Patent Description:
Piezoelectric devices, which make use of the piezoelectric effect of substances, have conventionally been adopted. The piezoelectric effect is a phenomenon in which microscopic polarization is produced in response to a mechanical stress applied to a substance. Using the piezoelectric effect, various sensors including pressure sensors, acceleration sensors, and acoustic emission (AE) sensors for detecting elastic waves are commercially available.

Piezoelectric devices are typically formed into a multilayer stack with a piezoelectric layer sandwiched between a pair of electrodes. A structure having electrode films made of a metal alloy such as Ti-alloy, Mg-alloy, Al-alloy, Zn-alloy or the like is proposed. With this structure, the Young's modulus of the electrode films is set smaller than that of the piezoelectric layer. See, for example, Patent Document <NUM> presented below. It is described in this document that the electrode films preferably have an unoriented or amorphous structure.

A multilayer stack with a piezoelectric layer sandwiched between a pair of electrodes is generally fabricated on a substrate, from the viewpoint of structural stability and convenience of fabrication approach. When a plastic or resin substrate is used, the surface of the substrate tends to be rough or uneven. Such surface roughness or unevenness of the substrate is hardly absorbed by the metal crystal of the subsequently formed electrode, and in fact, the surface of the metal electrode formed on the uneven substrate becomes uneven. The unevenness or pinholes present in the metal surface may cause cracks in a piezoelectric layer formed over the metal film, and leakage current paths may be created between the top and bottom electrodes. Such leakage current paths diminish the electric charges produced by polarization and accumulated at the interfaces of the piezoelectric layer, and consequently, the piezoelectric effect may not be exhibited.

Devices and methods of the prior art are described in <CIT>; <CIT>; <NPL>) and in <CIT>.

One of the objectives of the present invention is to suppress a leakage current path and provide a piezoelectric device having a satisfactory piezoelectric characteristic and a method of manufacturing the same.

In one aspect of the invention, a device according to claim <NUM> is provided. In another aspect of the invention, a method according to claim <NUM> is provided.

In an example configuration, the thickness of the first electrode may range from <NUM> to <NUM>, and more preferably, <NUM> to <NUM>.

With the above-described configuration, the leakage current path can be suppressed, and a piezoelectric device with a satisfactory piezoelectric characteristic can be achieved.

In general, when a piezoelectric layer is formed of a wurtzite material such as zinc oxide (ZnO), it is believed that depositing a crystal film under the piezoelectric layer is desirable because a wurtzite layer can be grown with a good crystal orientation, reflecting the underlayer crystal structure.

It is also assumed that the piezoelectric layer should have a certain degree of thickness in order to secure the crystal orientation of the piezoelectric layer. However, increasing the thickness of the piezoelectric layer tends to cause cracking or crazing in the piezoelectric layer. In particular, when the surface of the underlaid metal electrode is uneven, cracks or pinholes are likely to appear after the piezoelectric layer has been fabricated.

" Cracks or crazing produced in the piezoelectric layer will cause leakage current paths. Due to the leakage current path, the electric charges generated by polarization disappear and the piezoelectric characteristics are impaired.

In the embodiments to be described below, of the pair of electrodes sandwiching the piezoelectric layer, at least an electrode provided between the substrate and the piezoelectric layer, which may be referred to as a "bottom electrode", is configured to be an amorphous transparent oxide conductor. This configuration can absorb the unevenness or roughness of the substrate surface, thereby suppressing leakage current paths and achieving satisfactory piezoelectric characteristics.

<FIG> is a schematic diagram of a piezoelectric device <NUM>. The piezoelectric device <NUM> is applied to, for example, a piezoelectric pressure sensor configured to detect a pressure applied to the device and output the detection result as an electric signal. The piezoelectric device <NUM> has a multilayer stack <NUM>, in which a first electrode <NUM>, a piezoelectric layer <NUM>, and a second electrode <NUM> are stacked in this order, on a substrate <NUM>. The term "on" the substrate <NUM> does not means the absolute direction, and it simply represents an upper side in the stacking direction relative to the substrate.

In the configuration of <FIG>, the first electrode <NUM> may be called a "bottom electrode" and the second electrode <NUM> may be called a "top electrode. " Of the two electrodes, at least the first electrode <NUM> is fabricated as an amorphous oxide conductor. The amorphous oxide conductor may be "transparent" to visible light, or "transparent" with respect to light having a specified wavelength or falling within a specified wavelength band, depending on the situation.

Examples of the amorphous oxide conductor include, but are not limited to, indium tin oxide (ITO), indium zinc oxide (IZO), indium zinc tin oxide (IZTO), indium gallium zinc oxide (IGZO), etc..

When ITO is used, the tin (Sn) content with respect to the total of Sn and In (i.e., the ratio Sn/(In + Sn)) is, for example, <NUM> to <NUM> wt%. Within this range, the ITO is transparent to visible light and an amorphous film can be formed by sputtering at room temperature.

When IZO is used, the zinc (Zn) content with respect to the total of Zn and In (i.e., the ratio Zn/(In + Zn)) is, for example, around <NUM> wt%. IZO with this Zn content is also transparent to visible light, and an amorphous IZO film can be formed by sputtering at room temperature.

When IZTO is used, the In content with respect to the total of In, Zn and Ti (i.e., the ratio In/(In + Zn + Ti)) is, for example, <NUM> to <NUM> wt%. When IGZO is used, the In content with respect to the total of In, Ga and Ti (i.e., the ratio In/(In + Ga + Zn)) is, for example, <NUM> to <NUM> wt%. Both IZTO and IGZO with the above-described In content are transparent to visible light, and have high carrier mobility. IZTO and IGZO can be formed in amorphous films at room temperature.

Films of these amorphous oxide conductors may be formed in an argon (Ar) atmosphere, or in a mixed gas of Ar and a small quantity of oxygen (O<NUM>). Preferably, the ratio of the O<NUM> flow to the total flow of Ar and O<NUM> ranges from <NUM>% to <NUM>%, and more preferably <NUM>% to <NUM>%. The reasoning for the preferred range of the flow ratio will be explained later.

For the substrate <NUM>, any suitable material may be used. Either an inorganic substrate such as a glass substrate, a sapphire substrate, an MgO substrate, etc., or a plastic substrate may be used. When a plastic substrate is used, and when the first electrode <NUM> of an amorphous transparent oxide conductor is formed over the plastic surface, the advantageous effect of suppressing leakage current paths can be exhibited more significantly. Although the surface of a plastic substrate or a resin substrate tends to be uneven, the first electrode <NUM> of an amorphous oxide conductor can absorb the unevenness of the substrate surface, and can improve the crystal orientation of an upper layer, i.e., the piezoelectric layer to be subsequently formed on the first electrode <NUM>.

When the substrate <NUM> is formed of plastic, polyethylene terephthalate (PET), polyethylene naphthalate (PEN), polycarbonate (PC), acrylic resin, cycloolefin polymer, polyimide (PI) or the like may be used. Among these materials, PET, PEN, PC, acrylic resin, and cycloolefin polymer are colorless and transparent materials, and are suitably used when the first electrode <NUM> is located on the light incident side.

The piezoelectric layer <NUM> is formed of a piezoelectric material having a wurtzite crystal structure, and has a thickness of <NUM> to <NUM>. When the thickness of the piezoelectric layer <NUM> is within this range, cracking or crazing can be suppressed. When the thickness of the piezoelectric layer <NUM> exceeds <NUM>, cracking or crazing is likely to increase, and the haze value (or crystal opacity) is adversely affected.

When the thickness of the piezoelectric layer <NUM> is less than <NUM>, it is difficult to obtain good crystal orientation, and is difficult to achieve satisfactory piezoelectric characteristics (or polarization characteristics according to applied pressure). Preferably, the thickness of the piezoelectric layer <NUM> is <NUM> to <NUM>, and more preferably, <NUM> to <NUM>.

The crystal structure of a wurtzite has general formula AB, where A is a positive element (An+) and B is a negative element (Bn-). It is desirable for a wurtzite piezoelectric material to exhibit piezoelectric characteristics of a certain level or higher and to be crystallized in a low temperature process at or below <NUM>. For example, zinc oxide (ZnO), zinc sulfide (ZnS), zinc selenide (ZnSe), zinc telluride (ZnTe), aluminum nitride (AlN), gallium nitride (GaN), cadmium selenide (CdSe), cadmium telluride (CdTe), silicon carbide (SiC), etc. can be used. Only one of these compounds may be used, or alternatively, a combination of two or more of these compounds may be used.

When two or more of these compounds are combined, each of the selected compounds may be stacked one by one, or a single layer may be formed using multiple targets of the respective compounds. The selected one of the above-described compounds or a combination of two or more compounds may be used as the main component that dominantly forms the wurtzite crystal, and another component may be optionally added as a subcomponent. The percentage or ratio of the subcomponent contained in the main component is not particularly limited as long as the advantageous effect of the present invention is acquired. When a subcomponent is added to the main component, the content of the subcomponent may be <NUM> at. % to <NUM> at. %, preferably, <NUM> at. % to <NUM> at. %, and more preferably, <NUM> at. % to <NUM> at.

In one example, a wurtzite material formed of ZnO or AlN as the main component is used. A metal that does not exhibit conductivity when added to the main component (ZnO, AlN, etc.) may be used as a dopant or a subcomponent. Examples of such a metal dopant include, but not limited to silicon (Si), magnesium (Mg), vanadium (V), titanium (Ti), zirconium (Zr), lithium (Li), etc. A single dopant may be added, or a combination of two or more dopants may be added in combination. By adding a metal dopant, the likelihood of cracking or crazing can be reduced. When a transparent wurtzite crystal material is used as the piezoelectric layer <NUM>, it is suitable for application to a display.

Because the piezoelectric layer <NUM> is provided on the first electrode <NUM> that is formed as an amorphous oxide conductor, it is unnecessary to insert a specific crystal-orientation film under the piezoelectric layer <NUM>. This is because the first electrode <NUM> serves not only as the electrode but also as an underlayer for improving the crystal orientation of the piezoelectric layer <NUM>.

The second electrode <NUM> may be formed of an amorphous transparent oxide conductor, or it may be formed of a metal, an alloy, or a non-transparent conductor. When an amorphous transparent oxide conductor is used for the second electrode, it may be made of the same material as the first electrode <NUM>, or it may be made of a different material.

The piezoelectric device <NUM> of <FIG> can be manufactured by the following steps. A first electrode <NUM> is formed as an amorphous oxide conductor on the substrate <NUM>. For the first electrode <NUM>, an ITO film, an IZO film, an IZTO film, an IGZO film, etc. may be formed by direct current (DC) or radio frequency (RF) magnetron sputtering in an Ar atmosphere or in a mixed gas atmosphere with Ar and a predetermined ratio of O<NUM>. Depending on the application of the device, the first electrode <NUM> may be formed as a solid electrode layer, or it may be patterned into a predetermined shape by etching or other suitable process. When the piezoelectric device <NUM> is applied to a pressure sensor used for a touch panel, the first electrode <NUM> may have a pattern of strips extending parallel to the first direction.

Then, the piezoelectric layer <NUM> may be formed on the first electrode <NUM> by, for example, RF magnetron sputtering using a ZnO target in a mixed gas atmosphere of Ar and a small quantity of O<NUM>. The thickness of the ZnO piezoelectric layer <NUM> is <NUM> to <NUM>. The temperature of forming the ZnO film is not necessarily room temperature as long as the amorphous state is maintained in the first electrode <NUM>. The ZnO film may be formed at, for example, a substrate temperature of <NUM> or lower.

By using the sputtering method for forming the first electrode <NUM> and the piezoelectric layer <NUM>, uniform films having good adhesion can be formed, while maintaining the composition ratios of the targets almost unchanged. In addition, films with desired thicknesses can be formed accurately by simply controlling the sputtering time.

Next, the second electrode <NUM> is formed in a predetermined pattern on the piezoelectric layer <NUM>. For the second electrode <NUM>, an ITO film with a thickness of <NUM> to <NUM> is formed at room temperature by, for example, DC or RF magnetron sputtering. The second electrode <NUM> may be formed over the entire surface of the substrate. Alternatively, when the first electrode <NUM> is patterned into stripes, the second electrode <NUM> may also be patterned into stripes extending in the direction orthogonal to the stripes of the first electrode <NUM>. Thus, the piezoelectric device <NUM> can be fabricated. The characteristics of the fabricated piezoelectric device <NUM> are examined using several samples.

<FIG> is a schematic diagram of a sample <NUM> used for characteristic evaluation. The first electrode <NUM> and the piezoelectric layer <NUM> are provided in this order on the substrate <NUM>. The substrate <NUM> is a PET film with a thickness of <NUM>. The first electrode <NUM> is a thin film of an amorphous oxide conductor formed by magnetron sputtering at room temperature. For the characteristic measurement described later, three types of samples <NUM> having different materials and different thicknesses of the first electrode <NUM> are fabricated. In addition, two other samples <NUM> are fabricated changing the flow ratio of Ar and O<NUM> when forming the first electrode <NUM>.

The piezoelectric layer <NUM> is a ZnO film with a thickness of <NUM> grown at room temperature. Samples <NUM>, each having a size of <NUM> × <NUM>. In the characteristic measurement of the samples <NUM>, the crystal orientation of the piezoelectric layer <NUM>, the haze value (or the opacity), and the d33 value representing a piezoelectric characteristic, are measured.

The crystal orientation is determined by the X-ray rocking curve (XRC) method, measuring the reflection from (<NUM>) plane of the ZnO film. The locking curve of the (<NUM>) reflection represents the fluctuation of the orientation of the crystal axis of ZnO in the c-axis direction. The smaller the full width at half maximum (FWHM) of the X-ray locking curve, the better the c-axis orientation of the crystal.

The haze value (or the opacity) indicates the degree of opacity of a crystal, and is represented as the percentage of the scattered component of the light passing through the material to the total transmitted light. The smaller the haze value, the higher the transparency. A haze meter manufactured by Suga Test Instruments Co. is used to measure the haze.

Parameter d33 represents contraction or expansion in the thickness direction, which is defined by the amount of polarization charges per unit pressure applied in the thickness direction. The d33 parameter is often called "piezoelectric coefficient". The higher the d33 value, the better the polarization characteristic in the thickness direction.

<FIG> illustrates a setup for measuring the d33 parameter. As the measuring instrument <NUM>, a piezometer PM300 manufactured by Piezotest Limited is used to directly measure d33 values. Prior to the measurement, aluminum (Al) films <NUM> and <NUM> are provided to the bottom and the top of the sample <NUM>, respectively, by attaching aluminum foil onto the back face of the substrate <NUM> and the top face of the piezoelectric layer <NUM>. The sample <NUM> with Al films <NUM> and <NUM> is placed between the electrodes <NUM> and <NUM> of the measuring instrument <NUM>.

A load is applied at a low frequency by the indenter <NUM> to the sample <NUM> from the upper side of the piezoelectric layer <NUM>, and the amount of electric charges generated is measured by the coulomb meter <NUM>. The value calculated by dividing the measured electric charges by the applied load is d33.

<FIG> shows the evaluation results of five samples. Sample No. <NUM> to Sample No. <NUM> are prepared changing the material and the thickness of the first electrode <NUM>, while fixing the percentage of the O<NUM> flow in the total atmosphere containing Ar and O<NUM> to <NUM>%. Sample No. <NUM> and Sample No. <NUM> are prepared by changing the flow ratio of O<NUM> with respect to the total atmosphere when forming the first electrode <NUM>. The sample parameters to be considered include the material and the thickness of the first electrode <NUM>, the flow ratio O<NUM>/(Ar+O<NUM>), the c-axis orientation of the piezoelectric layer <NUM>, the haze (opacity), and the d33 value. Together with the measurements of the c-axis orientation, haze, and d33, evaluations are marked with symbols. The evaluation with a good score is marked with a double circle (⊚), the evaluation with an acceptable score is marked with an open circle (○), and the evaluation out of the acceptable range is marked with a cross marks (×).

In Sample No.<NUM>, an IZO film with a thickness of <NUM> is formed as the first electrode <NUM> on a PET film substrate <NUM>, and a ZnO film with a thickness of <NUM> is provided on the IZO film. The ratio of Zn to the total of In and Zn in the IZO film is <NUM> wt%.

The FWHM of X-ray rocking curve (XRC) of Sample No. <NUM> is <NUM>°, which is within an acceptable range for c-axis orientation. The haze value is <NUM>%, and transparency is sufficient. The d33 value is <NUM> (pC/N), and the polarization characteristic in the thickness direction is good.

In Sample No. <NUM>, an IZO film with a thickness of <NUM> is formed as the first electrode <NUM> on the PET film substrate <NUM>, and a ZnO film with a thickness of <NUM> is provided on the IZO film. The ratio of Zn to the total of In and Zn in the IZO film is <NUM> wt%.

The FWHM of XRC of Sample No. <NUM> is as small as <NUM>°, which shows good c-axis orientation. The haze value is <NUM>%, and transparency is sufficient. The d33 value is <NUM> (pC/N), and the polarization characteristic in the thickness direction is very good.

The FWHM of XRC of Sample No. <NUM> is <NUM>°, which shows good c-axis orientation. The haze value is <NUM>%, and transparency is sufficient. The d33 value is <NUM> (pC/N), and the polarization characteristic in the thickness direction is good.

In Sample No. <NUM>, an ITO film with a thickness of <NUM> is formed as the first electrode <NUM> on the PET film substrate <NUM>, and a ZnO film with a thickness of <NUM> is provided on the ITO film. The ratio of Sn to the total of In and Sn in the ITO film is <NUM> wt%. The source gas for forming the first electrode <NUM> is Ar gas only (which means that the O<NUM> flow ratio is zero percent).

The FWHM of XRC of Sample No. <NUM> is <NUM>°, which is in the acceptable range for c-axis orientation. The haze value is <NUM>%, and the sample is highly transparent. The d33 value is <NUM> (pC/N), and the polarization characteristic in the thickness direction is good.

In Sample No. <NUM>, an ITO film with a thickness of <NUM> is formed as the first electrode <NUM> on the PET film substrate <NUM>, and a ZnO film with a thickness of <NUM> is provided on the ITO film. The ratio of Sn to the total of In and Sn in the ITO film is <NUM> wt%. The oxygen ratio in the source gas for forming the first electrode <NUM>, namely, the flow ratio of O<NUM> with respect to the total of Ar and O<NUM> is <NUM>%.

The FWHM of XRC of Sample No. <NUM> is as small as <NUM>°, which shows good c-axis orientation. The haze value is <NUM>%, and the sample is highly transparent. The d33 value is <NUM> (pC/N), and the polarization characteristic in the thickness direction is good.

From the results of Sample Nos. <NUM> and <NUM>, it is understood that with a small amount of O<NUM> gas mixed in the source gas for forming the transparent conductive film, the amorphous state of the conductive electrode film is maintained, and that the c-axis orientation and transparency of the subsequently formed piezoelectric layer are improved.

All of the five samples (Sample No. <NUM> to Sample No. <NUM>) exhibit good or acceptable c-axis orientation of the ZnO piezoelectric layer <NUM>. This is because by forming the first electrode <NUM> as an amorphous oxide conductor, the crystal orientation of the ZnO film grown on the first electrode <NUM> is improved.

Besides, when the first electrode <NUM> is formed as an amorphous oxide conductor on the substrate <NUM> made of a resin or plastic, it is inferred that the unevenness of the surface of the resin or plastic substrate <NUM> is absorbed by the upper layer electrode, and that the surface roughness of the first electrode <NUM> is reduced. The grain boundaries are reduced at the interface between the first electrode <NUM> and the piezoelectric layer <NUM>, and cracking or leakage current paths are suppressed.

From the above, it is understood that by selecting the film thickness of the first electrode <NUM> of an amorphous oxide conductor from the range at least <NUM> to <NUM>, the crystallinity and piezoelectric characteristics of the piezoelectric layer <NUM> provided on the first electrode <NUM> are improved. When a predetermined quantity of O<NUM> gas is mixed in the Ar gas flow during the film formation of the first electrode <NUM>, the transparency of the electrode is improved, while maintaining the amorphous state. An appropriate range of the O<NUM> flow ratio for maintaining the amorphous state will be described later with reference to <FIG>.

<FIG> shows measurement results of other configurations for comparisons. Comparative Examples <NUM> and <NUM> show the crystal characteristics and piezoelectric characteristics of ZnO when a metal electrode is formed on the substrate <NUM>. Comparative Example <NUM> shows the crystal characteristics and piezoelectric characteristics of ZnO when a crystalline ITO film is formed on the substrate <NUM>. In Comparative Example <NUM>, the oxygen content in the source gas during film formation of the first electrode <NUM> is <NUM>%. The material and the thickness of the substrate <NUM> are the same as those in the sample <NUM> of the example.

In Comparative Example <NUM>, a Ti film having a thickness of <NUM> is formed on the substrate <NUM>, and a ZnO film is formed as the piezoelectric layer <NUM> on the Ti film. The XRC-FWHM of Comparative Example <NUM> is <NUM>°, which is broader than those of Sample No. <NUM> to Sample No. <NUM> of the above-described examples, whereas the c-axis orientation is within the acceptable range. Regarding the transparency of the crystal, opacity is visually observed, and the sample is not transparent even without measuring the haze value.

As for the d33 value, no polarization is sensed at the resolution of the measuring instrument used, which means that the piezoelectric characteristic is poor. This comparative configuration cannot be applied to a piezoelectric sensor.

In Comparative Example <NUM>, an Al film having a thickness of <NUM> is formed on the substrate <NUM>, and a ZnO film is formed as the piezoelectric layer <NUM> on the Al film. The XRC-FWHM of Comparative Example <NUM> is as broad as <NUM>°, and the c-axis orientation is out of the acceptable range. Regarding the transparency of the crystal, opacity is visually observed, and the sample is not transparent even without measuring the haze value. As for the polarization characteristics, no polarization is sensed by the measuring instrument used, and therefore, d33 is zero.

<FIG> is a diagram for explaining the reason for the deficiency in the d33 value in Comparative Examples <NUM> and <NUM>. With a plastic or resin substrate <NUM>, the surface tends to become uneven due to the film formation process or the flexibility of the material itself. When a metal electrode film <NUM> is formed on the uneven surface of the substrate <NUM>, the metal crystal of the electrode film <NUM> cannot sufficiently absorb the unevenness of the substrate surface, and protrusions are formed in the surface of the electrode film <NUM>.

When the piezoelectric layer <NUM> is formed on the metal electrode film <NUM>, cracks <NUM> may occur in the piezoelectric layer <NUM> due to the uneven surface of the electrode film <NUM>. Thereby leakage current paths are produced between the upper electrode (for example, Al film) and the metal electrode films <NUM>. As a result, the electric charge generated by polarization are canceled and the d33 value cannot be obtained.

In Comparative Example <NUM>, a crystalline ITO film with a thickness of <NUM> is formed on the substrate <NUM>, and a ZnO layer is formed as the piezoelectric layer <NUM> on the crystalline ITO film. With the oxygen content of <NUM>% in the source gas during film formation of the ITO film, the resultant ITO film becomes crystalline. The FWHM of XRC of Comparative Example <NUM> is as broad as <NUM>°, and the c-axis orientation is out of the acceptable range. When the underlaid electrode film is crystalline, the electric charges generated at the interface of the ZnO layer cannot be detected at the resolution of the measuring instrument used, and d33 value cannot be acquired. On the other hand, because the ITO film is used, the haze value is as high as <NUM>, and transparency is obtained.

<FIG> shows the measurement results of samples prepared under different O<NUM>/Ar flow ratios, measured by grazing incidence X-ray diffraction (GIXD). An ITO film is formed on a PET substrate by changing the ratio of O<NUM> flow to the total flow of Ar gas and O<NUM> to <NUM>%, <NUM>%, <NUM>%, and <NUM>%. Crystalline ITO is defined as one in which multiple peaks from lattice plane orientations are observed by the GIXD method in an as-depo state without thermal annealing after the film formation.

When the O<NUM> ratio to the total flow of Ar gas and O<NUM> is <NUM>%, many peaks are observed at different lattice plane orientations, and in particular, the peak at the (<NUM>) crystal plane is prominent. The small peak appearing at <NUM> degrees of 2θ is a peak derived from the PET substrate.

When the O<NUM> ratio to the total flow of Ar gas and O<NUM> is set to <NUM>% and <NUM>%, the measurement profiles are almost flat except for the small peaks derived from the PET. Accordingly, the prepared ITO films are amorphous. When the O<NUM> ratio to the total flow of Ar gas and O<NUM> is <NUM>%, there is a small peak observed only at the (<NUM>) crystal plane, but the peak intensity is less than that of the peak originating from the PET. In this case, it is determined that the film is amorphous.

From this measurement result, the ratio of the O<NUM> flow to the total flow of Ar gas and O<NUM> is set to <NUM>% to <NUM>%, and more preferably <NUM>% to <NUM>%. With this range, the first electrode <NUM> becomes amorphous, which can improve the c-axis orientation, transparency, thereby improving the piezoelectric characteristics of the upper piezoelectric layer.

Comparing the examples of <FIG> and the comparative configurations of <FIG>, it is preferred that at least the electrode provided between the substrate <NUM> and the piezoelectric layer <NUM> is formed of an amorphous oxide conductor. With this arrangement, the crystal orientation and piezoelectric characteristics of the piezoelectric layer <NUM> are improved, and a high-quality piezoelectric device can be achieved. An amorphous electrode film can be acquired by setting the oxygen content of the source for forming the oxide conductor film to <NUM>% or less, and more preferably, to <NUM>% or less.

Although the present invention has been described based on specific examples, the invention is not limited to the above-described configurations and fabrication processes. For example, when the first electrode is formed of an amorphous oxide conductor, water may be introduced during the sputtering process to form a low resistance amorphous film on the substrate <NUM>.

The multilayer stack including the electrode of an amorphous oxide conductor and the piezoelectric layer <NUM> of the invention is applicable not only to a piezoelectric sensor, but also to a piezoelectric device such as a speaker or an oscillator making use of the inverse piezoelectric effect. When an alternating current electric signal is applied to the piezoelectric layer <NUM>, mechanical vibration is generated in the piezoelectric layer <NUM> according to its resonance frequency. Owing to the presence of the amorphous first electrode <NUM> under the piezoelectric layer, the c-axis orientation and polarization characteristics of the piezoelectric layer <NUM> are good, and the operating accuracy as a piezoelectric device can be improved.

Claim 1:
A piezoelectric device (<NUM>) comprising:
a multilayer stack (<NUM>) in which a first electrode (<NUM>), a piezoelectric layer (<NUM>), and a second electrode (<NUM>) are stacked in this order on a substrate (<NUM>),
characterised in that at least the first electrode (<NUM>) is formed of an amorphous oxide conductor,
wherein the piezoelectric layer (<NUM>) has a wurtzite crystal structure, and
wherein a d33 value of the piezoelectric layer (<NUM>) ranges from <NUM> to <NUM> pC/N.