1. Field of the Invention
The present invention relates to boundary acoustic wave devices used as, for example, resonators or band-pass filters, and particularly, to a boundary acoustic wave device including a piezoelectric body, an electrode defined by a metal embedded in the upper surface of the piezoelectric body, and a dielectric body extending over the piezoelectric body and the electrode.
2. Description of the Related Art
Duplexers (DPXs) and RF filters used in mobile communication systems need to have both broad band-pass properties and good temperature properties. Conventional boundary acoustic wave devices used for such DPXs or RF filters include a piezoelectric substrate made of 36-50 degrees rotated Y-plate X-propagation LiTaO3. The piezoelectric substrate has a temperature coefficient of frequency of −45 ppm/° C. to −35 ppm/° C. A known technique for improving temperature properties is to arrange a SiO2 layer having a positive temperature coefficient of frequency over IDT electrodes arranged on the piezoelectric substrate.
In a structure in which the SiO2 layer extends over the IDT electrodes, unevenness occurs between fingers of the IDT electrodes and spaces between the electrode fingers. That is, a surface of the SiO2 layer cannot be prevented from having differences in height between the IDT electrodes and spaces therebetween. Therefore, there is a problem in that surface irregularities of the SiO2 layer cause a deterioration of insertion loss.
An increase in the thickness of the IDT electrodes necessarily increases the height of the irregularities. Therefore, the thickness of the IDT electrodes cannot be increased.
Recently, boundary acoustic wave devices have been replacing surface acoustic wave devices and have been attracting significant attention because the boundary acoustic wave devices are useful in manufacturing small-size packages. “RF Filter Using Boundary Acoustic Wave” (Proc. Symp. Ultrason. Electron., Vol. 26, pp. 25-26 (2005/11)) discloses a boundary acoustic wave device including a LiNbO3 substrate, IDT electrodes, and a SiO2 layer defining a dielectric body laminated in that order. The IDT electrodes have a relatively large thickness such that the acoustic velocity of an SH-type boundary acoustic wave propagating between the LiNbO3 substrate and the SiO2 layer is less than that of a slow transverse wave propagating in the SiO2 layer. Thus, the SH-type boundary acoustic wave is non-leaky. FIG. 3 of “RF Filter Using Boundary Acoustic Wave” (Proc. Symp. Ultrason. Electron., Vol. 26, pp. 25-26 (2005/11)) shows that the thickness of an IDT electrode that is sufficient for an SH-type boundary acoustic wave to be non-leaky is at least 0.15λ when the IDT electrode is made of Al, or at least 0.04λ when the IDT electrode is made of one of Cu, Ag, and Au, wherein λ represents the wavelength of the SH-type boundary acoustic wave.
When boundary acoustic wave devices, as well as the boundary acoustic wave device disclosed in “RF Filter Using Boundary Acoustic Wave” (Proc. Symp. Ultrason. Electron., Vol. 26, pp. 25-26 (2005/11)), include IDT electrodes which are made of Au and which have a thickness of at least 0.04λ, frequency properties of the boundary acoustic wave devices vary significantly due to differences in thickness between the electrodes. Therefore, it has been difficult to manufacture boundary acoustic wave devices having good frequency properties with high reproducibility.
To overcome the problems described above, preferred embodiments of the present invention provide a boundary acoustic wave device which includes electrodes having reduced thickness, which can confine an SH-type boundary acoustic wave between a piezoelectric body and a dielectric body, and which has low loss.
A first preferred embodiment of the present invention provides a boundary acoustic wave device that includes a LiNbO3 substrate which has a plurality of grooves provided in the upper surface thereof and which has Euler angles (0°, θ, −45° to +45°), electrodes defined by metal material filled in the grooves, and a dielectric layer provided over the LiNbO3 substrate and the electrodes. The upper surface of the dielectric layer is flat or substantially flat. The metal material used to define the electrodes is preferably at least one selected from the group consisting of Al, Ti, Ni, Cr, Cu, W, Ta, Pt, Ag, and Au, for example. Al and Ti are grouped into a first group. Ni and Cr are grouped into a second group. Cu, W, Ta, Pt, Ag, and Au are grouped into a third group. The thickness of the electrodes made of the metal materials assigned to each group, θ of the Euler angles of the LiNbO3 substrate, and the thickness of the dielectric layer are within any of ranges shown in Table 1 below.
In the boundary acoustic wave device of the first preferred embodiment, the thickness of the electrodes, θ of the Euler angles of the LiNbO3 substrate, and the thickness of the dielectric layer are within any of ranges shown in Table 2 below.
A second preferred embodiment of the present invention provides a boundary acoustic wave device that includes a LiTaO3 substrate which has a plurality of grooves provided in the upper surface thereof and which has Euler angles (0°, θ, −45° to +45°); electrodes defined by a metal material filled in the grooves; and a dielectric layer provided over the LiTaO3 substrate and the electrodes. The upper surface of the dielectric layer is flat or substantially flat. The metal material used to define the electrodes is preferably at least one selected from the group consisting of Al, Cu, Au, Ta, and Pt, for example. The thickness of the electrodes, θ of the Euler angles of the LiTaO3 substrate, and the thickness of the dielectric layer are within any of ranges shown in Table 3 below.
In the boundary acoustic wave device according to the second preferred embodiment, the thickness of the electrodes, θ of the Euler angles of the LiTaO3 substrate, and the thickness of the dielectric layer are within any of ranges shown in Table 4 below.
In the boundary acoustic wave device according to each preferred embodiment described above, the dielectric layer is preferably made of silicon dioxide, for example. Since silicon dioxide has a positive temperature coefficient of frequency TCF and LiNbO3 and LiTaO3 have a negative temperature coefficient of frequency TCF, a boundary acoustic wave device having a temperature coefficient of frequency with a small absolute value and good temperature properties is provided.
In the boundary acoustic wave device according to the first preferred embodiment, the electrodes are preferably formed by filling the grooves, which are provided in the upper surface of the LiNbO3 substrate, with the metal material and the dielectric layer is provided over the LiNbO3 substrate and the electrodes, and the thickness of the electrodes can be adjusted by varying the depth of the grooves. Therefore, there is substantially no unevenness between electrode-bearing portions and electrode-free portions. Thus, the upper surface of the dielectric layer can be readily planarized and the insertion loss can be reduced.
In addition, the metal material used to define the electrodes is preferably at least one of the metal materials of the first group, those of the second group, and those of the third group and θ of the Euler angles of the LiNbO3 substrate, the thickness of the dielectric layer, and the thickness of the electrodes are within any of the ranges shown in Table 1. Therefore, as shown in the experiments described below, an SH-type boundary acoustic wave can be non-leaky even if the electrodes have a reduced thickness. Thus, a boundary acoustic wave device which utilizes a SH-type boundary acoustic wave and which has low loss can be provided.
When the thickness of the electrodes, θ of the Euler angles, and the thickness of the dielectric layer are any of those shown in Table 2, the loss of the boundary acoustic wave device can be further reduced.
According to the second preferred embodiment, the electrodes are formed preferably by filling the grooves, which are formed in the upper surface of the LiTaO3 substrate, with the metal material and the dielectric layer is provided over the LiNbO3 substrate and the electrodes, and there is substantially no unevenness between electrode-bearing portions and electrode-free portions. Thus, the upper surface of the dielectric layer is flat or substantially flat and the insertion loss can be reduced. In addition, the material used to define the electrodes is preferably at least one of metal materials such as Al, Cu, Au, Ta, and Pt and the thickness of the electrodes, θ of the Euler angles of the LiTaO3 substrate, and the thickness of the dielectric layer are within any of the ranges shown in Table 2. Therefore, an SH-type boundary acoustic wave can be non-leaky even if the electrodes have a reduced thickness. Thus, a boundary acoustic wave device which utilizes a SH-type boundary acoustic wave and which has low loss can be provided.
In particular, when the thickness of the electrodes, θ of the Euler angles, and the thickness of the dielectric layer are within any of the ranges shown in Table 4, the loss of the boundary acoustic wave device can be further reduced.
Other features, elements, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
Preferred embodiments of the present invention will be described below with reference to the accompanying drawings
A method for manufacturing a boundary acoustic wave device according to a preferred embodiment of the present invention is described below with reference to
As shown in
A photoresist layer 2 is formed over the upper surface 1a of the LiNbO3 substrate 1. The photoresist layer 2 can preferably be formed from any photoresist material that is resistant to reactive ion etching (RIE) which is performed later. In this example, a positive resist, AZ-1500™, available from Clariant (Japan) K.K., for example, is preferably used. In this example, the thickness of the photoresist layer 2 is preferably about 2 μm.
The photoresist layer 2 is patterned such that the photoresist layer is exposed to light and then developed, whereby a photoresist pattern 2A is formed as shown in
As shown in
Al layers are preferably formed by vapor deposition or sputtering, for example. This allows the Al layers defining electrode layers 3 to be disposed in the grooves 1b as shown in
The LiNbO3 substrate is immersed in a stripping solution preferably including acetone, for example, whereby the photoresist pattern 2A and the Al layer disposed on the photoresist pattern 2A are removed. This enables the grooves 1b to be filled with the electrode layers 3 and enables the LiNbO3 substrate 1 to have a flat or substantially flat upper surface as shown in
As shown in
A process for forming the SiO2 layer 4 is not particularly limited. The SiO2 layer 4 may preferably be formed by an appropriate process such, as a printing process, a vapor deposition process, or a sputtering process, for example.
The method for manufacturing the boundary acoustic wave device 5 of this preferred embodiment is as described above with reference to
In this example, there is substantially no unevenness between electrode-bearing portions and electrode-free portions. Thus, the upper surface of the SiO2 layer 4, which defines a dielectric layer, can be easily and effectively planarized and the insertion loss can be reduced.
The boundary acoustic wave device having low loss can be provided without increasing the thickness of the electrode layers 3. The electrode layers 3 are preferably made of a metal material that is at least one selected from the group consisting of Al, Ti, Ni, Cr, Cu, W, Ta, Pt, Ag, and Au, for example. Al and Ti are grouped into a first group, Ni and Cr are grouped into a second group, Cu, W, Ta, Pt, Ag, and Au are grouped into a third group, the thickness of the electrode layers made of the metal materials assigned to each group, θ of the Euler angles of the LiNbO3 substrate 1, and the thickness of a dielectric layer are within any of the ranges shown in Table 5 below. Therefore, although the electrode layers have a relatively small thickness, the boundary acoustic wave device having low loss can be provided. This is described below in detail using examples.
“RF Filter using Boundary Acoustic Wave” (Proc. Symp. Ultrason. Electron., Vol. 26, pp. 25-26 (2005/11)) describes that the SH-type boundary acoustic wave is non-leaky in a SiO2/electrodes/y-cut X-propagation LiNbO3 multilayer structure when the electrodes are made of Al and have a thickness of at least 0.16λ or when the electrodes are made of Au, Cu, or Ag and have a thickness of at least 0.04λ.
However, experiments conducted by the inventors have shown that an SH-type boundary acoustic wave can be non-leaky in the boundary acoustic wave device 5 of this preferred embodiment although the electrode layers 3, which are defined by the metal material filled in the grooves 1b, have a smaller thickness. This is described below with reference to
As shown in
In the boundary acoustic wave devices 5, θ of the Euler angles (0°, θ, 0°) of each LiNbO3 substrate is varied and IDT electrodes are made of the corresponding metal materials of the first to third groups.
As shown in
In the boundary acoustic wave devices 5, dielectric layers defined by SiO2 layers 4. The following relationship was determined using LiNbO3 substrates with Euler angles (0°, 103°, 0°): the relationship between the normalized thickness H/λ of the dielectric layers defined by the SiO2 layers 4 and the electromechanical coefficient k2 of SH-type normalization. The results are shown in
The results of electrode layers 3 made of Al, Ni, and Cu are shown in
As shown in
The results shown in
When any of the ranges shown in Table 12 below is satisfied, propagation loss can be further reduced.
In the boundary acoustic wave device 5 of this preferred embodiment, the electrode layers 3 including IDT electrodes are formed by filling the grooves 1b, disposed in the upper surface of the LiNbO3 substrate 1, with the metal material. According to this structure, the absolute value of a temperature coefficient of frequency TCF can be reduced and frequency-temperature characteristic can be improved as compared to those of comparative examples in which IDT electrodes are formed on LiNbO3 substrates without filling grooves with any metal material. This is shown in
As shown in
In this preferred embodiment, the dielectric layer is preferably defined by the SiO2 layer 4, for example, but may preferably be made of silicon oxide other than SiO2.
Although the LiNbO3 substrates were preferably used in the preferred embodiments described above, LiTaO3 substrates are used in the preferred embodiments described below. A plurality of grooves 1b were formed in the upper surfaces of the LiTaO3 substrates in the same or substantially the same manner as that described with reference to
Electromechanical coefficients were determined such that LiTaO3 with Euler angles (0°, 126°, 0°) were used to prepare the LiTaO3 substrates and the thickness of the electrodes and the type of metal material used for the electrodes were varied. The obtained results are shown in
As shown in
The results shown in
The analysis of the data in Tables 13 to 22 shows that a boundary acoustic wave device having low loss is obtained if any of the ranges shown in Tables 23 and 24 is satisfied. More preferably, any of the ranges shown in Table 24 is satisfied because the loss thereof is further reduced.
In the preferred embodiments described above, the IDT electrodes are preferably made of a single metal such as Al or Au, for example. However, the IDT electrodes may preferably have a multilayer structure in which an electrode layer primarily including such a metal is disposed on another electrode layer made of another metal material.
The dielectric layers may preferably be made of another dielectric material having an acoustic wave velocity of a transverse wave greater than that of the electrodes. Examples of such a dielectric material include glass, SixNy, SiC, and Al2O3. When the dielectric layers are made of any one of these materials, the thickness thereof may be determined in inverse proportion to the acoustic wave velocity of a transverse wave of SiO2.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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2006-278970 | Oct 2006 | JP | national |
Number | Name | Date | Kind |
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7322093 | Kadota et al. | Jan 2008 | B2 |
7550898 | Kadota et al. | Jun 2009 | B2 |
7581306 | Kadota et al. | Sep 2009 | B2 |
7688161 | Miura et al. | Mar 2010 | B2 |
Number | Date | Country | |
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20100320866 A1 | Dec 2010 | US |
Number | Date | Country | |
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Parent | 12420944 | Apr 2009 | US |
Child | 12862843 | US | |
Parent | PCT/JP2007/067583 | Sep 2007 | US |
Child | 12420944 | US |