JP5007973B2 - Thin film manufacturing method - Google Patents

Description

  The present invention relates to a method of manufacturing a thin film made of a material having a wurtzite type crystal structure (wurtzite structure) such as ZnO or AlN used as a piezoelectric body.

  In order to improve the performance of a measuring instrument in ultrasonic measurement, a transducer with high resolution is required. The transducer is an element that excites or detects acoustic surface waves and bulk waves, and the measurement transducer is mainly used for measurement of material constants, exploration of defects and scratches in the medium, measurement of stress, and the like. In general, a transducer is a piezoelectric body having a piezoelectric effect, which is a phenomenon in which polarization changes as a distortion is applied by sound waves. Since the spatial resolution of the measurement system is inversely proportional to the sound speed and proportional to the operating frequency, in order to perform the above measurement with a high resolution, (i) a transverse wave whose sound speed is slower than the longitudinal wave is used, and (ii) in the high frequency region Excitation and detection must be performed. Therefore, a high-frequency transverse wave transducer is required in the measurement field.

  Further, with the miniaturization of mobile communication devices such as mobile phones, there is a demand for miniaturization of signal processing devices used for them. One such device is the SAW (Surface Acoustic Wave) device. In the SAW device, a Rayleigh wave that is a composite wave of a longitudinal wave and a transverse wave that propagates on a piezoelectric film has been conventionally used. Since the Rayleigh wave is attenuated when it is reflected by the end face of the piezoelectric film, it has conventionally been necessary to provide a reflector to prevent this attenuation. On the other hand, in recent years, an SH type SAW device using a surface SH (shear-horizontal) wave composed only of a transverse wave component vibrating in parallel with a piezoelectric film has been used. Since the surface SH wave is totally reflected at the end face of the piezoelectric film, this SH type SAW device does not need to be provided with a reflector as in the prior art, and can be made smaller than before.

A piezoelectric body having a wurtzite structure such as ZnO (zinc oxide) or AlN (aluminum nitride) is preferably used as the piezoelectric body used in the transducer using these transverse waves and the surface SH wave device. As shown in FIG. 1, a piezoelectric body having a wurtzite structure has a hexagonal unit cell and is composed of a layer (A layer) composed of A ^{n +} (Zn ²⁺ , Al ^3+, etc.) and B ⁿ⁻ (O ^{2 -} , N ^3- etc.) Layers (B layers) are alternately stacked. The B layer is at a position shifted in the c-axis direction from the center of the upper and lower A layers. Due to this crystal structure, a piezoelectric body having a wurtzite structure has a characteristic that it has spontaneous polarization (polarity) in a direction parallel to the c-axis even when no external electric field is applied. Therefore, the c-axis is oriented in one direction in the plane of the wurtzite piezoelectric thin film (that is, parallel to the thin film), and the wurtzite piezoelectric thin film is sandwiched between two electrodes in a direction perpendicular to the thin film. A transverse wave is excited by applying an oscillating electric field. Hereinafter, a wurtzite thin film in which the c-axis is oriented in one direction in the plane is referred to as “in-plane uniaxially oriented wurtzite thin film”.

  When a wurtzite thin film is produced by a commonly used method such as sputtering, the c-axis is usually oriented in a direction perpendicular to the thin film. On the other hand, as described in Patent Document 1, an in-plane uniaxially oriented wurtzite thin film can be produced by depositing a thin film material on a substrate on which a temperature gradient is formed. Further, in Patent Document 2, a flow in one direction (raw material flow) of a thin film raw material having a density gradient in a direction orthogonal to the flow is formed, and the substrate is upstream on the high density side of the raw material flow. It is described that an in-plane uniaxially oriented wurtzite thin film can be produced by inclining and arranging in the raw material flow so as to be on the downstream side on the low density side.

Japanese Patent No. 3561745 ([0020] to [0031], FIG. 3) JP 2006-083010 A ([0027] to [0033], FIGS. 2 and 3)

  In the c-axis in-plane oriented wurtzite thin film produced by the above method, the c-axis is basically oriented in one direction in the plane as described above, but strictly speaking, the c-axis is slightly in the direction of the orientation. Variation is seen. It is expected that the characteristics of SAW devices and the like can be improved by increasing the accuracy of this orientation.

  The problem to be solved by the present invention is to provide a method for producing a wurtzite thin film in which the c-axis is oriented in one direction in the plane of the thin film with higher accuracy than before.

The method for producing a thin film according to the present invention, which has been made to solve the above problems, is a method for producing a thin film having a wurtzite type crystal structure and having a c-axis oriented in one direction in the plane.
When depositing the thin film on the substrate surface, the ion beam is irradiated such that a portion of the at least the ion beam is incident on the substrate surface at an angle less than 10 ° with respect to the substrate surface, of said ion beam The target is sputtered by causing a part of the ion beam not incident on the substrate surface to enter the target made of the thin film material, and the sputtered thin film material is deposited on the substrate surface.

In the present invention, an ion beam incident at an angle of less than 10 ° with respect to the substrate surface has the effect of orienting the c-axis of the crystal constituting the thin film in one direction in the plane. Here, the ion beam incident in this way may include a part or all of the raw material of the thin film, or may be independent of them. When the ion beam includes a part or all of the thin film raw material, the ion beam is also used for thin film deposition. As the thin film raw material, conventionally known raw materials used for manufacturing a thin film having a wurtzite type crystal structure can be used as they are.

  When manufacturing a ZnO thin film, it is desirable to use an oxygen ion beam as the ion beam when manufacturing a ZnO thin film, and a nitrogen ion beam when manufacturing an AlN thin film.

According to the present invention, when a material having a wurtzite structure is deposited on the substrate surface, the ion beam is incident at an angle of less than 10 ° that is parallel to the substrate surface, whereby the ion beam is incident on the substrate surface. A thin film with the c-axis oriented along the orthogonal projection is formed. Thereby, a wurtzite thin film in which the c-axis is highly oriented in one direction in the plane of the thin film can be produced. Since the direction of the ion beam can be controlled more precisely than the direction of the temperature gradient in the conventional method or the direction of the density gradient of the raw material flow and the raw material flow, the method of the present invention increases the degree of orientation compared to the conventional method. be able to.

  Simply prepare the target by sputtering the target using a part of the ion beam that is not incident on the substrate surface (deviated from the substrate surface) (ion beam sputtering method). Although a thin film material can be deposited on the surface of the substrate, the manufacturing apparatus can be simplified by doing so. In the present invention, sputtering may be performed using an ion beam different from the incident beam on the substrate surface. Further, a magnetron sputtering method, a vapor deposition method, or the like, which is a method other than the ion beam sputtering method, may be used.

One embodiment of the thin film manufacturing method according to the present invention will be described with reference to FIG.
FIG. 2 is a schematic configuration diagram of the first thin film manufacturing apparatus 10 used in the present embodiment. An ion source 12 is provided in the vacuum chamber 11. The ion source 12 generates an ion beam and emits the ion beam into the vacuum chamber 11 in one direction. In addition, a substrate holder 13 for fixing a substrate 21 which is a base for producing a thin film is provided in the vacuum chamber 11. The substrate holder 13 can fix the substrate 21 such that a portion of the ion beam is incident on the surface of the substrate 21 at an angle of 10 ° or less. Usually, there is a spread of about 10 ° in the direction in which ions fly in the ion beam. Thus, by making the ion beam incident at an angle of 10 ° or less with respect to the substrate surface in this way, at least a part of the ions are allowed to enter. Incident light can be incident on the substrate surface at an angle close to parallel.

  Furthermore, a target holder 14 for fixing a target 22 that is a solid made of a thin film material is provided downstream of the ion beam from the substrate 21. For the target 22, a raw material that is conventionally used for manufacturing a thin film having a wurtzite crystal structure can be used as it is. For example, in the case of producing an in-plane uniaxially oriented ZnO thin film, as described in Patent Documents 1 and 2, a target made of a ZnO sintered body for performing magnetron sputtering can be used.

  On the wall surface of the vacuum chamber 11, a discharge port 15 for discharging the gas in the vacuum chamber 11 using a pump (not shown) and a gas introduction port 16 for introducing the gas into the vacuum chamber 11 are provided. The gas inlet 16 is used when the raw material for the thin film needs to be supplied in a gas (with the target 22).

  A method for producing a wurtzite thin film using the first thin film production apparatus 10 will be described. The substrate 21 is attached to the substrate holder 13 and the target 22 is attached to the target holder 14. Then, an ion beam is emitted from the ion source 12. Thereby, a part of the ion beam is incident on the surface of the substrate 21 at an angle θ of 10 ° or less (FIG. 3) with respect to 211, and the other part is incident on the target 22. Hereinafter, the former partial ion beam is referred to as a substrate incident beam 24, and the latter partial ion beam is referred to as a target incident beam.

  The target 22 is sputtered by the incidence of the target incident beam, whereby particles made of a thin film material jump out of the target 22. Of these raw material particles, those reaching the surface of the substrate 21 are deposited on the surface of the substrate 21. At that time, since the substrate incident beam 24 is incident on the surface of the substrate 21 at an angle close to parallel and directed in one direction, as shown in a longitudinal sectional view in FIG. 24 are deposited so that the c-axis is oriented along an orthogonal projection 25 (thick broken line in FIG. 3) onto the surface 211 of the substrate 21. Thereby, an in-plane uniaxially oriented wurtzite thin film in which the c-axis is oriented in the direction of the orthogonal projection 25 can be obtained.

  When a ZnO thin film is manufactured, there is a high tendency for oxygen atoms in crystals constituting the material to be deficient, and thus there is a tendency for oxygen atoms to be deficient in the manufactured ZnO thin film. Therefore, it is desirable to use an oxygen ion beam in the method of the present invention. Thereby, since oxygen atoms can be supplied not only by the raw material but also by an ion beam, a high-quality ZnO thin film with few oxygen vacancies can be manufactured. At the same time, the concentration of oxygen ions on the surface of the substrate increases toward the upstream side of the oxygen ion beam (FIG. 4), so that the ZnO crystal grows easily toward the upstream side, thereby further increasing the degree of orientation of the c-axis. Can be increased.

  Similarly, when manufacturing a thin film other than a ZnO thin film, by using an ion beam containing ions composed of atoms as the material of the thin film, defects in the atoms can be suppressed and the degree of orientation of the c-axis is increased. be able to. For example, it is desirable to use a nitrogen ion beam when manufacturing an AlN thin film.

  In the present invention, it is of course possible to produce a ZnO thin film using an ion beam other than an oxygen ion beam, and to produce an AlN thin film using an ion beam other than a nitrogen ion beam. For example, an ion beam generated from argon, which is relatively inexpensive, can be used in the present invention.

  Another embodiment of the thin film manufacturing method according to the present invention will be described with reference to FIG. In the second thin film manufacturing apparatus 30 used in the thin film manufacturing method of the present embodiment, instead of the target holder 14 in the first thin film manufacturing apparatus 10, an evaporation source 31 that evaporates (or sublimates) the raw material of the thin film is vacuumed. This is provided below the substrate holder 13 in the chamber 11. Other configurations are the same as those of the first thin film manufacturing apparatus 10.

  In the second thin film manufacturing apparatus 30, a thin film material is supplied to the substrate surface by the evaporation source 31. Therefore, the ion source 12 has only the role of making the ion beam incident on the substrate. Except for this raw material supply method, the thin film manufacturing method of the present embodiment is the same as the thin film manufacturing method when the first thin film manufacturing apparatus 10 is used.

  When ZnO is produced using the second thin film manufacturing apparatus 30, an apparatus for heating ZnO can be used as the evaporation source 31. When ZnO is heated to 600 ° C. or higher, sublimated Zn atoms and oxygen gas are generated from the evaporation source 31. When the sublimated Zn reaches the surface of the substrate 21, if there is not enough oxygen gas or oxygen ions in the vicinity of the surface, the ZnO thin film is not formed or even if formed, a large number of oxygen atoms are lost. . Therefore, by using an oxygen ion beam as described above, an in-plane uniaxially oriented ZnO thin film with fewer oxygen vacancies can be formed on the surface of the substrate 21 by sublimated Zn and oxygen ions.

A first embodiment of the thin film manufacturing method according to the present invention will be described with reference to FIGS.
In the first embodiment, in the first thin film manufacturing apparatus 10, an oxygen gas is introduced from the ion source 12 to the substrate 21 and the target 22 at an accelerating voltage of 3 kV while oxygen gas is introduced into the vacuum chamber 11 from the gas inlet 16. Released towards. As the substrate 21, a glass plate having a Cu (copper) thin film deposited thereon was used. This Cu thin film becomes an electrode when the produced ZnO thin film is used as an element such as a transducer. A ZnO sintered body was used for the target 22. The incident angle of the ion beam on the substrate 21 was set to 5 ° or less.

  For the ZnO thin film prepared according to this example, an experiment was conducted to detect Bragg reflection on the (11-22) plane by pole X-ray diffraction. In this experiment, the X-ray intensity detected by the detector was measured while changing the elevation angle ψ and azimuth angle φ of the thin film by rotating the ZnO thin film using an X-ray having a wavelength of 0.154 nm. At that time, the X-ray source is fixed so that the X-ray is incident on the surface at an angle θ = 33.98 ° with respect to the surface of the thin film when ψ = 0 ° and φ = 0 °. The detector was fixed to detect X-rays diffracted at an angle of 2θ = 67.96 °. Here, the value θ = 33.98 ° is the Bragg angle in the (11-22) plane of ZnO. The value φ was defined as 0 when the plane including the incident X-rays and the diffracted X-rays and the orthographic projection 25 in the production of the ZnO thin film were parallel. If the c-axis of the obtained ZnO thin film is an in-plane uniaxially oriented ZnO thin film oriented along the orthogonal projection of the ion beam, the (11-20) plane parallel to the c-axis and the above (11-22) plane Since they intersect at an angle of 32 °, Bragg reflection on the (11-22) plane will be observed when ψ = 32 ° and φ is either 90 ° or 270 °. On the other hand, if the c-axis is in an arbitrary direction in the plane, Bragg reflection on the (11-22) plane is observed when φ takes any value when ψ = 32 °. Become.

The results of this experiment are shown in FIGS.
The solid line data in FIG. 6 indicate the X-ray detection intensity when φ is scanned with φ fixed at 90 °. A peak of X-ray detection intensity is seen around ψ = 32 °. Next, FIG. 7 shows the result of measuring the X-ray detection intensity when ψ is fixed at 32 ° and φ is scanned 180 °. In this figure, an X-ray detection intensity peak centered at φ = 90 ° is seen. As these two data show, when ψ = 32 ° and φ = 90 °, the Bragg angle θ = 33.98 °, that is, the Bragg reflection on the (11-22) plane is observed. It can be said that the obtained ZnO thin film is an in-plane uniaxially oriented ZnO thin film.

  6 and FIG. 7 together with the pole X-ray diffraction measurement obtained by the in-plane uniaxially oriented ZnO thin film having the same film thickness as that of the thin film of this example, which was produced by the method described in Patent Document 2. A result (comparative example) is shown by a broken line. When the elevation angle ψ was scanned, the full width at half maximum of the obtained peak was 6 ° in the present example, whereas it was 8 ° in the comparative example. Further, the full width at half maximum of the peak when scanning the azimuth angle φ was 35 ° in the present example, whereas it was 43 ° in the comparative example. That is, regardless of whether the elevation angle ψ or the azimuth angle φ is scanned, the line width of the peak of the intensity distribution of the X-ray diffraction is narrower in this example than in the comparative example. This indicates that the variation in the orientation direction is smaller in this example than in the comparative example, that is, the degree of orientation is higher. Further, in this embodiment, the value of ψ at the peak when the elevation angle ψ is scanned is closer to the theoretical value of 32 ° than the comparative example. This indicates that the direction of the c-axis is closer to the direction parallel to the plane of the thin film than in the comparative example.

  Next, an in-plane uniaxially oriented ZnO thin film was produced using an argon ion beam instead of an oxygen ion beam (second example). In the present embodiment, in the first thin film manufacturing apparatus 10, while introducing oxygen gas into the vacuum chamber 11 from the gas inlet 16, an argon ion beam from the ion source 12 is applied to the substrate 21 and the target 22 at an acceleration voltage of 1.5 kV. It was released toward. Here, the acceleration voltage of argon ions is made smaller than the acceleration voltage of oxygen ions because the mass of argon ions is larger than that of oxygen ions, and thus it is necessary to suppress damage caused by the argon ion beam to the substrate 21. This is because is higher than in the case of the oxygen ion beam. The method of the second embodiment was the same as the method of the first embodiment except that such an argon ion beam was used.

  FIG. 8 shows Xn while scanning (2θ-θ scanning) with respect to the ZnO thin film fabricated according to the first and second embodiments in conjunction with the detector position 2θ and the incident X-ray θ with respect to the thin film surface. The result of having performed the line diffraction measurement is shown. In the X-ray diffraction chart of the first embodiment, a peak is observed in the vicinity of 2θ = 43 °, which is due to the Cu film on the substrate.

  In both the first and second examples, a diffraction peak on the (11-20) plane was obtained with the strongest intensity, and then a diffraction peak on the (10-10) plane was obtained. These two surfaces are both parallel to the c-axis. This result reflects that the c-axis is oriented parallel to the plane of the thin film. On the other hand, diffraction peaks on the (0002) plane, which is a plane perpendicular to the c-axis, were hardly detected in the first embodiment, but were detected in the second embodiment. However, the diffraction peak at the (0002) plane in the second embodiment is smaller than the diffraction peak at the (11-20) plane. If the ZnO thin film is oriented in the direction perpendicular to the c-axis, a diffraction peak that is significantly stronger than the diffraction peak on the (11-20) plane should be detected. It can be said that the tendency that the c-axis is oriented parallel to the plane of the thin film is shown.

Schematic showing the wurtzite structure. The schematic block diagram of the apparatus used in one Embodiment of the thin film manufacturing method which concerns on this invention. FIG. 3 is a longitudinal sectional view showing the relationship between a surface 211 of a substrate 21 and a substrate incident beam 24 in the present embodiment. The longitudinal cross-sectional view which shows the direction of the board | substrate incident beam 24, the density | concentration distribution in the surface of the board | substrate of the ion (for example, oxygen ion) of the ion beam, and the growth direction of c-axis. The schematic block diagram of the apparatus used in other embodiment of the thin film manufacturing method which concerns on this invention. The X-ray-diffraction chart which shows the result of having measured the Bragg reflection in (11-22) plane, scanning the elevation angle (psi) about the ZnO thin film obtained by 1st Example. The X-ray diffraction chart which shows the result of having measured the Bragg reflection in (11-22) plane, scanning the azimuth angle (phi) about the ZnO thin film obtained by 1st Example. The X-ray diffraction chart which shows the result of having performed the X-ray-diffraction measurement by 2theta-theta scanning about the ZnO thin film obtained by 1st Example and 2nd Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 31 ... Thin film manufacturing apparatus 11 ... Vacuum chamber 12 ... Ion source 13 ... Substrate holder 14 ... Target holder 15 ... Exhaust port 16 ... Gas inlet 21 ... Substrate 211 ... Substrate surface 22 ... Target 24 ... Substrate incident beam 25 ... Orthographic projection 31 of substrate incident beam ... Evaporation source

Claims (3)

In a method for producing a thin film having a wurtzite crystal structure and having a c-axis oriented in one direction in the plane,
When depositing the thin film on the substrate surface, the ion beam is irradiated such that at least a part of the ion beam is incident on the substrate surface at an angle of less than 10 ° with respect to the substrate surface, the target was sputtered by incident portion of the ion beam not incident on the substrate surface to a target comprising a material of the thin film, the thin film you characterized in that the sputtered thin film material is deposited on the substrate surface Production method.   The thin film manufacturing method according to claim 1, wherein a raw material of the thin film is zinc oxide, and the ion beam is an oxygen ion beam.   2. The thin film manufacturing method according to claim 1, wherein the raw material of the thin film is aluminum nitride, and the ion beam is a nitrogen ion beam.

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