The present application claims priority from Japanese patent application JP 2011-221688 filed on Oct. 6, 2011, the content of which is hereby incorporated by reference into this application.
1. Technical Field
The present invention relates to a plasma etching apparatus for use in manufacturing a semiconductor device.
2. Background Art
The plasma etching apparatus used in processing of a semiconductor device generates ions and radicals by dissociating a reactive gas by plasma within a decompression chamber, and irradiates a surface of a sample with the ions and the radicals to process the sample. It is general to create energy for generating the plasma by electromagnetic waves. From the viewpoint of a method for inputting the electromagnetic wave, the plasma etching apparatus is roughly classified into two systems. One of the systems is an electrode discharge system such as parallel plate plasma or a magnetron RIE in which an antenna electrode for generating the electromagnetic wave is disposed in the decompression chamber. The other system is an electrodeless discharge system such as microwave plasma (for example, Japanese Patent Application Laid-Open Publication No. Hei-10-64881) or an inductively coupled plasma (for example, Japanese Patent Application Laid-Open Publication No. 2006-517743), in which the antenna electrode is disposed outside of the decompression chamber, and the electromagnetic wave is introduced through a dielectric window that separates the decompression chamber from the external. In a process (front end process) of forming a transistor among processes for manufacturing the semiconductor device, in order to prevent a temporal change in discharge characteristics due to the corrosion of the antenna electrode, or the deterioration of the transistor characteristic due to heavy metal released from the corroded antenna electrode, the electrodeless discharge system has been used. The electrodeless discharge system has such a feature that non-uniform plasma is generated on the decompression chamber side of the dielectric window. Accordingly, in order to uniformly etch a sample with a large diameter, there has been used a method in which the sample is sufficiently distanced from the dielectric window, and ions are uniformized by diffusion.
The recent study has found that the radicals cannot be sufficiently uniformized in the method in which the sample is merely sufficiently distanced from the dielectric window. Under the circumstances, the present inventors have studied the positive effects of improving the uniformity by the technique disclosed in Japanese Patent Application Laid-Open Publication No. Hei-10-64881, that is, by introducing an additive gas whose slight flow rate needs to be controlled into a periphery of the sample.
However, it has been found that even if a gas that is liable to generate desired radicals is added from an outer periphery of the sample as the additive gas, there is substantially no positive effect of improving the uniformity.
An object of the present invention is to provide a plasma etching apparatus of the electrodeless system which can uniformize the radical density to improve the uniformity of etching.
In order to achieve the above object, according to one aspect of the present invention, there is provided a plasma etching apparatus that has a first gas introduction mechanism for supplying a first gas into a decompression chamber, generates plasma by inputting electromagnetic waves from an external of the decompression chamber into the decompression chamber through a dielectric window, generates radicals from the first gas by the plasma, irradiates a sample placed on a stage with the radicals, and inputs an RF (radio-frequency) power from a first RF power supply connected to the stage to generate a bias voltage in the sample for etching, the plasma etching apparatus including:
a second gas introduction mechanism for supplying a second gas aside from the first gas introduction mechanism; and
a second RF power supply for inputting the stage the RF power that allows the radicals to be generated in the outer periphery of the sample, which is different in frequency from the first RF power supply.
Also, according to another aspect of the present invention, there is provided a plasma etching apparatus that has a first gas introduction mechanism for supplying a first gas into a decompression chamber, generates plasma by inputting electromagnetic waves from an external of the decompression chamber into the decompression chamber through a dielectric window, generates radicals from the first gas by the plasma, irradiates a sample placed on a stage with the radicals, and inputs a RF power from a first RF power supply connected to the stage to generate a bias voltage in the sample for etching, the plasma etching apparatus including:
a second gas introduction mechanism for supplying a second gas aside from the first gas introduction mechanism;
an electrode disposed in an outer periphery of the sample so as to be isolated from the stage; and
a second RF power supply for inputting the RF power that allows the radicals to be generated in the outer periphery of the sample to the electrode, which is different in frequency from the first RF power supply.
According to the present invention, there can be provided the plasma etching apparatus of the electrodeless system that enables even etching because a reduction in the radicals on the outer periphery of the sample can be compensated.
The present inventors have studied reasons that the uniformity is not improved even if a gas that is liable to generate desired radicals is added from an outer periphery of the sample as an additive gas. As a result, the present inventors have found, for example, the following facts. Because oxygen radicals and carbon radicals are high in extinction probability in the inner wall of the decompression chamber, the radicals in the vicinity of the inner wall of the decompression chamber are extinguished while the radiations are diffused from the plasma generation area in the vicinity of the dielectric window to the sample, and the radical density in the outer peripheral part is reduced in the vicinity of the sample. Because the radical density is decreased, a pattern dimension after processing is thinned in the outer peripheral of the sample. The gas that is liable to generate the radicals introduced from the periphery of the sample dissociates in the plasma generation area which is not in the periphery of the sample, but above the sample and in the vicinity of the dielectric window to generate the radicals. Therefore, the entire radical density within the decompression chamber is increased, but there is no effect of increasing the radical density only in the vicinity of the inner wall of the decompression chamber, and the radical density is not uniformized. In order to increase the radical density only in the vicinity of the inner wall of the decompression chamber to uniformize the radical density, there is a need to form the plasma generation area in the vicinity of the inner wall of a processing chamber, particularly in the periphery of the sample. The present invention has been derived from the above knowledge.
Hereinafter, embodiments will be described in detail.
A first embodiment of the present invention will be described with reference to
Also, an insulating ring 35 made of dielectric material is placed on the outer periphery of the stage 18. As illustrated in
First, as the etching gas, a mixed gas of chlorine, hydrogen bromide, and oxygen is introduced from the gas introduction mechanism 19, no additive gas is supplied from the gas introduction holes 40, no RF voltage is applied from the RF power supply 2 for plasma generation, and the RF voltage is applied from the RF power supply 29 for bias to etch the silicon substrate. An oxygen radical concentration distribution in the vicinity of the sample surface in this situation is illustrated in
Under the circumstances, in order to increase the oxygen radical density in the sample outer periphery, an oxygen gas of 10 sccm is added from the gas introduction holes 40 to execute etching. The oxygen radical concentration distribution in the vicinity of the sample surface is illustrated in
Under the circumstances, the RF power of 100 W is input from the RF power supply 2 for plasma generation to execute etching. The oxygen radical concentration distribution in the vicinity of the sample surface in this situation is illustrated in
Subsequently, an influence of the pitches of the gas introduction holes 40 has been studied.
Subsequently, an influence of the position of the gas introduction holes 40 has been studied. In the above-mentioned configuration, the gas introduction holes 40 are formed in the outermost periphery of the dielectric window 26, and the results of examining the radical concentration distribution in the vicinity of the wafer as in
In this embodiment, the frequency of the RF power supply 2 for plasma generation is set to 40 MHz. However, if the RF power supply is 4 MHz or higher, the same effect is obtained even if the RF power supply 2 is set to any frequency. Also, in this embodiment, the frequency of the RF power supply 29 for bias application is set to 400 kHz. However, if the frequency is 100 kHz or higher and lower than the frequency of the RF power supply 2 for plasma generation, the same effect is obtained even if the RF power supply 29 is set to any frequency. Also, in this embodiment, the gas introduction holes 40 for additive gas are formed in the insulating ring 35 placed on the outer periphery of the stage 18. However, the same effect is obtained if the gas introduction holes 40 are formed in the outer periphery of the sample 21 and at a position closer to the sample 21 than the dielectric window 26. If the pitch of the gas introduction holes 40 is shorter than the distance between the gas introduction holes 40 and the sample 21, the same effect is obtained. Also, in this embodiment, the plasma etching apparatus of the inductively-coupled plasma system is used. However, the same effect is obtained if the plasma etching apparatus is of the electrodeless discharge system. In this embodiment, oxygen is used as the additive gas. However, the same effect is obtained even by other additive gases if the etching gas or the sample structure is different.
As described above, according to this embodiment, there can be provided the plasma etching apparatus of the electrodeless system which generates the radicals in the outer periphery of the sample to uniformize the radical density so as to improve the uniformity of etching. Also, because both of the RF voltage for bias application and the RF voltage for plasma generation are applied to the stage, the structure is simple, and an increase in the costs can be suppressed.
A second embodiment of the present invention will be described with reference to
Ions and radicals are generated from the etching gas by the plasma generation area 17, and the ions and the radicals are transported by diffusion, and can be irradiated on the sample 21 placed on the stage 18. Also, the RF power supply 29 of 400 kHz for bias supply is fitted to the stage 18 through the matching box 30 and the low-pass filter 31. A RF voltage is applied from the RF power supply 29 to the stage 18 to allow the sample 21 to generate a negative voltage so that positive ions within the decompression chamber 20 can be accelerated and irradiated. Aside from this configuration, the RF power supply 2 of 27 MHz for plasma generation is connected to the stage 18 through the matching box 32 and the high-pass filter 33, and the RF power is input to the stage 18 from the RF power supply 2 so that a ring-shaped plasma generation area 1 can be formed in the outer periphery of the sample 21. In particular, in the apparatus having the longitudinal magnetostatic field within the decompression chamber as in the magneto-microwave plasma etching apparatus, plasma can be efficiently generated in only the outer periphery of the sample 21, by mutual interaction of a lateral electric field produced in the outer periphery of the sample 21 by the electric power supplied from the RF power supply 2 for the plasma generation, and a longitudinal magnetostatic field produced by coils 56. The two RF power supplies 2 and 29 different in frequency are thus fitted to the stage 18 so that a negative voltage for accelerating positive ions and the plasma generation can be controlled, independently.
Also, the insulating ring 35 made of dielectric material is placed on the outer periphery of the stage 18. As illustrated in
With the use of this apparatus, a sample in which an Si3N4 film 300 nm in thickness is deposited on a silicon wafer of φ300 mm, and a mask made of an organic material having a line pattern 200 nm in thickness and 50 nm in width is formed on that film is etched.
First, as the etching gas, a mixed gas of CHF3 and Ar is introduced from the gas supply mechanism 16, no additive gas is supplied from the gas introduction holes 40, no RF voltage is applied from the RF power supply 2 for plasma generation, and the RF voltage is applied only from the RF power supply 29 of 400 kHz for bias to etch the silicon substrate. A CxFy radical concentration distribution in the vicinity of the sample surface in this situation is illustrated in
Under the circumstances, in order to increase the CxFy radical density in the sample outer periphery, CH2F2 of 10 sccm is added from the gas introduction holes 40 for additive gas introduction to execute etching. The radical concentration distribution in the vicinity of the sample surface is illustrated in
Under the circumstances, the RF power of 50 W is input from the RF power supply 2 for plasma generation to execute etching. The dimension of the pattern in the outer periphery of the sample 21 is increased, and the pattern dimension becomes substantially uniform within the sample plane.
Under the circumstances, the RF power of 100 W is input from the RF power supply 2 for plasma generation to execute etching. The CxFy radical concentration distribution in the vicinity of the sample surface in this situation is illustrated in
In this embodiment, the frequency of the RF power supply 2 for plasma generation is set to 27 MHz. However, if the RF power supply is 4 MHz or higher, the same effect is obtained even if the RF power supply 2 is set to any frequency. Also, in this embodiment, the frequency of the RF power supply 29 for bias application is set to 400 kHz. However, if the frequency is 100 kHz or higher and lower than the frequency of the RF power supply 2 for plasma generation, the same effect is obtained even if the RF power supply 29 is set to any frequency. Also, in this embodiment, the gas introduction holes 40 for additive gas are formed in the insulating ring 35 placed on the outer periphery of the stage 18. However, the same effect is obtained if the gas introduction holes 40 are formed in the outer periphery of the sample 21 and at a position closer to the sample 21 than the dielectric window 26. Also, in this embodiment, the plasma etching apparatus of the magneto-microwave plasma system is used. However, the same effect is obtained if the plasma etching apparatus is of the electrodeless discharge system. In this embodiment, CH2F2 is used as the additive gas. However, the same effect is obtained if the additive gas is fluorocarbon gas. Also, the same effect is obtained even by other additive gases if the etching gas or the sample structure is different.
As described above, according to this embodiment, there can be provided the plasma etching apparatus of the electrodeless system which generates the radicals in the outer periphery of the sample to uniformize the radical density so as to improve the uniformity of etching. Also, because both of the RF voltage for bias application and the RF voltage for plasma generation are applied to the stage, the structure is simple, and an increase in the costs can be suppressed.
A third embodiment of the present invention will be described with reference to
Ions and radicals are generated from the etching gas by the plasma generation area 17, and the ions and the radicals are transported by diffusion, and can be irradiated on the sample 21 placed on the stage 18. Also, the RF power supply 29 of 400 kHz for bias supply is fitted to the stage 18 through the matching box 30 and the low-pass filter 31. A RF voltage is applied from the RF power supply 29 to the stage 18 to allow the sample 21 to generate a negative voltage so that positive ions within the decompression chamber 20 can be accelerated and irradiated.
Also, the insulating ring 35 made of dielectric material is placed on the outer periphery of the stage 18. As in the figure of the first embodiment, the gas introduction holes 40 for supplying an additive gas are concentrically arranged in the insulating ring 35 as illustrated in
An electrode 41 insulated from the stage 18 is mounted on the insulating ring outside of the gas introduction holes 40. The RF power supply 2 of 27 MHz for plasma generation is connected to the stage 18 through the matching box 32 and the high-pass filter 33, and the RF power is input to the electrode 41 from the RF power supply 2 so that the plasma generation area 1 can be formed in the outer periphery of the sample 21. The two RF power supplies 2 and 29 different in frequency are thus fitted to the stage 18 and the insulated electrode 41 so that the negative voltage for accelerating the positive ions and the plasma generation can be controlled, independently.
With the use of this apparatus, a sample in which an organic film 300 nm in thickness is deposited on a silicon wafer of φ300 mm, and a mask made of SiO2 having a line pattern 20 nm in thickness and 50 nm in width is formed on the organic film is etched.
First, as the etching gas, a mixed gas of O2 and Ar is used, no additive gas is supplied, no RF voltage of 27 MHz for plasma generation is applied, and the RF voltage of 400 kHz for bias is applied to execute etching. The processing shape of the organic film in the outer periphery of the sample 21 after processing is illustrated in
Under the circumstances, in order to increase the oxygen radical density in the outer periphery of the sample 21, oxygen of 10 sccm is added from the gas introduction holes 40 for additive gas introduction to execute etching. The processing shape of the organic film in the outer periphery of the sample 21 after processing is illustrated in
Under the circumstances, the RF power of 100 W is input from the RF power supply 2 for plasma generation to execute etching. The shape after processing in this situation is illustrated in
In this embodiment, the frequency of the RF power supply 2 for plasma generation is set to 27 MHz. However, if the RF power supply is 4 MHz or higher, the same effect is obtained even if the RF power supply 2 is set to any frequency. Also, in this embodiment, the frequency of the RF power supply 29 for bias application is set to 400 kHz. However, if the frequency is 100 kHz or higher and lower than the frequency of the RF power supply 2 for plasma generation, the same effect is obtained even if the RF power supply 29 is set to any frequency. Also, in this embodiment, the gas introduction holes 40 for additive gas are formed in the insulating ring 35 placed on the outer periphery of the stage 18. However, the same effect is obtained if the gas introduction holes 40 are formed in the outer periphery of the sample 21 and at a position closer to the sample 21 than the dielectric window 26. Also, in this embodiment, the plasma etching apparatus of the microwave plasma system is used. However, the same effect is obtained if the plasma etching apparatus is of the electrodeless discharge system. In this embodiment, oxygen is used as the additive gas. However, the same effect is obtained even by other additive gases if the etching gas or the sample structure is different.
As described above, according to this embodiment, there can be provided the plasma etching apparatus of the electrodeless system which generates the radicals in the outer periphery of the sample to uniformize the radical density so as to improve the uniformity of etching. Also, the plasma generation area formation electrode in the periphery of the sample is insulated from the stage, so that the negative voltage for accelerating the positive ions and the plasma generation can be controlled, independently.
The present invention is not limited to the above-mentioned embodiments, but includes a variety of modified examples. For example, the above-mentioned embodiments are described in detail for facilitating the understanding of the present invention, and the present invention is not always limited to the inclusion of all the above-described configurations. Also, a part of a configuration in one embodiment can be replaced with a configuration in another embodiment, and the configuration of one embodiment can be added with the configuration of another embodiment. A part of the configurations in the respective embodiments can be subjected to addition, deletion, or replacement of another configuration.
Number | Date | Country | Kind |
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2011-221688 | Oct 2011 | JP | national |