`
`I, Naoko UNO, c/o Sakai International Patent Office, SF, Toranomon Mitsui Building 8-1,
`
`Kasumigaseki 3-chome, Chiyoda-ku, Tokyo, 100-0013, Japan, do hereby certify that I am fluent in the
`
`English and Japanese languages and a competent translator thereof, and that to the best of my
`
`knowledge and belief the following is a true and correct translation of the accompanying Non-English
`
`Language Japanese Patent Application Laid-Open Publication No. JPOS-191059 A.
`
`I certify under penalty of perjury under the laws of the United States that the foregoing is true
`and correct.
`
`Executed this 20th day of January, 2017.
`
`Signature: __ ~~--·~-=~-· __ U ___ ..--vv-_____ _
`
`Naoko Uno
`
`Tokyo Electron Limited
`EXHIBIT 1008
`IPR Petition for
`U.S. Patent No. RE40,264
`
`Page 1 of 6
`
`
`
`(19) JAPAN PATENT OFFICE (JP)
`
`(12) PATENT APPLICATION
`LAID-OPEN PUBLICATION (A)
`
` (11) PUBLICATION NUMBER
`JP 8-191059 A
`(43) DATE OF PUBLICATION
` 23. 07. 1996 (H8)
`
`(51) Int.Cl6
`H01L 21/3065
`C08J 7/00
`C23F 4/00
`C30B 25/12
`
`IDENTIFICATION CODE: JPO REFERENCE NUMBER F1
`
`TECHNICAL INDICATIONS
`
`306
`
`A
`
`A
`H01L 21/302
`Request for Examination: Not Filed
`Number of Claims: 1 OL (5 pages total) continued to the last page
`
`(21) Application Number: H07-1039
`
`(22) Date of Filing: 09. 01. 1995 (H7)
`
`(71) Applicant: 000005108
`Hitachi, Ltd.
`4-6 Kandasurugadai,
`Chiyoda-ku, Tokyo
`
`(72) Inventor:
`
`Manabu EDAMURA
`c/o Mechanics Research
` Institute, Hitachi, Ltd.
`502 Kandatsu-cho, Tsuchiura-
`shi, Ibaragi
`
`(74) Representative: Patent Attorney
`Masao OGAWA
`
`(54) [Title of the Invention] PLASMA PROCESSING APPARATUS
`
`(57) [ABSTRACT]
`[CONSTITUTION]
` In a plasma processing apparatus provided with a plasma
`source and a stage 7 for holding a processed object in a
`processing chamber 1 to heat or cool the processed object,
`the stage 7 is divided into a plurality of blocks 8 and a heat
`quantity transmitted from the processed object to the stage 7
`is controlled for each block 8, so that the temperature
`distribution of the processed object can be controlled freely,
`and the temperature of the processed object is uniform
`during plasma processing.
`
`[PURPOSE]
` It is possible to freely control the temperature distribution
`of the processed object, and in a semiconductor
`manufacturing process, a finer and higher-performance
`semiconductor can be manufactured. In addition, it is
`possible to reduce dust falling on the processed object and
`to improve the yield of semiconductor elements.
`
`Page 2 of 6
`
`
`
`[Claim(s)]
`[Claim 1] A plasma processing apparatus characterized in that
`the apparatus comprises: a plasma source; and a stage configured
`to hold a processed object in a processing chamber and to heat or
`cool the processed object, the stage being divided into a plurality
`of blocks, and a temperature of each of the blocks is set
`independently from each other so that a temperature distribution
`of the processed object can be set.
`
`[Detailed Description of the Invention]
`[0001]
`[Industrial Applicability] The present invention relates to a
`plasma processing apparatus that allows temperature distribution
`control of a processed object.
`[0002]
`[Description of the Prior Art] In recent years, a semiconductor
`device has become still smaller, and higher scale integration has
`been achieved. In order to manufacture a semiconductor device
`with higher precision, it is necessary to set various conditions
`which affect processes. Among semiconductor processes used
`today, many of the film formation and etching processes are
`plasma processing, in which a processing gas is introduced into a
`vacuum chamber, and ionized by energy of a direct voltage, a μ
`wave, a high-frequency wave, and the like, so that a film is
`formed on a semiconductor wafer and etched.
`[0003] The temperature of a semiconductor wafer (hereinafter
`referred to as wafer) during the plasma processing is one of the
`important parameters determining the precision achieved in the
`processing, and it is required to uniformize the wafer temperature
`distribution during the processing.
`[0004] In the plasma processing apparatuses, for example, in an
`etching apparatus, a wafer is heated by plasma during processing,
`and hence, it is necessary to cool the wafer in order to keep the
`wafer temperature at a desired level. A first conventional
`technique for cooling a wafer uses an electrostatic force to hold
`the wafer on to a cooled stage as described in JP S56-53853 B
`and JP S57-44747 B. A second conventional technique for
`cooling a wafer holds the wafer onto the stage by mechanical
`means such as a clamp and introduces a gas between the wafer
`and the stage to promote cooling as described in JP H2-27778 B
`and JP H2-30128 A. A third conventional technique for cooling
`a wafer introduces a gas between the wafer and the stage while
`holding the wafer by an electrostatic force as described in JP S58-
`32410 A and JP S60-115226 A.
`[0005] When these methods are employed, the wafer
`temperature is determined according to heat input from plasma
`and the heat transmission rate between the stage and the wafer.
`In the first conventional technique, there is a problem that a
`wafer cannot be sufficiently cooled due to an insufficient heat
`transmission rate. In the second and third conventional
`techniques, there is a problem that even though heat input from
`plasma is uniform in the surface of the wafer, a temperature
`distribution is generated in the wafer such that the temperature of
`the outer periphery thereof is higher because the gas pressure
`between the stage and the wafer is lower in the vicinity of the
`outer periphery of the wafer. In addition, in each case, when heat
`input from plasma is not uniform, a temperature distribution is
`generated according thereto.
`
`
`
`[0006] In addition, one of important problems for a
`semiconductor manufacturing process as typified by a plasma
`processing process is foreign matter (dust) falling on a wafer.
`In plasma processing such as CVD and etching, dust particles
`which have been grown in plasma, or dust particles peeled off
`from a surface of a processing chamber fall on the wafer, which
`causes deterioration of the film quality and reduction of the
`process yield.
`[0007] As described in one literature (Shiratani et al. Jpn. J
`Apl. Phys. 30 (1991) 1887.), it is known that dust particles are
`negatively charged in plasma and suspended above the wafer or
`the electrode in an electric field formed by plasma. The
`behavior of the dust particles is affected by gravity, gas flow,
`electric field, magnetic field, and the like; however, the
`behavior also relates to a wafer temperature which causes
`thermophoresis.
`[0008] As described in detail in one literature (G. M. Jellum et
`al. J Apl. Phys. 67 (1990) 6490.), for example, it is reported
`that dust particles with the diameter of 0.5 μm move from a
`high temperature side to a low temperature side along an
`equipotential surface due to a thermophoresis effect caused by
`temperature gradient of several °C/mm in a parallel-plate argon
`RF discharge (0.5 Torr) with electrode interval of 25 mm.
`[0009] Here, in a plasma etching apparatus, for example, since
`an object exposed to plasma is heated by incident ions, usually
`a wafer is actively cooled in order to obtain desired etching
`characteristics, and the periphery of the wafer or the electrode is
`lowest in temperature in the processing chamber. From the
`perspective of the thermophoresis effect, this satisfies a
`condition for easily collecting dust in the chamber. Therefore,
`it is expected that dust particles will be gathered near the wafer
`due to thermophoresis from a member around a processed
`object exposed to plasma, a chamber wall surface, and the like.
`[0010]
`[Problem to be solved by the invention] An object of the
`present invention is to uniformize the temperature distribution
`of a processed object, to obtain better plasma processing
`characteristics, and to reduce dust particles falling on the
`processed object.
`[0011]
`[Means for solving problem] The above problem is solved by
`configuring a stage which allows a free control of the
`temperature distribution of the processed object.
`[0012]
`[Function] According to the present invention, by configuring a
`stage which heats and cools a processed object so that the
`temperature distribution of the processed object can be freely
`controlled, it is possible to uniformize the temperature of the
`processed object and to obtain uniform plasma processing
`characteristics when the processed object is subjected to plasma
`processing.
`[0013] Furthermore, by setting the temperature distribution in
`the processed object and an object(s) around it to a
`predetermined temperature distribution (for example, a
`temperature distribution where the temperature decreases from
`the processed object to its periphery) before blocking plasma, it
`is possible to guide dust particles in plasma in a direction away
`from the processed object and to reduce dust particles falling on
`the processed object upon plasma blocking.
`
`Page 3 of 6
`
`
`
`[0014]
`[Embodiment] Although the present invention is not limited to
`the field of semiconductor manufacturing, since it seems that the
`present invention is most useful for a semiconductor
`manufacturing apparatus and a semiconductor manufacturing
`process, an embodiment will be described in a case where a
`semiconductor wafer is used as a processed object and a
`microwave plasma etching apparatus is used as a plasma
`processing apparatus.
`[0015] Fig. 1 is a cross-sectional view illustrating an
`embodiment of the present invention. The microwave plasma
`etching apparatus includes a processing chamber 1, a process gas
`introduction system 2, a microwave generation unit 3, a
`waveguide 4, a coil 5, a stage 7 for holding a wafer 6. The stage
`7 also serves as an electrode for applying a high frequency to the
`wafer 6. Details of the stage 7 are illustrated in Fig. 2, and the
`stage 7 is divided into a plurality of blocks 8a, 8b, .... Since the
`wafer 6 is approximately circular, it is desirable that the blocks
`be divided as illustrated in Fig. 3. The number of blocks is
`determined according to the accuracy degree of controlling the
`temperature distribution of the wafer. It is desirable that the
`blocks be made of a metal material with high thermal
`conductivity such as aluminum. In addition, the blocks are
`partitioned by partitions 13 made of a material lower in thermal
`conductivity than the block, such as a ceramic material. All the
`blocks are cooled by one cooling block 9. It is preferable that the
`cooling block be also made of a metal material with high thermal
`conductivity such as aluminum. Furthermore, the blocks 8a, 8b,
`... incorporate heaters 10a, 10b, …, respectively, and the heaters
`are separately controlled. Therefore, it is possible to separately
`set the temperature for each block by controlling the output of the
`heater. Electrostatic chucks 11a, 11b, … are formed on the
`surfaces of the blocks 8a, 8b, ..., respectively, and it is possible to
`electrostatically attract the wafer thereon. Furthermore, a gas of
`several Torr for promoting thermal conduction is introduced
`between the wafer and the stage. By using the stage having the
`above configuration, it is possible to freely set the temperature
`distribution of the wafer. That is, in order to increase the
`temperature at the center of the wafer, it is only necessary to
`increase the temperature of the block 10a by increasing the
`output from the heater 10a in Fig. 2. In contrast, in order to
`uniformize the wafer temperature in a case where the wafer
`temperature is not uniform even though the temperatures of the
`blocks are the same (in a case where heat input to the wafer from
`plasma is not uniform), it is only necessary to lower the set
`temperature of the block in contact with a portion high in
`temperature.
`[0016] In addition, by adding a block-temperature detection
`means 14 for detecting the temperature of the block itself as
`illustrated in Fig. 2 or further preferably, by adding a wafer-
`temperature detection means 15 as illustrated in Fig. 4, and by
`controlling a heat transfer quantity between each block and the
`wafer using a detected temperature, it is possible to always
`control the temperature distribution of the wafer to a desired
`temperature distribution even if heat input to the wafer changes.
`
`[0017] Being able to change the temperature distribution of the
`wafer contributes to reduction in dust falling on the wafer. Fig.
`5 illustrates a flowchart of an etching process which is an
`embodiment according to the present invention. As described
`above, during the etching, dust generated due to etching or
`generated from the chamber wall surface or the like is charged
`and float near the wafer. It is desirable that the wafer
`temperature be uniform as much as possible because of a
`demand for uniformizing etching. At the time point when the
`etching processing is nearly finished, if the temperature
`distribution is made to change such that the temperature of the
`center portion of the wafer is high and the periphery thereof is
`low without blocking plasma, dust moves to a peripheral
`portion due to a thermophoresis effect caused by temperature
`gradient on the wafer. At this time, if a portion whose
`temperature is lowest is provided outside the wafer (block 8d in
`the embodiment illustrated in Fig. 2), the dust is gathered to the
`portion. Therefore, by blocking plasma after removing dust on
`the wafer, it is possible to reduce dust falling on the wafer when
`blocking plasma. In addition, in the case where enlargement of
`the temperature distribution of the wafer before blocking
`plasma has an adverse effect on the etching process, it is
`possible to minimize the effect on the etching process by
`changing the temperature distribution of the wafer after
`changing plasma into clean plasma which hardly affects the
`wafer, such as argon plasma as illustrated in the flowchart of
`Fig. 6.
`[0018]
`[Effect of the invention] The plasma processing apparatus
`according to the present invention can freely control the
`temperature distribution of a processed object, and in the
`semiconductor manufacturing process, can manufacture a
`smaller and higher-performance semiconductor by making the
`wafer temperature distribution during plasma processing
`uniform. In addition, the plasma processing method according
`to the present invention can reduce dust falling on the processed
`object and can improve the yield of semiconductor elements.
`[Brief Description of the Drawings]
`[Fig. 1] Fig. 1 is a cross-sectional view illustrating one
`embodiment according to the present invention.
`[Fig. 2] Fig. 2 is a cross-sectional view illustrating the one
`embodiment according to the present invention.
`[Fig. 3] Fig. 3 is a perspective view illustrating block division
`on a stage.
`[Fig. 4] Fig. 4 is a cross-sectional view illustrating a second
`embodiment according to the present invention.
`[Fig. 5] Fig. 5 is a flowchart illustrating the one embodiment
`according to the present invention.
`[Fig. 6] Fig. 6 is a flowchart illustrating the second embodiment
`according to the present invention.
`[Reference Signs List]
`1 processing chamber, 2 process gas introduction system,
`3 microwave generation unit, 4 waveguide, 5 coil, 6 wafer, 7
`stage, 8 block, 9 cooling block, 10 heater, 11 electrostatic
`chuck, 12 gas introduction port for promoting heat transfer, 13
`partition, 14 stage-temperature detection means, 15 wafer-
`temperature detection means, 16 exhaust system, 17 high-
`frequency power supply
`
`Page 4 of 6
`
`
`
`WIG.ti
`
`< WAVP.GUIU~
`
`[FIG. 2]
`
`11, ~IJlCTROSfATIC CHUCK
`
`I!, PAR'!ITION
`
`6COII,
`
`2 PROCESS OAS INTRUCITION SYSTEM
`
`12 OAS ltm\ODUCTION PORT f'OR
`
`PROMOTll\"O ll!AT THANSf"~K
`
`9 COOLING BLOCK
`
`M 8LOCK-1'BMP~HATURF. DETECTION ~1 M~NS
`
`16 &KHA UST SYSn:M
`
`-~
`
`11 HJGH·FREQUENCY POWER SUPPLY
`
`X
`
`[FIG.3]
`
`[r'IG. 4]
`
`16 WAFER·TEMPERAT1JIIB DETECTION MEANS
`
`12 GAS lm'ROD CTION PORT FOR
`
`PROMOTING HEAT TRANSt'ER
`
`Page 5 of 6
`
`
`
`continued from the front page
`(51) Int.Cl6
`IDENTIFICATION CODE: JPO REFERENCE NUMBER F1
`C30B 25/16
`H01L 21/205
` 21/31
`// C23C 16/46
`
`C
`
`TECHNICAL INDICATIONS
`
`Page 6 of 6
`
`