JP2714826B2 - Magnetron sputtering equipment - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetron sputtering apparatus with improved erosion of a target.

(Prior Art) A conventional magnetron sputtering apparatus is shown in FIG. In FIG. 1, an anode electrode 3 on which a substrate 2 is mounted and a target 4 made of a magnetic material also serving as a cathode electrode are arranged in parallel in a vacuum chamber 1 at a predetermined interval. An electromagnet 7 including a yoke 5 and a coil 6 is provided on the back surface of the target 4.
The yoke 5 of the electromagnet 7 protrudes above the bottom yoke 5a, the center yoke 5b protruding above the center of the bottom yoke 5a, and the periphery of the bottom yoke 5a, and surrounds the center yoke 5b at a predetermined interval. It is formed integrally with the peripheral yoke 5c. The central yoke 5b of the yoke 5 is located at the center of the rear surface of the target 4, and the peripheral yoke 5c is located at the peripheral edge of the rear surface of the target 4. The coil 6 includes a central coil 6a provided on the outer periphery of the central yoke 5b and a peripheral coil 6b provided on the outer periphery of the peripheral yoke 5c. Figure 5 shows a perspective view of the electromagnet 7, as can be seen from this figure, the center yoke 5b of the yoke 5 includes a longitudinal portion 5b ₁ of the central portion is straight longitudinally extending, the longitudinal portions 5b ₁ It is integrally formed in the longitudinal direction of the semi-cylindrical portion 5b ₂ projecting to the semicylindrical from both sides of the. Also, the yoke 5
The peripheral edge yoke 5c, the I narrow longitudinal portions 5b ₁ of the central yoke 5b, 2 two the longitudinal periphery 5c ₁ which straightly extends to and parallel to the longitudinal direction, the radius r ₀ of the semi-cylindrical portion 5b ₂ of the central yoke 5b the central axis is integrally formed with the semi-cylindrical portion 5c _2, which allowed to exist across the center axis and the the two semicylindrical longitudinal periphery 5c ₁ of the inner surface of the inner diameter R, the center yoke 5b predetermined of Surrounded at intervals.

Therefore, the center coil 6a of the coil 6 and the peripheral coil
When the center yoke 5b is excited, the central yoke 5b and the peripheral yoke 5c of the yoke 5 become magnetic poles, respectively, and a magnetic field is formed between the central yoke 5b and the peripheral yoke 5c. Therefore, the yoke 5
Most of the magnetic flux emitted from the upper end of the central yoke 5b flows through the target 4 made of a magnetic material toward the peripheral portion from the central portion thereof, and enters the peripheral yoke 5c of the yoke 5.
A part of the magnetic flux leaks from the central portion of the target 4 and enters the peripheral portion of the target 4 while forming a leakage magnetic field composed of curved magnetic force lines in a space near the surface between the central portion and the peripheral portion of the target 4. Then, it enters the peripheral yoke 5c of the yoke 5. The magnetic flux entering the peripheral yoke 5c of the yoke 5 then reaches the central yoke 5b through the peripheral yoke 5c and the bottom yoke 5a. Then, the magnetic flux repeats the above flow again.

In such an apparatus, after the inside of the vacuum chamber 1 is evacuated from the exhaust passage 8, a sputtering gas such as Ar gas is introduced into the vacuum chamber 1 from the gas introduction passage 9, and the pressure in the vacuum chamber 1 is reduced to 10 ^{−. 2} Torr and the voltage of the anode electrode 3
When the voltage of the target 4 made of a magnetic material also serving as a cathode electrode is set to −700 V, electrons are emitted from the target 4 due to an electric field between the anode electrode 3 and the target 4, and the electrons and the sputtering gas Collide,
When the sputter link gas is excited or ionized, plasma is generated, and electrons are generated between an electric field between the anode electrode 3 and the target 4 and a leakage magnetic field formed in a space near the surface of the target 4. By the action, the target 4 moves in a space near the surface of the target 4 while drawing a cycloid or trochoid trajectory, so that the density of plasma in the space near the surface of the target 4 where the leakage magnetic field is formed increases.
The ions in the plasma having the increased density then sputter the target 4 and become eroded.

As shown by hatching in FIG. 6, the erosion region 10 of the target 4 is formed on the surface of the target 4 between the center yoke 5b and the peripheral yoke 5c of the yoke 5, and includes a straight straight portion 10a and a semicircular half. It has a track shape formed by combining with the circular portion 10b.

Note that particles sputtered from the target 4 by sputtering adhere to the substrate 2 attached to the anode electrode 3 and form a thin film on the surface of the substrate 2.

(Problems to be Solved by the Invention) The conventional magnetron sputtering apparatus forms a leakage magnetic field in the space near the surface of the target 4 between the central yoke 5b and the peripheral yoke 5c as described above, and reduces the plasma density there. The erosion region 10 having a track shape is formed on the target 4 by increasing the height of the target 4. The semi-cylindrical portion 5b ₂ of the central yoke 5b and the semi-cylindrical portion 5b of the peripheral yoke 5c are formed.
flux density of the leakage magnetic field formed in the space in the vicinity of the surface of the target 4 between the c _2, the semi-cylindrical portion of the center yoke 5b
Since decreased with increasing distance from 5b _2, decreases with the plasma density in accordance with this reduction also separated from the semi-cylindrical portion 5b ₂ of the central yoke 5b, semicylindrical portion of the central yoke 5b
And 5b _2, erosion of the surface of the target 4 between the semi-cylindrical portion 5c ₂ of the peripheral yokes 5c occurs much in than semicylindrical portion 5b ₂ of the central yoke 5b. Therefore, even if the plasma is swung over the entire width of the erosion region 10 by changing the current flowing through the peripheral coil 6b of the coil 6, the target 4
Holes in than the half cylindrical portion 5b ₂ of the central yoke 5b empty quickly the problem of lowering the utilization efficiency of the target 4 has occurred.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a magnetron sputtering apparatus which solves the above-mentioned conventional problems and can improve the utilization efficiency of the target without biasing the erosion of the surface of the target.

(Means for Achieving the Object) In order to achieve the above object, the present invention provides a magnetron sputtering apparatus having the above-described configuration, in which a first track on a back surface of a semicircular portion of a track-shaped erosion region of a target is provided. A compensation magnetic plate is provided between the central yoke corresponding to the magnetic pole and the peripheral yoke corresponding to the second magnetic pole, the compensation magnetic plate being reduced in thickness from the central yoke to the peripheral yoke.

In the present invention, the central yoke has a semi-cylindrical portion on both sides, the peripheral yoke has a semi-cylindrical portion surrounding the semi-cylindrical portion of the central yoke, and is provided between the semi-cylindrical portion of the central yoke and the semi-cylindrical portion of the peripheral yoke. The compensation magnetic plate is provided on the back surface of the target, and the value obtained by adding the thickness of the compensation magnetic plate to the thickness of the target at the point separated by the distance r from the center axis of the radius of the semi-cylindrical portion of the central yoke is proportional to 1 / r. It is preferable that the value be as follows.

(Operation) In the present invention, a compensating magnetic plate whose thickness decreases from the central yoke to the peripheral yoke is provided between the central yoke corresponding to the first magnetic pole and the peripheral yoke corresponding to the second magnetic pole. Therefore, uneven erosion does not occur in the erosion region having the target track shape.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

The whole device of the embodiment of the present invention is the same as the whole of the conventional device shown in FIG. 4, and the drawing showing the whole device of the embodiment of the present invention is incorporated by reference to FIG. The electromagnet used in the apparatus of the embodiment is the same as the conventional electromagnet shown in FIG. 5, and the drawing of the electromagnet used in the apparatus of the embodiment of the present invention is incorporated by reference to FIG. Therefore, the description of the entire apparatus and the electromagnet of the embodiment of the present invention will be omitted.

However, in the embodiment of the present invention, unlike the conventional one, as shown in FIGS. 1 and 2, the back surface of the target 4 made of a magnetic material also serving as the cathode electrode corresponds to the first magnetic pole. And the second semi-cylindrical portion 5b ₂ of the central yoke 5b
Between the semi-cylindrical portion 5c ₂ of the peripheral yokes 5c corresponding to magnetic poles of the target 4 of the same material, or compensation magnetic plate 11 is solder made of a magnetic material close to that of this and relative permeability, adhesive or filler And the radius r ₀ of the semi-cylindrical portion 5b ₂ of the yoke 5b
The value obtained by adding the thickness of the target 4 and the thickness of the compensating magnetic plate 11 at a point separated by a distance r from the center axis of the above is a value proportional to 1 / r.

Therefore, with reference to FIG. 3, considering the situation of the magnetic flux density only in the target 4, in FIG. 3, at a distance r ₁ from the center axis of the radius r ₀ of the semi-cylindrical portion 5b ₂ yokes 5b When the magnetic flux density at B ₁ is B ₁ and the magnetic flux density at distance r ₂ is B ₂ ,
It becomes as shown by the following formula.

Then, when the stuck compensation magnetic plate 11 on the back surface of the target 4, at a point at a distance r from the center axis of the radius r ₀ of the semi-cylindrical portion 5b ₂ yokes 5b as shown in FIG. 2, the target 4 and the thickness of the compensating magnetic plate 11 are added to t.
In this case, since t is tr1 / r, the magnetic flux density between the target 4 and the compensating magnetic plate 11 is expressed by the following equation.

The equation (4), the density of magnetic flux passing through both the target 4 and the compensation magnetic plate 11, regardless from the distance r central axis of the radius r ₀ of the semi-cylindrical portion 5b _2, indicating that constant across I have.

Therefore, the distribution of the magnetic flux density of the leakage magnetic field formed in the space in the vicinity of the surface of the target 4 between the semi-cylindrical portion 5c ₂ of the semi-cylindrical portion 5b ₂ and a peripheral yokes 5c of the central yoke 5b is
Since there is a close relationship between the distribution of magnetic flux density at both the target 4 and the compensation magnetic plate 11, unlike the conventional, it will not decrease with distance from the semi-cylindrical portion 5b ₂ of the central yoke 5b. Therefore, at the center of the semicircle portion 10b of the erosion region 10 in which the track shape of the target 4, is as erosion occurs, erosion does not occur biased to half cylindrical portion 5b ₂ side of the center yoke 5b.

Therefore, in particular, if the plasma is oscillated over the entire width of the erosion region 10 by changing the current flowing through the peripheral coil 6b of the coil 6, the utilization efficiency of the target 4 is improved.

Although the electromagnet 7 is used in the above-described embodiment, the first magnetic pole and the second magnetic pole may be formed by using a permanent magnet instead of the electromagnet 7. Also, the first magnetic pole and the second magnetic pole
May be a combination of an electromagnet and a permanent magnet. Further, the central yoke 5b may be cylindrical, and the peripheral yoke 5c may be cylindrical.

(Effect of the Invention) Since the present invention has the above-described configuration, the erosion of the surface of the target is not biased, and the effect of improving the use efficiency of the target is achieved.

[Brief description of the drawings]

FIG. 1 is a plan view of an embodiment of the present invention, FIG. 2 is a cross-sectional view taken along line AA of FIG. 1, and FIG. 3 is an explanatory diagram for explaining the state of magnetic flux density in a target. . FIG. 4 is an explanatory view showing the entire conventional apparatus, FIG. 5 is a perspective view of an electromagnet used in the conventional apparatus, and FIG. 6 is a plan view showing a track-shaped erosion area on the surface of a target. In the figure, 1 ...... vacuum tank 4 ...... target 5 ...... yoke 5a ...... bottom yoke 5b ...... central yoke 5b ₁ ...... longitudinal section 5b ₂ ...... semicylindrical portion 5c ...... peripheral yoke 5c ₁ ...... longitudinal periphery Part 5c ₂ … Semi-cylindrical part 6… Coil 7… Electromagnet 10… Erosion area 10a… Linear part 10b… Semi-circular part 11… Compensating magnetic plate

Claims (2)

(57) [Claims] A first magnetic pole is provided at a central portion of a back surface of a target disposed in a vacuum chamber, and a second magnetic pole surrounding the first magnetic pole at a predetermined interval also at a peripheral portion of the back surface of the target. And a part of the magnetic flux generated between the first magnetic pole and the second magnetic pole is leaked to the space near the surface of the target, and the leaked magnetic flux increases the density of plasma in the space near the surface of the target, In a magnetron sputtering apparatus which sputters a target between the first magnetic pole and the second magnetic pole with ions in the plasma having a high density and forms a track-shaped erosion region thereon, Between the first magnetic pole and the second magnetic pole on the back surface of the semicircular portion of the erosion area of the erosion region, the thickness increases from the first magnetic pole to the second magnetic pole. Magnetron sputtering apparatus, characterized in that a thinning compensating magnetic plate. 2. The first magnetic pole has semi-cylindrical portions on both sides,
The second magnetic pole has a semi-cylindrical portion surrounding the semi-cylindrical portion of the first magnetic pole, and the target is located between the semi-cylindrical portion of the first magnetic pole and the semi-cylindrical portion of the second magnetic pole. A compensation magnetic plate is provided on the back surface, and the value obtained by adding the thickness of the compensation magnetic plate to the thickness of the target at the point separated by a distance r from the center axis of the radius of the semi-cylindrical portion of the first magnetic pole is 1 / r. 2. The magnetron sputtering apparatus according to claim 1, wherein the value is proportional to.