JP2601127B2 - Plasma CVD equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma CVD apparatus used for forming a semiconductor thin film layer or an insulating thin film layer of a semiconductor device such as a thin film transistor of a liquid crystal display, a solar cell, and the like. High-speed deposition,
The present invention relates to means for controlling a composition ratio of a film, suppressing particles, reducing damage to a substrate, and the like.

[0002]

2. Description of the Related Art FIG. 3 shows a conventional example of this type of plasma CVD apparatus. This plasma CVD apparatus is a so-called parallel plate type apparatus, and contains a high-frequency electrode 8 and a holder / electrode 18 facing each other in a vacuum vessel 4 which is evacuated by a vacuum exhaust device (not shown). High frequency electrode 8
Are insulated from the vacuum container 4 by an insulator 12.
The holder / electrode 18 is grounded. Holder and electrode 18
A substrate 2 on which a film is to be formed is placed thereon. Substrate 2
Is heated by a heater 20 in the holder / electrode 18, for example.

The high frequency electrode 8 has a large number of gas ejection holes 1 for ejecting the mixed gas 14 introduced therein into the vacuum vessel 4.
0 on its lower surface.

[0004] The mixed gas 14 includes all gases conventionally used for film formation, that is, a source gas used as a material for forming a film,
A reaction gas that reacts with the source gas and a diluent gas that dilutes these gases are included. For example, when forming a semiconductor thin film layer of a-S _i on the substrate 2, the raw material gas is S _i H _4, diluent gas is H _2, the reaction gas is not required. When forming an insulating thin film layer of a-S _i N _x and a-S _i O _x on the substrate 2, the raw material gas is S _i H _4, the reaction gas is N _2, N
H ₃ or O ₂ , and the diluent gas is H ₂ .

[0005] Between the high-frequency electrode 8 and the holder / electrode 18,
For example, 13.56 MHz high frequency power is supplied from the high frequency power supply 24 via the matching box 22.

In such an apparatus, the above-described mixed gas 14 is introduced into the vacuum vessel 4 to reduce the inside of the vacuum vessel 4 to, for example, about several hundred mTorr, and high-frequency power is supplied from the high-frequency power supply 24 to the high-frequency electrode 8. When supplied, a high-frequency discharge occurs between the high-frequency electrode 8 and the holder / electrode 18 to generate a plasma 26. At this time, since a matching capacitor is generally included in the matching box 22, electrons are accumulated therein, and the high-frequency electrode 8 is negatively charged. Then, the positive ions in the plasma 26 are converted into the high-frequency electrode 8.
, And collide with the high-frequency electrode 8, thereby generating electrons, which act to maintain the plasma 26.

As described above, the source gas in the mixed gas 14 is excited by the plasma 26 to generate excited active species, and a chemical reaction proceeds, and a desired film, for example, a _{-S i, a-S i N} x, films such as a-S _i O _x is formed.

[0008]

However, the above-mentioned plasma CVD apparatus has the following problems.

Since the substrate 2 is placed in the plasma generation region where the plasma 26 is generated, the surface of the substrate 2 or the surface of the film on the substrate 2 is damaged by the plasma 26.

[0010] Since a large number of reactive species are present in the plasma 26 and it is difficult to control the ratio of the reactive species to increase the number of specific reactive species therein, the control of the film composition ratio and the deposition rate is difficult. Is difficult.

Since all gases including the source gas are in a plasma state between the high-frequency electrode 8 and the holder / electrode 18, a film generated by a chemical reaction is deposited on the high-frequency electrode 8, which obstructs the high-frequency operation. Plasma 2 from electrode 8
It becomes difficult for electrons to be supplied into 6, and maintenance and stability of plasma 26 deteriorate.

When the particles trapped in the sheath of the plasma 26 near the high-frequency electrode 8 and caught by the gas-phase reaction cut off the high-frequency power to extinguish the plasma 26, the trapping action is lost and the substrate 2 And adheres to the surface of the substrate 2.

A plasma 26 is generated almost entirely between the high-frequency electrode 8 and the holder / electrode 18, and excited active species are generated even at a location that does not contribute to film formation on the substrate surface, that is, at a location away from the substrate surface, thereby causing a chemical reaction. Therefore, efficient film formation on a substrate, that is, high-speed film formation is impossible.

Accordingly, the present invention has made it possible to reduce damage to the substrate surface and the film surface, control the composition ratio of the film, improve the stability of plasma, improve the film formation speed, and suppress particles adhering to the substrate. A main object is to provide a plasma CVD apparatus.

[0015]

In order to achieve the above object, a plasma CVD apparatus according to the present invention, in which a gas is introduced, has a large number of vertically penetrating through-holes and the holder / hole. An intermediate electrode having a large number of gas ejection holes for ejecting the gas on the surface on the electrode side is provided between the high-frequency electrode and the holder / electrode so as to partition the space between the two electrodes. A high frequency power is supplied between the electrode and the electrode, and an exhaust port for evacuating the inside of the vacuum vessel is provided substantially in the center of the back side of the holder / electrode.
Portion , and into the high-frequency electrode, introduce all the gases except for the raw material gas which is a raw material for forming a film, blow it out from the gas blowing holes of the electrode, and In addition, a source gas or a mixed gas of the same and a diluent gas is introduced and ejected from a gas ejection hole of the electrode.
It is characterized in that a heater is provided .

Further, the intermediate electrode may be provided electrically insulated from the vacuum vessel, and a variable voltage power supply for applying a DC bias voltage to the holder / electrode may be provided at the intermediate electrode.

[0017]

According to the above construction, since the high-frequency power is supplied between the high-frequency electrode and the intermediate electrode, the high-frequency power is supplied between the two electrodes. Since no high-frequency power is supplied between the two electrodes, the region becomes a plasma non-generating region where plasma is not generated.

The gas excluding the raw material gas, which is ejected from the gas ejection holes of the high-frequency electrode, is excited by the plasma in the above-mentioned plasma generation region, thereby producing excited active species.

The excited active species generated in the plasma generation region is provided such that the exhaust port of the vacuum vessel is located on the back side of the holder / electrode.
It is led to the above-mentioned plasma non-generation area through many through holes of the intermediate electrode.

A source gas or a mixed gas of the source gas and the diluent gas is supplied to the non-plasma generating region from a number of gas ejection holes of the intermediate electrode, and the source gas and the excited active species are mixed near the surface of the substrate. A chemical reaction occurs to form a film on the surface of the substrate.

In this case, by providing the bias power supply and controlling the bias voltage between the intermediate electrode and the holder / electrode, it is possible to control the attraction of the ionic species in the excited active species to the substrate side. Therefore, it is possible to control the ratio of the ionic species and the radical species that reach the vicinity of the surface of the substrate, thereby making it possible to change the film forming conditions.

[0022]

FIG. 1 is a sectional view showing a plasma CVD apparatus according to one embodiment of the present invention. FIG. 2 is an enlarged plan view partially showing the lower surface of the intermediate electrode in FIG. FIG.
The same reference numerals are given to the same or corresponding parts as in the conventional example, and the differences from the conventional example will be mainly described below.

In this embodiment, an intermediate electrode 30 is provided in the vacuum vessel 4 between the high-frequency electrode 8 and the holder / electrode 18 so as to partition the space between the electrodes.

The intermediate electrode 30 has a hollow inside, and a gas 40 is introduced from outside the vacuum vessel 4 to the inside through several (for example, four from four sides) gas introduction pipes 36. Is done. On the lower surface of the intermediate electrode 30, that is, on the surface on the side of the holder / electrode 18, a number of gas ejection holes 34 that are connected to the internal cavity and eject the gas 40 introduced therein.
Is provided. The intermediate electrode 30 is provided with a large number of through holes 32 penetrating vertically. Of course, each of the through holes 32 and the hollow portion inside the intermediate electrode 30 are partitioned.

Between the intermediate electrode 30 and the high-frequency electrode 8, the high-frequency power supply 24 described above
High-frequency power is supplied via the power supply 2. Therefore, the intermediate electrode 30 may be simply grounded. Alternatively, as in this embodiment, an insulator 38 is provided between the gas introduction pipe 36 and the vacuum vessel 4 to electrically insulate the intermediate electrode 30 from the vacuum vessel 4 and the changeover switch 41 and the bias power supply 42 Is provided so that the intermediate electrode 30 can be grounded via the gas introducing pipe 36 by applying the changeover switch 41, or a DC bias voltage can be applied to the intermediate electrode 30 from the bias power supply 42 to the holder / electrode 18. You can keep it.

The bias power supply 42 has a variable output voltage and can apply a positive, negative, or negative to positive voltage to the intermediate electrode 30.

As shown in FIG. 1, an exhaust port 6 for evacuating the inside of the vacuum vessel 4 is provided on the rear side of the holder / electrode 18.
It is provided so as to be located at the center of the lens .

In this embodiment, the high-frequency electrode 8 has:
An annularly wound heater 48 for heating the substrate 2
It is provided on the inside and outside double. 50 is their cover. The heater 48 may be a single heater, but a double heater provides better uniformity of substrate heating.

In this embodiment, the gas other than the source gas is activated by the plasma instead of using the method of activating atoms and molecules in all the gases including the source gas by the plasma as in the conventional example. I have to.

That is, all the gases (that is, the diluent gas or the mixed gas of the diluent gas and the reaction gas) except the source gas which is the source material for forming the film are introduced into the high-frequency electrode 8 via the gas introduction pipe 44. Then, the gas 46 is ejected from a large number of gas ejection holes 10 of the electrode to a region between the intermediate electrode 30 and the gas. Further, a source gas or a mixed gas 40 of the same and a diluent gas is introduced into the intermediate electrode 30 via a gas introduction pipe 36, and this gas 40 is connected to the substrate 2 through a number of gas ejection holes 34 of the electrode. It is made to squirt into the area between.

According to the above configuration, since the high-frequency power is supplied from the high-frequency power supply 24 between the high-frequency electrode 8 and the intermediate electrode 30, a plasma 26 is generated between the two electrodes. On the other hand, although a bias voltage is supplied from the bias power supply 42 between the intermediate electrode 30 and the holder / electrode 18, no high-frequency power is supplied, so that no plasma is generated between the two electrodes. That is, the high-frequency electrode 8 and the intermediate electrode 3
A range between 0 and 0 is a plasma generation region where the plasma 26 is generated, and a region between the intermediate electrode 30 and the holder / electrode 18 is a non-plasma generation region where no plasma is generated.

The gas 46 excluding the raw material gas ejected from the gas ejection holes 10 of the high-frequency electrode 8 is excited by the plasma 26 in the above-mentioned plasma generation region, thereby generating excited active species.

The exhaust port 6 of the vacuum vessel 4 has a holder / electrode 18
, The gas flow in the exhaust gas flows toward the bottom of the vacuum vessel 4, and the excited active species generated in the plasma generation region by the gas flow are shown in FIG. As shown by an arrow A in FIG. 1, the liquid crystal is guided to the above-mentioned non-plasma generation region between the intermediate electrode 30 and the holder / electrode 18 through a large number of through holes 32 of the intermediate electrode 30.

On the other hand, a source gas or a mixed gas 40 of the source gas and the diluent gas is supplied to the non-plasma generating region from a number of gas ejection holes 34 of the intermediate electrode 30, and the source gas and the excited active species are mixed. A chemical reaction occurs near the surface of the substrate 2 to form a film on the surface of the substrate 2.

The features of this plasma CVD apparatus are as follows.

Since the film is formed on the substrate 2 in the non-plasma-generating region where the plasma 26 is not generated, damage to the substrate surface and the film surface on the substrate 2 by plasma is reduced.

It is possible to control the flow ratio of gas ejected from the high-frequency electrode 8 and the intermediate electrode 30,
Thereby, the ratio of the reactive species can be controlled, and as a result, the composition ratio of the film and the film formation speed can be controlled.

Since no raw material gas is supplied between the high-frequency electrode 8 and the intermediate electrode 30, a chemical reaction does not occur near the high-frequency electrode 8 and a film is not deposited on the high-frequency electrode 8. Since the electrons are stably supplied into the plasma 26, the stability of the plasma 26 is improved.

Since the source gas does not flow near the high-frequency electrode 8, no particles are generated near the high-frequency electrode 8 due to the gas phase reaction. Therefore, the adhesion of particles to the substrate 2 when the high-frequency power is turned off to extinguish the plasma 26 can be greatly suppressed.

Since a chemical reaction is caused only between the intermediate electrode 30 and the holder / electrode 18, that is, only in the vicinity of the surface of the substrate 2, there is no unnecessary reaction, and therefore, the film forming speed on the substrate 2 is improved. I do.

As in this embodiment, the bias power supply 42
By controlling the bias voltage between the intermediate electrode 30 and the holder / electrode 18, it is possible to control the attraction of the ionic species in the excited active species to the substrate 2 side. As a result, the ratio of the ionic species and the radical species that reach the vicinity of the surface of the substrate 2 can be controlled, thereby making it possible to change the film forming conditions.

Since no raw material gas flows in the high-frequency electrode 8, no chemical reaction occurs in the high-frequency electrode 8.
As in this embodiment, it is possible to incorporate a heater 48 for heating the substrate in the high-frequency electrode 8. As a result, the substrate 2 can be heated from the front side, though through the intermediate electrode 30, and a more uniform temperature distribution can be obtained.

Next, a more specific embodiment of the present invention will be described.

As the structure of the device, the high-frequency electrode 8 and the substrate 2
The distance between them was about 300 mm, and the distance between the intermediate electrode 30 and the substrate 2 was about 15 mm. The intermediate electrode 30 is a high-frequency electrode 8
(700 mm × 700 mm), and the aperture ratio of the through-hole 32 was about 40%. The gas ejection holes 34 of the intermediate electrode 30 are provided so that the gas at the center is directed directly downward and the gas ejection holes 34 at both outsides are directed inward so that the gas 40 can flow on the substrate 2 as uniformly as possible. The gas introduction pipe 36 for introducing the gas 40 to the intermediate electrode 30 is provided to improve the uniformity of the gas flow distribution and the temperature distribution.
Four pieces arranged at 90 degree intervals were used.

In film formation, the heater 2 in the holder / electrode 18 and the heater 4 in the high-frequency electrode 8 are used to heat the substrate 2.
8 was used. Monosilane is used (S _i H ₄₎ a-
_{S i: H, a-S} i O x: H and a-S _i N _X: In the deposition of the H, the pressure in the vacuum vessel 4 (gas pressure) 300-9
The gas flow rate of the intermediate electrode 30 is set to 00 mTorr with respect to the flow rate of the gas 46 jetting from the gas jetting hole 10 of the high-frequency electrode 8 in order to prevent the source gas from flowing back into the plasma generation region. Gas 4 gushing from 34
The flow rate of 0 was set to about 1/6 to 1/3.

Table 1 shows the types of gases used at this time, and Table 2 shows the results of film formation in comparison with the conventional apparatus as shown in FIG.

[0047]

[Table 1]

[0048]

[Table 2]

As shown in Table 2, according to the apparatus of the embodiment, the film forming speed is improved about twice or more as compared with the apparatus of the conventional example, and the amount of particles adhering to the substrate 2 is reduced. 1 /
3 or less. Further, according to the apparatus of the embodiment, since the gas flow ratio can be changed, it is easy to control the composition ratio of the film and the hydrogen concentration in the film.

[0050]

Since the present invention is configured as described above, it has the following effects.

Since film formation is performed on the substrate in a plasma non-generating region where plasma is not generated, damage to the substrate surface and the film surface on the substrate due to plasma is reduced.

It is possible to control the flow rate ratio of the gas ejected from the high-frequency electrode and the intermediate electrode, thereby controlling the ratio of the reactive species, and as a result, controlling the film composition ratio and the film formation rate. It can be performed.

Since no raw material gas is supplied between the high-frequency electrode and the intermediate electrode, a chemical reaction does not occur near the high-frequency electrode and a film is not deposited on the high-frequency electrode. Since it is supplied stably, the stability of the plasma is improved.

Since the source gas does not flow near the high-frequency electrode, no particles are generated near the high-frequency electrode due to the gas phase reaction. Therefore, adhesion of particles to the substrate when the plasma is extinguished by cutting off the high-frequency power can be greatly suppressed.

Since a chemical reaction is caused only between the intermediate electrode and the holder / electrode, that is, only in the vicinity of the surface of the substrate, there is no useless reaction, and the film forming speed on the substrate is improved.

The exhaust port is located on the back side of the holder / electrode.
So that the flow of gas in the vacuum vessel is
Passing near the surface of the substrate toward the back of the holder / electrode
This gas flow causes the gas to flow over the intermediate electrode.
The excited active species generated in the plasma generation region
Since it can be efficiently guided to near the surface, the surface of the substrate
It is possible to increase the deposition rate by increasing the reaction in the vicinity.
Can be. Ejected from the intermediate electrode by the flow of the above gas
Source gas flows to the plasma generation area above the intermediate electrode
The plasma generation region
Causes gas phase reaction of raw material gas to generate particles
Can be more reliably prevented. The exhaust port is located almost in the center of the back of the holder / electrode.
Gas on the substrate on the holder / electrode
Flows near the surface of the surface without uneven distribution with good uniformity
So that the excited active species is also on the surface of the substrate.
Since it is guided to the vicinity with good uniformity, the film in the plane of the substrate
The uniformity of thickness and film quality distribution can be further improved. An annular heater provided inside the high-frequency electrode allows
The substrate is also applied from the front side, though through the electrodes.
Heating allows more uniformity in the substrate plane
A uniform temperature distribution can be obtained.
To improve the uniformity of film thickness and film quality distribution
it can. (10) Gas or intermediate electrode ejected from high-frequency electrode
If the temperature of the source gas ejected from the
It is easy to become particles in the gas phase without forming a film on the plate surface
However, according to the present invention, the heater provided in the high-frequency electrode
Therefore, the gas ejected from the high-frequency electrode is
The heater can be efficiently heated nearby and the heater
By heating the intermediate electrode, the intermediate electrode
Source gas to be ejected from the
To promote film formation on the substrate surface.
In addition, generation of particles can be suppressed. (11) By providing a bias power supply and controlling the bias voltage between the intermediate electrode and the holder / electrode, it is possible to control the attraction of ionic species in the excited active species to the substrate side. As a result, it is possible to control the ratio between the ionic species and the radical species that reach the vicinity of the surface of the substrate, thereby making it possible to change the film forming conditions.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a plasma CVD apparatus according to one embodiment of the present invention.

FIG. 2 is an enlarged plan view partially showing a lower surface of an intermediate electrode in FIG. 1;

FIG. 3 is a schematic sectional view showing an example of a conventional plasma CVD apparatus.

[Explanation of symbols]

 2 Substrate 4 Vacuum container 6 Exhaust port 8 High frequency electrode 10 Gas ejection hole 18 Holder / electrode 24 High frequency power supply 26 Plasma 30 Intermediate electrode 32 Through hole 34 Gas ejection hole 36 Gas introduction tube 40 Gas 42 Bias power supply 44 Gas introduction tube 46 Gas

Claims (2)

(57) [Claims] 1. A vacuum vessel to be evacuated, a high-frequency electrode housed in the vacuum vessel, having a plurality of gas ejection holes into which a gas is introduced and ejecting the gas on a lower surface, In a plasma CVD apparatus having a holder and an electrode which is housed in a container so as to face the high-frequency electrode and also serves as a holder for mounting a substrate, a gas is introduced into the inside and penetrates vertically. An intermediate electrode having a large number of through-holes and a large number of gas ejection holes for ejecting the gas to the surface on the holder / electrode side, between the high-frequency electrode and the holder / electrode to partition a space between both electrodes. And a high-frequency power is supplied between the intermediate electrode and the high-frequency electrode, and an exhaust port for evacuating the inside of the vacuum vessel is provided on the back side of the holder / electrode .
Provided so as to be located substantially at the center , and into the high-frequency electrode, introducing all gases except for a raw material gas serving as a raw material for forming a film, and ejecting the same from gas ejection holes of the electrode; and A source gas or a mixed gas of the diluent gas and the raw material gas is introduced into the electrode, and is ejected from a gas ejection hole of the electrode.
A plasma CVD apparatus comprising an annular heater provided therein. 2. The intermediate electrode according to claim 1, wherein said intermediate electrode is electrically insulated from a vacuum vessel, and said intermediate electrode is provided with a variable voltage bias power supply for applying a DC bias voltage to said holder / electrode. The plasma CVD apparatus as described in the above.