575A4 (en) | 2018-03-28 |
WO2010074127A9 (ja) | 2010-09-16 |
CN102265514A (zh) | 2011-11-30 |
CN102265514B (zh) | 2014-03-12 |
US20110215678A1 (en) | 2011-09-08 |
US20140047687A1 (en) | 2014-02-20 |
US9406868B2 (en) | 2016-08-02 |
JPWO2010074127A1 (ja) | 2012-06-21 |
EP2381575A1 (en) | 2011-10-26 |
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