JP6960137B2 - Ion plating device and method for forming yttrium film using it - Google Patents

Description

The present invention is an ion plating device and yttria using the same (yttrium oxide: Y 2 _{O 3)} relates to a method for preparation of films, in particular, using an ion plating device and which is suitable for forming an insulating film The present invention relates to a method for forming an yttria film as the insulating film.

As an ion plating apparatus of this type, there is a device conventionally disclosed in, for example, Patent Document 1. According to this prior art, an evaporation source is provided inside the vacuum chamber to which the inside is exhausted. This evaporation source includes an electron gun as a so-called evaporation means for evaporating a coating material as a vapor deposition material, and the coating material is housed in a so-called accommodating means such as a crucible. Also, this evaporation source is connected to the ground potential. Then, an object to be vapor-deposited as an object to be processed is provided above the evaporation source. This deposited material is connected to a bias power source outside the vacuum chamber. Specifically, the object to be deposited is used as a cathode and the ground potential is used as an anode, and bias power is supplied to both of them. Further, a thermionic radiating filament as a hot cathode is provided between the evaporation source and the object to be vapor-deposited and diagonally above the vicinity of the evaporation source. Both ends of the filament are connected to, for example, an AC heating power source outside the vacuum chamber. At the same time, the filament is connected to the ground potential. In addition, an ionization electrode made of, for example, a rod-shaped member is provided above the filament and below the object to be deposited. Both ends of the ionization electrode are connected to, for example, an AC heating power source outside the vacuum chamber. Further, a DC power supply for arc discharge is provided between the ionization electrode and the ground potential. Specifically, the ionizing electrode serves as an anode, the ground potential serves as a cathode, in other words, the filament serves as the cathode, and DC power for arc discharge, so to speak, ionizing power is supplied to both of them. Further, an introduction port is provided inside the vacuum chamber to introduce the reactive gas when necessary.

According to this configuration, for example, an alumina (aluminum oxide: Al ₂ O ₃ ) film can be formed. In this case (although not disclosed in detail in Patent Document 1), aluminum (Al) is adopted as the coating material. At the same time, oxygen (O ₂ ) gas is adopted as the reactive gas. Further, high frequency power is adopted as the bias power. On top of that, the inside of the vacuum chamber is first exhausted. Then, inside the exhausted vacuum chamber, aluminum as a coating material is heated and evaporated. At the same time, alternating current heating power is supplied to the filament from the heating power source for the filament. As a result, the filament is heated and thermoelectrons are emitted from the filament. Further, the ionization electrode serves as an anode and the filament serves as a cathode, and ionization power is supplied to both of them. Then, the thermions emitted from the filament as the cathode are accelerated toward the ionized electrode as the anode. The accelerated thermions inelastically collide with the evaporated particles of aluminum. As a result, the evaporated particles of aluminum are ionized, that is, ionized. Further, with this ionization, electrons are repelled from the evaporated particles of aluminum. The blown electrons flow into the ionization electrode. By continuing this phenomenon, plasma is generated. A mode of this plasma is an arc discharge with a low voltage and a large current. In this state, oxygen gas as a reactive gas is introduced into the vacuum chamber. Then, the particles of the oxygen gas are also ionized and ionized. Then, high-frequency power is supplied to both of them, with the object to be vapor-deposited as the cathode and the ground potential as the anode. Then, the ionized aluminum particles and the ionized oxygen gas particles are incident on the surface of the object to be deposited, so to speak, the surface to be processed. As a result, an alumina film, which is a compound (reactant) of ionized aluminum particles and ionized oxygen gas particles, is formed on the surface to be treated of the vapor-deposited material.

Here, the alumina film is formed not only on the surface of the object to be deposited but also on the surface of the ionization electrode. This applies not only to the alumina film but also to any film. However, when an insulating film such as an alumina film is formed on the surface of the ionized electrode, the surface of the ionized electrode is insulated, the discharge (plasma) becomes unstable, and a film of the desired quality is formed. You will not be able to. In addition, when forming a conductive film, such an inconvenience does not occur. In order to avoid the inconvenience of forming the insulating film, alternating current heating power is supplied to the ionization electrode from the heating power source for the ionization electrode. As a result, the ionized electrode is heated, and more specifically, the ionized electrode is heated to a temperature equal to or higher than the evaporation temperature of the insulating coating. As a result, the insulating film formed on the surface of the ionized electrode is re-evaporated, the insulation of the surface of the ionized electrode is prevented, and the discharge is stabilized. Then, it becomes possible to form a film of the desired quality.

Even if a heating power source for the ionization electrode is not used, by adopting an ionization electrode having an appropriate structure, the ionization electrode is self-heated, and thus the surface insulation of the ionization electrode is prevented. It is said that it can be done. For example, by adopting a thin plate made of refractory metal such as tungsten (W), molybdenum (Mo), or tantalum (Ta) or graphite as the ionization electrode, the ionization electrode can be utilized by utilizing the electron impact caused by the arc discharge. It is said that the self-heating can be performed above the evaporation temperature of the insulating film, and thus the insulation of the surface of the ionized electrode can be prevented.

As another conventional technique, for example, there is one disclosed in Patent Document 2. According to the so-called second prior art disclosed in Patent Document 2, in the so-called first prior art configuration disclosed in Patent Document 1, a DC filament bias power supply is provided between the filament and the ground potential. Be done. Specifically, the filament is used as a cathode and the ground potential is used as an anode, and DC filament bias power is supplied to both of them. According to the second conventional technique having such a configuration, the spatial potential of the plasma can be reduced as compared with the first conventional technique, and by extension, the occurrence of abnormal discharge due to the high spatial potential of the plasma is suppressed. It is said that it can be done. In addition, according to this second prior art, the adoption of asymmetric pulse power as the bias power eliminates the need for a matching box, unlike, for example, the case where high frequency power is used as the bias power. It is said that the configuration of the entire device can be simplified and the cost can be reduced. When the object to be processed is an insulating substance, asymmetric pulse power cannot be adopted as the bias power, and high frequency power is also adopted.

Japanese Unexamined Patent Publication No. 1-96373 Japanese Unexamined Patent Publication No. 11-36073

However, in any of these first and second prior arts, for example, when forming an insulating film having a relatively large film thickness such that the film thickness exceeds 10 μm, in other words, the film forming time is correspondingly appropriate. When the length is long, the insulating film formed on the surface of the ionization electrode may not completely re-evaporate and may remain on the surface of the ionization electrode in no small measure. Then, when the insulating film remaining on the surface of the ionized electrode becomes thick to a certain extent, the thick insulating film may be peeled off during the film forming process, which may cause an abnormal discharge. Needless to say, this abnormal discharge causes a deterioration in the quality of the insulating coating originally formed on the surface to be treated of the object to be treated. This tendency becomes more remarkable as the film forming speed increases. By further raising the heating temperature of the ionized electrode, the occurrence of the abnormal discharge referred to here can be suppressed, but the occurrence of the abnormal discharge cannot be completely eliminated. For example, the central portion of the ionization electrode is sufficiently heated so that the insulating coating formed on the central portion is sufficiently re-evaporated. However, since both ends of the ionization electrode are usually held via a water cooling mechanism, the temperature of both ends is lower than the temperature of the central portion. Therefore, the insulating coating formed on both ends may not be sufficiently re-evaporated. Therefore, even if the heating temperature of the ionization electrode is further raised, the insulating film formed on the surface of the ionization electrode cannot be sufficiently re-evaporated, and as a result, the occurrence of abnormal discharge due to this cannot be prevented. It is not possible to form an insulating coating of the desired quality.

In addition, the ionized electrode is a kind of consumable item, which is replaced, for example, in batches. That is, this leads to an increase in the cost of the entire ion plating apparatus including the ionization electrode, and in particular, an increase in running cost. Further, in particular, when a heating power source for heating the ionization electrode is provided, the cost of the entire ion plating apparatus including the heating power source increases, and in particular, the initial cost increases.

On the other hand, in recent years, a film having high plasma resistance has been required for an electrode of a dry etching apparatus, and an itria film is regarded as one of them. When this yttrium film is formed by the above-mentioned conventional technique, it is conceivable that yttrium itself is adopted as a vapor deposition material, for example. However, since itria is a sublimable substance, it is extremely difficult to sublimate it uniformly (for example, at a constant velocity or a constant distribution) with an electron beam. Therefore, when such yttrium itself is adopted as a vapor deposition material, it is difficult to stably form an yttrium film of the desired quality. Therefore, it is conceivable that solid yttrium is used as the vapor deposition material and oxygen gas is used as the reactive gas instead of yttrium itself. Since yttrium is an evaporative substance, by adopting such yttrium as a vapor deposition material, it is possible to avoid inconvenience when yttrium itself is adopted as a vapor deposition material. However, in this case, especially when the yttrium film having a relatively large film thickness is formed, the above-mentioned problem arises due to the yttrium film being formed on the surface of the ionization electrode.

Therefore, the present invention has a simpler structure than the conventional one, and even when an insulating film having a relatively large film thickness is formed, the insulating film of the desired quality is stably formed. It is an object of the present invention to provide an ion plating apparatus capable of forming an itria film as the insulating film using the ion plating apparatus.

In order to achieve this object, the present invention includes a first invention relating to an ion plating apparatus and a second invention relating to a method for forming an itria film.

The first invention includes a vacuum chamber, an accommodating means, an evaporation means, a holding means, a hot cathode, an ionization power supply means, a gas introduction means, and a bias power supply means. The inside of the vacuum chamber is exhausted. Then, the accommodating means accommodates the vapor-deposited material which is the material of the insulating coating inside the vacuum chamber. The evaporating means evaporates the vaporized material contained in the accommodating means with an electron gun in a state where the inert gas is not supplied. The holding means holds the object to be treated so that the surface to be treated of the object to be formed of the film is opposed to the evaporated portion of the vaporized material in the accommodating means inside the vacuum chamber. The hot cathode is provided between the accommodating means and the object to be processed, and emits thermions. The gas introduction means introduces a reactive gas, which is another material of the coating film, into the inside of the vacuum chamber. The ionization power supply means uses the accommodating means as an anode and the hot cathode as a cathode, and supplies direct current ionization power to both of them to ionize the vapor-deposited material and the reactive gas evaporated from the accommodating means. .. Then, the bias power supply means supplies predetermined bias power to both of them by using the accommodating means as an anode and the object to be processed as a cathode.

According to the first invention having such a configuration, a compound film made of a vapor-deposited material and a reactive gas can be formed. Therefore, first, the vaporized material contained in the accommodating means is evaporated by the evaporating means. At the same time, thermions are emitted from the hot cathode. Further, the accommodating means serves as an anode and the hot cathode serves as a cathode, and direct current ionization power is supplied to both of them by the ionization power supply means. Then, the thermions emitted from the hot cathode as the cathode are accelerated toward the accommodating means as the anode. The accelerated thermions inelastically collide with the evaporated particles of the vaporized material. As a result, the evaporated particles of the vapor-deposited material are ionized, that is, ionized. Further, with this ionization, electrons are repelled from the evaporated particles of the vaporized material. The blown electrons flow into the containment means. By continuing this phenomenon, plasma is generated. The mode of this plasma is an arc discharge as in the prior art described above. In this state, the reactive gas is introduced into the vacuum chamber by the gas introducing means. The particles of this reactive gas are then also ionized and ionized. Then, bias power is supplied to both of them, with the accommodating means as an anode and the object to be processed as a cathode. Then, the evaporated particles of the ionized vaporized material and the particles of the ionized reaction gas are incident on the surface to be processed of the object to be processed. As a result, a compound film of the evaporated particles of the ionized vaporized material and the particles of the ionized reaction gas is formed on the surface to be treated of the object to be treated.

That is, since the accommodating means acts as an anode for inducing an arc discharge (plasma), the ionization electrode as in the above-mentioned prior art becomes unnecessary. Therefore, for example, even when an insulating film is formed as a film, the above-mentioned inconvenience does not occur due to the insulating film being formed on the surface of the ionized electrode. Therefore, even when an insulating film having a relatively large film thickness is formed, the insulating film of the desired quality can be stably formed. Further, since the ionization electrode is not required, the cost of the entire ion plating apparatus can be reduced as compared with the conventional technique that requires the ionization electrode. In particular, since the ionized electrode is a consumable item, the running cost can be reduced by eliminating the need for such an ionized electrode. In addition, since a heating power source for heating the ionized electrode is not required, further cost reduction is achieved, and in particular, initial cost is reduced.

In the first invention, when the insulating film is formed, the insulating film is also formed on the surface of the accommodating means, whereby the surface of the accommodating means is insulated and the electric discharge is caused. There is concern that it will become unstable. However, since the accommodating means is located below the evaporated particles of the vapor-deposited material, it is difficult to form an insulating film on the surface of the accommodating means. Therefore, there is no such concern.

In the first invention, it is desirable that the mutual distance (shortest distance) between the accommodating means and the hot cathode is 10 mm to 100 mm.

In order to efficiently ionize the evaporated particles of the vaporized material, it is desirable that the distance between them is short. However, if the distance between the two is excessively small, the electron beam emitted from the electron gun interferes with the hot cathode, especially when an electron gun is adopted as the evaporation means, and this causes heating by the electron beam. Power may be lost. On the contrary, the larger the distance between them, the less likely it is that ionization will occur. Therefore, the distance between them is preferably 10 mm to 100 mm, more preferably about 20 mm to 70 mm.

Further, in the first invention, the ionization current detecting means and the thermionic emission amount controlling means may be further provided. Of these, the ionization current detecting means detects the current flowing through the ionizing power supply means, so to speak, the ionization current. Then, the thermionic emission control means controls the thermionic emission amount by the hot cathode so that the detection value of the ionization current by the ionization current detecting means becomes constant.

Here, the current flowing through the ionization power supply means, so to speak, the ionization current represents the amount of ions generated between the hot cathode and the accommodating means. The larger the ionization current, the larger the amount of ions generated, and as a result, the amount of ions incident on the surface to be processed also increases. In other words, the current flowing through the object to be processed, so to speak, the object to be processed. The current also increases. If the amount of evaporation of the vapor-deposited material by the evaporation means is constant, the amount of thermions emitted by the hot cathode is constant, and the voltage component of the ionization power, so to speak, the ionization voltage is constant, ideally, the ionization current Becomes constant. However, the ionization current fluctuates with the passage of the film formation time. The causes of this are that as the vaporized material evaporates, the molten surface of the vaporized material decreases and the distance between the molten surface and the hot cathode increases, the hot cathode itself deforms, and the flow of evaporated particles. It is presumed that this is due to the fact that the collision probability between the thermoelectrons and the evaporated particles fluctuates due to changes in the shape and distribution of the. Therefore, it is desirable to control the amount of thermions emitted by the hot cathode so that the ionization current becomes constant. With this configuration, the quality of the coating film can be made uniform and the reproducibility can be maintained.

Further, in the first invention, the film formation rate detecting means and the evaporation amount controlling means may be provided. Of these, the film forming rate detecting means detects the film forming rate, that is, the so-called film forming rate, which is formed on the surface to be treated of the object to be treated. Then, the evaporation amount control means controls the evaporation amount of the vaporized material by the evaporation means so that the detection value of the film formation rate by the film formation rate detection means becomes constant.

That is, the film formation rate is proportional to the amount of evaporation of the vaporized material by the evaporation means. However, as the film formation time elapses, the amount of the vapor-deposited material contained in the accommodating means decreases. The heating temperature of the evaporated material rises, resulting in a higher film formation rate. Therefore, it is desirable to detect (monitor) this film formation rate and control the amount of evaporation of the vaporized material by the evaporation means so that the film formation rate becomes constant. This configuration also ensures uniform quality of the coating and maintenance of reproducibility.

In particular, the constant control of the film formation rate and the above-mentioned constant control of the ionization current are performed independently of each other, so that the quality and characteristics of the coating film can be flexibly and variously controlled. This greatly contributes to meeting various demands on the coating.

As described above, the electrons blown off from the evaporated particles of the vaporized material also flow into the accommodating means. In other words, ionized power is also supplied to the accommodating means. Therefore, the amount of evaporation of the vaporized material, that is, the film formation rate, also depends on this ionization power. On the other hand, the ionization voltage, which is a voltage component of the ionization power, is made constant, and then the above-mentioned constantization control of the ionization current is performed, so that the ionization power becomes constant. Therefore, when the film formation rate is controlled to be constant, it is desirable that the ionization current is controlled to be constant in parallel with the control.

As described above, the first invention is extremely useful for forming an insulating coating as a coating.

Next, the second invention relates to a method for forming an itria film as described above, and comprises an evaporation process, a thermionic emission process, an ionization power supply process, a gas introduction process, and a bias power supply process. Equipped. In the evaporation process, the vaporized material, which is the material of the coating film contained in the accommodating means inside the vacuum chamber in which the inside is exhausted, is the vaporized material, and the electron gun is in a state where the inert gas is not supplied. Evaporate with. Then, in the thermoelectron emission process, the object to be processed is held so that the surface to be processed of the object to be formed of the film is opposed to the evaporated portion of the vaporized material in the accommodating means inside the vacuum chamber. Then, thermions are emitted from the hot cathode provided between the accommodating means and the object to be processed. Then, in the gas introduction process, a reactive gas, which is another material of the coating film, is introduced into the inside of the vacuum chamber. In the ionization power supply process, the accommodating means serves as an anode and the hot cathode serves as a cathode, and direct current ionizing power is supplied to both of them to ionize the vapor-deposited material and the reactive gas evaporated from the accommodating means. do. The evaporation process, the thermionic emission process, the ionization power supply process, and the gas introduction process are performed in parallel . Then, in the bias power supply process, the ionized vapor deposition material and the ionized reactive gas are directed to the object to be processed by a predetermined bias power having the accommodating means as the anode and the object to be processed as the cathode. .. Here, yttrium is adopted as the vapor deposition material. Then, oxygen gas is adopted as the reactive gas. As a result, an itria film is formed as a film.

That is, the second invention forms an itria film using the first invention described above. Therefore, according to the second invention, even when the yttrium film having a relatively large film thickness is formed, the yttrium film of the desired quality can be formed. Such an Itria film is promising as a film for an electrode of a dry etching apparatus that requires high plasma resistance as described above, for example.

As described above, according to the present invention, despite the simpler configuration than the conventional one, even when an insulating film is formed as a film, the insulating film of the desired quality can be stably produced. Can be formed. Such an invention is extremely useful for forming an Itria film having high plasma resistance.

It is a schematic diagram which shows the schematic structure of one Embodiment of this invention. It is a photograph which shows the generation state of plasma in the same embodiment. It is a graph which shows the relationship between the ionization voltage, the ionization current, and the emission current of an electron gun in the same embodiment. It is a schematic diagram which shows the X-ray diffraction pattern of the ytria film formed in the same embodiment. It is an observation image by a scanning electron microscope of the cross section of the yttrium film. It is a schematic diagram which shows the test result of the plasma resistance of the yttrium film in comparison with that of other bulk materials.

An embodiment of the present invention will be described with reference to FIGS. 1 to 6.

As shown in FIG. 1, the ion plating apparatus 10 according to the present embodiment includes a substantially cylindrical vacuum chamber 12. The vacuum chamber 12 is made of a metal having high corrosion resistance and high heat resistance, for example, stainless steel such as SUS304, and its wall portion is connected to a ground potential as a reference potential. An exhaust port 14 is provided at an appropriate position on the wall portion of the vacuum tank 12, for example, at the bottom, and the exhaust port 14 is outside the vacuum tank 12 via an exhaust pipe (not shown). A vacuum pump as an exhaust means (not shown) is coupled. The diameter (inner diameter) in the vacuum chamber 12 is, for example, about 700 mm, and the height dimension is, for example, about 1000 mm. Further, the upper portion of the vacuum chamber 12 is formed in a substantially dome shape for reasons such as improvement in strength.

In the vacuum chamber 12, the evaporation source 16 is arranged near the bottom thereof. The evaporation source 16 has a roughly cup-shaped (more specifically, a roughly cylindrical shape with an open top) copper crucible 18 as a means of accommodating, and a 270 ° deflecting electron gun 20 as an means of evaporation. There is. That is, the crucible 18 is for accommodating the vapor deposition material 22 which is a material for the coating film described later, and the electron gun 20 is for heating and evaporating the coating material 22 in the crucible 18. Although detailed illustration is omitted, a hearth liner made of a refractory metal, for example, tantalum, is provided in the crucible 18, and the vapor deposition material 22 is housed in the hearth liner. Further, the power Wg of the electron gun 20 is controlled by a dedicated power supply device 24 provided outside the vacuum chamber 12, and is, for example, 10 kW at the maximum. Incidentally, in FIG. 1, the power supply destination from the power supply device 24 is shown to be the evaporation source 16 (housing), but this is for the sake of simplification of the illustration, and in reality, Electric power from the power supply device 24 is supplied to the electron gun 22. Further, although detailed illustration is omitted, the evaporation source 16 is provided with a water-cooled cooling mechanism for preventing overheating of the crucible 18. The evaporation source 16 (housing) is connected to the ground potential including the crucible 18.

Then, for example, the substrate 26 as an object to be processed is arranged above the evaporation source 16. The substrate 26 is held by the substrate base 28 as a holding means with the surface to be film-formed, that is, the surface to be processed, facing the evaporation source 16, particularly toward the opening of the crucible 18. ing. Further, between the substrate 26 and the crucible 18, a shutter 30 that is driven to open / close by an opening / closing mechanism (not shown) is provided. The distance from the crucible 18 of the evaporation source 16 to the surface to be processed of the substrate 26 is approximately 250 mm to 700 mm, although it depends on the size of the surface to be processed of the substrate 26.

Further, the substrate base 28 is connected to a radio frequency (RF) power supply device 32 as a bias power supply means outside the vacuum chamber 11. Specifically, the high-frequency power supply device 32 is provided between the substrate base 28 and the ground potential. Further, a matching box 34 is provided between the high frequency power supply device 32 and the substrate base 28 as a matching means for matching the impedance between the two. The high frequency power supply device 32 outputs high frequency power having a frequency of 13.56 MHz as the bias power Wb. Further, when this high frequency power is supplied to the substrate base 28, a DC voltage having a negative potential based on the ground potential is naturally induced in the high frequency power Wb, and a so-called self-bias voltage is generated.

In addition, as a hot cathode between the evaporation source 16 and the shutter 30 diagonally above the vicinity of the evaporation source 16 so as not to interfere with the evaporation path of the evaporated particles described later from the evaporation source 16. Thermionic emission filament 36 of the above is provided. The filament 36 is, for example, a linear body made of tungsten having a diameter of 1 mm, and has a linear (shortest) distance of about 10 mm to 100 m, preferably about 20 mm to 70 mm, for example, about 30 mm upward from the peripheral edge of the opening of the crucible 18. It is provided so as to extend in the horizontal direction at a distant position. Further, the filament 36 is formed in a spiral shape so as to be able to emit as much thermoelectrons as possible, which will be described later, by increasing the surface area thereof. Specifically, it is formed in a spiral shape with a diameter of 6 mm, and the number of turns is 10 (turns), so that the length dimension of the spiral portion is 40 mm. Both ends of the filament 36 are connected to, for example, an AC filament heating power supply device 38 as a hot cathode heating power supply means outside the vacuum chamber 12. That is, the filament 36 is heated by receiving the AC filament heating power Wc from the filament heating power supply device 38, and emits thermoelectrons. As for the capacity of the filament heating power supply device 38, for example, the filament heating voltage Vc, which is a voltage component of the filament heating power Wc, is 40V, and the filament heating current Ic, which is a current component of the filament heating power Wc, is 60A. Further, the filament heating power Wc is not limited to AC power, but may be DC power. In any case, it suffices if the filament 36 can be heated to a level sufficient for thermions to be emitted, for example, to about 2000 ° C. to 2500 ° C.

Further, the filament 36 (one end portion) is connected to a DC ionization power supply device 40 as an ionization power supply means outside the vacuum chamber 12, and more specifically, to the positive electrode side output terminal of the ionization power supply device 40. It is connected. The negative electrode side output terminal of the ionization power supply device 40 is connected to the ground potential via a current detection device 42 as an ion current detection means. That is, the filament 36 is supplied with a direct current ionization power Wd having a positive potential based on the ground potential from the ionization power supply device 40. In other words, the filament 36 is used as a cathode, the ground potential is used as an anode, and in other words, the evaporation source 16 including the crucible 18 described above is used as an anode, and the ionization power Wd is supplied to both of them.

The current detection device 42 is for detecting the current component of the ionization power Wd, that is, the current flowing through the ionization power supply device 40, that is, the ionization current Id, and the detection value of the ionization current Id by the current detection device 42. Is supplied to the heating control device 44 as a thermionic emission control means. The heating control device 38 controls the filament heating power supply device 38 so that the detected value of the ionization current Id by the current detection device 42 becomes constant, that is, the ionization current Id becomes constant. The filament heating power Wc output from the power supply device 38 is controlled, that is, the heating temperature of the filament 36 is controlled.

In addition, a gas introduction pipe 46 for introducing various gases into the vacuum chamber 12 is provided at an appropriate position on the wall portion of the vacuum chamber 12, for example, at a position above the filament 36 and below the substrate base 28. It is provided. Examples of the various gases referred to here include argon (Ar) gas as a gas for ion bombard and oxygen gas as a reactive gas. Although not shown, the gas introduction pipe 46 is connected to each gas supply source outside the vacuum chamber 12. Further, the piping from each supply source is provided with an on-off valve as an opening / closing means for opening / closing the piping and a mass flow controller as a flow rate control means for controlling the flow rate of gas in the piping. Has been done.

Further, in the vicinity of the substrate base 28, for example, a crystal oscillator type film thickness sensor 48 is arranged with its detection unit facing the opening of the crucible 18. The film thickness sensor 48 is connected to the film thickness monitor 50 outside the vacuum chamber 12. The film thickness monitor 50 constitutes a film thickness detection means together with the film thickness sensor 48, and based on the film thickness detection value by the film thickness sensor 48, the film formation rate on the surface of the substrate 26, that is, the formation rate. Calculate the film thickness. Then, the calculation result of the film formation rate by the film thickness monitor 50 is supplied to the evaporation amount control device 52 as the evaporation amount control means.

The evaporation amount control device 52 controls the evaporation amount of the vaporized material 22 from the evaporation source 16 so that the film forming rate becomes constant based on the calculation result of the film forming rate by the film thickness monitor 50. Specifically, the output Wg of the electron gun 20 is controlled by controlling the power supply device 24 for the electron gun 20. The evaporation amount control device 52 may be incorporated in the power supply device 24 for the electron gun 20 or the film thickness monitor 50.

Further, although not shown, heating means for heating the inside of the vacuum chamber 12 including the substrate 26, for example, a ceramic heater, is provided at an appropriate position in the vacuum chamber 12. This ceramic heater heats the inside of the vacuum chamber 12 including the substrate 26 by receiving the heater heating power from the heater heating power supply device provided outside the vacuum chamber 12.

According to the ion plating apparatus 10 configured in this way, for example, an itria film, which is an insulating film, can be formed on the surface to be treated of the alumina substrate 26.

For that purpose, first, the solid yttrium, which is the material of the yttrium film, is housed in the crucible 18. As this itria, a granular one having a diameter of about 3 mm to 5 mm is adopted. Then, the inside of the vacuum chamber 12 is ^{exhausted to about 10 -4} Pa, so-called vacuuming is performed. Further, at the same time as this evacuation, the inside of the vacuum chamber 12 including the substrate 26 is heated by the above-mentioned ceramic heater, for example, the substrate 26 is heated to about 200 ° C.

After this evacuation and heat treatment are performed for, for example, 2 hours, a discharge cleaning (ion bombard) treatment for cleaning the surface to be treated of the substrate 26 is performed. Specifically, argon gas is introduced into the vacuum chamber 12 with the shutter 30 open. Then, the filament heating power Wc is supplied to the filament 36. As a result, the filament 36 is heated and thermoelectrons are emitted from the filament 36. Further, the ionization power Wd is supplied to the filament 36, that is, the filament 36 is used as a cathode and the evaporation source 16 including the crucible 18 is used as an anode, and the ionization power Wd is supplied to both of them. Then, the thermions emitted from the filament 36 as the cathode are accelerated toward the evaporation source 16 as the anode, particularly toward the crucible 18 located near the filament 36. The accelerated thermions then inelastically collide with the argon gas particles. As a result, the argon gas particles are ionized, that is, ionized. Further, with this ionization, electrons are repelled from the particles of the argon gas. The blown electrons flow into the crucible 18. By continuing this phenomenon, plasma due to arc discharge is generated. In this state, the bias power Wb is supplied to the substrate base 28, that is, the bias power Wb is supplied to the substrate 26 via the substrate base 28. The above-mentioned self-bias voltage, which is a negative potential based on the ground potential, is superimposed on the bias power Wb, that is, the potential of the substrate 26 becomes a negative potential by the self-bias voltage. As a result, argon ions in the plasma are incident on the surface to be treated of the substrate 26, and the impact at this time cleans the surface to be treated of the substrate 26.

The flow rate of argon gas in this discharge cleaning process is, for example, 20 mL / min. Then, the pressure in the vacuum chamber 12 is maintained at, for example, 0.1 Pa. The ionization voltage Vd, which is a current component of the ionization power Wd, is set to 50V. Then, the filament heating power Wc is controlled so that the ionization current Id becomes 5A. The filament heating power Wc at this time is approximately 810 W. Further, the bias power Wb is set to 200 W. The self-bias voltage at this time is approximately −500 V.

After this discharge cleaning process is performed for, for example, 10 minutes, a film forming process for forming an itria film is performed. First, the introduction of argon gas into the vacuum chamber 12 is stopped. Then, the electron gun 20 of the evaporation source 16 is energized. As a result, an electron beam is emitted from the electron gun 20, and the electron beam irradiates the vapor-deposited material 22 in the crucible 18. Upon irradiation with this electron beam, the vapor deposition material 22 is heated and evaporated. Also at this time, since the filament heating power Wc is supplied to the filament 36 and the ionization power Wd is also supplied to the filament 36, the thermions emitted from the filament 36 are accelerated toward the crucible 18. .. Then, the accelerated electrons collide inelastically with the evaporated particles of the vaporized material 22. As a result, the evaporated particles of the vapor-deposited material 22 are ionized and ionized. Further, with this ionization, electrons are repelled from the evaporated particles of the vapor deposition material 22. Then, the blown electrons flow into the crucible 18. By continuing this phenomenon, plasma due to arc discharge is generated as in the case of the above-mentioned discharge cleaning process. In addition, oxygen gas as a reactive gas can be introduced into the vacuum chamber 12. Then, the particles of the oxygen gas are also ionized and ionized. Then, when the shutter 30 is opened, the vaporized particles of the ionized vapor film material 22, that is, the yttrium ions, and the ionized oxygen gas particles, that is, the oxygen ions, are supplied with the bias power Wb. It is attracted toward the surface to be processed of 26 and is incident on the surface to be processed. As a result, an yttrium film, which is a compound of yttrium ions and oxygen ions, is formed on the surface to be treated of the substrate 26.

The flow rate of oxygen gas in this film forming process is, for example, 100 mL / min. Then, the pressure in the vacuum chamber 12 is maintained at ^{, for example, 4 × 10 -2 Pa.} The ionization voltage Vd is set to 30V. Then, the filament heating power Wc is controlled so that the ionization current Id becomes 40 A. The filament heating power Wc at this time is approximately 780 W to 810 W. Further, the bias power Wb is set to 100 W. The self-bias voltage at this time is approximately −100 V. The power Wg of the electron gun 20 is controlled so that the film forming speed is 3 nm / s. The power Wg of the electron gun 20 at this time is approximately 2.5 kW to 2.8 kW. The temperature of the substrate 26 under such conditions was about 380 ° C.

This film forming process is continued until an itria film having a desired film thickness is formed, and then the film forming process is completed. That is, the supply of the bias power Wb to the substrate 26 is stopped. At the same time, the supply of the filament heating power Wc to the filament 36 is stopped, and the supply of the ionization power Wd to the filament 36 is stopped. Further, the energization of the electron gun 20 is stopped, and the introduction of oxygen gas into the vacuum chamber 12 is stopped. As a result, the plasma disappears. Then, the pressure in the vacuum chamber 12 is gradually returned to the atmospheric pressure, and an appropriate cooling period is set. Then, the inside of the vacuum chamber 12 is opened to the atmosphere, and the substrate 26 is taken out from the inside of the vacuum chamber 12. This completes a series of processes including the film forming process for forming the yttrium film.

As described above, according to the present embodiment, plasma due to arc discharge is induced between the crucible 18 and the filament 36. Therefore, the ionization electrode as in the above-mentioned conventional technique becomes unnecessary. Therefore, even when an insulating film such as an yttrium film is formed, the inconvenience caused by the formation of the insulating film on the surface of the ionized electrode does not occur as in the prior art. Therefore, even when an insulating film having a relatively large film thickness is formed, the insulating film of the desired quality can be stably formed. Further, since the ionization electrode is not required, the cost of the entire ion plating apparatus 10 can be reduced by that amount as compared with the conventional technique that requires the ionization electrode. In particular, since the ionized electrode is a consumable item, the running cost can be reduced by eliminating the need for such an ionized electrode. In addition, since a heating power source for heating the ionized electrode is not required, further cost reduction is achieved, and in particular, initial cost is reduced.

FIG. 2 shows the state of plasma in the film forming process for forming the yttrium film. The condition at this time is that the pressure in the vacuum chamber 12 is 5 × 10 ^-4 Pa. The filament heating power Wc is 810 W, specifically, the filament heating voltage Vc is 18 V, and the filament heating current Ic is 45 A. Further, the power Wg of the electron gun 20 is 1.8 kW, specifically, the acceleration voltage Vg which is a voltage component of the power Wg is 10 kV, and the emission current Ig which is a current component of the power Wg is 180 mA. The ionization voltage Vd is 20 V, the ionization current Id is 30 A, that is, the ionization power Wd is 600 W. In FIG. 2, the spiral one shown in the center is the filament 36. The crucible 18 is a red-hot circular (oval) shape shown below the filament 36. As can be seen from FIG. 2, the bluish-purple discharge color seen in the arc discharge could be confirmed.

Then, FIG. 3 shows the relationship between the ionization voltage Vd, the ionization current Id, and the emission current Ig of the electron gun 20 when the acceleration voltage Vg of the electron gun 20 is a constant value of 10 kW. The filament heating power Wc at this time is 810 W. As can be seen from FIG. 3, the larger the ionization voltage Vd, the larger the ionization current Id. Further, the larger the emission current Ig, the larger the ionization current Id. This means that the higher the evaporation rate of yttrium, the larger the ionization current Id, that is, the larger the amount of ions generated. The larger the ionization voltage Vd, the higher the energy of thermions emitted from the filament 36, and the more ionization of yttrium as the vapor deposition material 22 is promoted. Further, the larger the emission current Ig, that is, the larger the power Wg of the electron gun 20, the higher the vapor pressure of yttrium, and the higher the probability that the evaporated particles of the yttrium collide with thermions, and the ionization current increases. Id increases.

FIG. 4 shows an X-ray diffraction (XRD) pattern of an Itria film formed on a silicon (Si) substrate 26 with a film thickness of 2.5 μm in the present embodiment. As is clear from FIG. 4, according to the present embodiment, it can be seen that a crystalline yttrium film is formed.

An observation image of a cross section of the substrate 26 on which the Itria film according to FIG. 4 is formed by a scanning electron microscope (SEM) is shown in FIG. As is clear from FIG. 5, it can be seen that a dense yttrium film is formed.

Further, FIG. 6 shows the test results of the plasma resistance of the yttrium film formed in the present embodiment in comparison with those of other bulk materials. Specifically, an alumina substrate 26 was adopted, and an itria film having a film thickness of 10 μm was formed on the surface to be treated of the alumina substrate 26. The conditions at this time are the same as those described with reference to FIG. Then, an etching test was conducted on the substrate 26 on which the ytria film having a film thickness of 10 μm was formed, using a reactive ion etching (RIE) apparatus. The conditions for this etching test are that _{the flow rate of carbon tetrafluoride (CF 4} ) gas is 40 mL / min and the flow rate of oxygen gas is 10 mL / min. The pressure in the tank is 5 Pa, and the power of high frequency power is 500 W. Under such conditions, the etching test was performed for 6 hours. Further, as other bulk materials to be compared, an alumina substrate and an Itria substrate were prepared, and the etching test was also performed on these under the same conditions.

As can be seen from FIG. 6, according to the yttrium film formed in the present embodiment, the etching depth is much smaller, that is, the etching resistance is much higher than that of the bulk material of the alumina substrate and the ytria substrate. Can be obtained. That is, according to the present embodiment, it is possible to form an itria film having extremely high etching resistance. Such an itria film can be expected to be applied as a film for electrodes of a dry etching apparatus that requires high plasma properties.

As described above, according to the present embodiment, even in the case of forming an insulating film such as an itria film, even though the ion plating device 10 has a simpler configuration than the above-mentioned conventional technique. The insulating coating of the desired quality can be stably formed. In particular, it is extremely useful for forming an Itria film that requires high plasma resistance.

Further, according to the present embodiment, the ionization current Id is controlled to be constant so that the ionization current Id is constant, so that the quality of the coating film can be made uniform and the reproducibility can be maintained. At the same time, the film formation rate is also controlled to be constant so that the film formation rate is constant, so that the quality of the film can be made uniform and the reproducibility can be maintained. By controlling the constantization of the ionization current Id and the constantization of the film formation rate independently of each other, it is possible to flexibly and variously control the quality and characteristics of the coating film.

It should be noted that this embodiment is a specific example of the present invention, and does not limit the scope of the present invention.

Further, in the present embodiment, the case of forming the itria film has been described, but other films can be formed. That is, an alumina film can be formed by using, for example, aluminum instead of yttrium as the vapor deposition material 22. Of course, other oxide films can also be formed. Further, as the reactive gas, a hydrocarbon-based gas such as _{acetylene (C 2} H _{2 ), a nitrogen (N 2} ) gas, or the like is adopted in place of or at the same time as the oxygen gas, thereby forming a carbide film or carbonitriding. A film, a nitride film, an oxynitride film, or the like can be appropriately formed.

A high-frequency power supply device 32 has been adopted as the bias power supply means, but the present invention is not limited to this. A DC power supply device, an asymmetric pulse power supply device, or the like may be adopted depending on the type of the substrate 26 and the coating film. However, when the substrate 26 is an insulating substance, a high-frequency power supply device 32 is adopted as the bias power supply means in order to prevent charge-up.

10 Ion plating device 12 Vacuum tank 16 Evaporation source 18 坩 堝 20 Electron gun 26 Board 32 High frequency power supply device 36 Thermionic radiation filament 38 Filament heating power supply device 42 Ionization power supply device 46 Gas introduction tube

Claims (5)

A vacuum tank that exhausts the inside and
An accommodating means for accommodating a vapor-deposited material, which is a material for an insulating coating, inside the vacuum chamber.
An evaporation means for evaporating the vaporized material contained in the accommodation means with an electron gun in a state where the inert gas is not supplied to the vacuum chamber.
A holding means for holding the object to be processed so that the surface to be processed of the object to be processed to be formed of the film is opposed to the evaporated portion of the vaporized material in the accommodating means inside the vacuum chamber.
A hot cathode provided between the accommodating means and the object to be processed and emitting thermions,
A gas introducing means for introducing a reactive gas, which is another material of the coating film, into the inside of the vacuum chamber,
An ionization power supply means for ionizing the vapor-deposited material and the reactive gas evaporated from the accommodation means by supplying direct current ionization power to both of them using the accommodation means as an anode and the hot cathode as a cathode.
Bias power supply means for supplying predetermined bias power to both of the accommodating means as an anode and the object to be processed as a cathode, and
An ion plating device. The distance between the accommodating means and the hot cathode is 10 mm to 100 mm.
The ion plating apparatus according to claim 1. An ionization current detecting means for detecting a current flowing through the ionization power supply means, and an ionization current detecting means.
The thermionic emission amount controlling means for controlling the thermionic emission amount by the hot cathode so that the detection value by the ionization current detecting means becomes constant, and the thermionic emission amount controlling means.
The ion plating apparatus according to claim 1 or 2, further comprising. A film forming rate detecting means for detecting the forming rate of the film formed on the surface to be treated, and
An evaporation amount control means that controls the evaporation amount of the vaporized material by the evaporation means so that the detection value by the film formation rate detecting means becomes constant.
The ion plating apparatus according to any one of claims 1 to 3, further comprising. The evaporation process of evaporating the vaporized material, which is the material of the coating film contained in the accommodating means inside the vacuum chamber to which the inside is exhausted, with an electron gun in a state where the inert gas is not supplied to the vacuum chamber.
In a state where the object to be processed is held so that the surface to be processed of the object to be processed to be formed of the film is opposed to the evaporated portion of the vaporized material in the accommodation means inside the vacuum chamber. A thermoelectron emission process for emitting thermoelectrons from a hot cathode provided between the means and the object to be processed,
The gas introduction process of introducing a reactive gas, which is another material of the coating film, into the inside of the vacuum chamber,
The ionization power supply process of supplying DC ionizing power to both of them with the accommodating means as an anode and the hot cathode as a cathode to ionize the vaporized material vaporized from the accommodating means and the reactive gas. ,
Run in parallel,
A bias power supply process in which the ionized vapor deposition material and the ionized reactive gas are directed toward the object to be processed by a predetermined bias power having the accommodating means as an anode and the object to be processed as a cathode.
And
The above-mentioned vapor deposition material is yttrium,
The above reactive gas is oxygen gas,
Forming an itria film as the above film,
A method for forming an itria film by the ion plating method.

Images