This Application is a U.S. national phase application under 35 U.S.C. §371 of PCT Application No. PCT/JP2012/065755 filed on Jun. 20, 2012, which claims the benefit of Japanese Patent Application No. 2011-144814 filed on Jun. 29, 2011, the entire disclosures of which are incorporated herein by reference.
The embodiments described herein pertain generally to a plating method, a plating apparatus and a storage medium for performing a plating process by supplying a plating liquid onto a surface of a substrate.
In general, a wiring is formed on a substrate such as a semiconductor wafer or a liquid crystal substrate to form a circuit on a surface of the substrate. The wiring is typically made of, instead of aluminum, copper having low electric resistance and high reliability. Since, however, copper tends to be easily oxidized as compared to aluminum, it is required to plate a surface of the copper wiring with a metal having high electromigration resistance in order to suppress the surface of the copper wiring from being oxidized.
For example, a plating process is performed by supplying an electroless plating liquid onto the surface of the substrate on which the copper wiring is formed. Conventionally, such an electroless plating process is performed by a batch-type processing apparatus, in general. In the electroless plating process, in order to form a plating film by incurring an oxidation-reduction reaction in the vicinity of a surface of a wafer, it is desirable to stand the wafer without being shaken during the film forming process. For this reason, when performing the electroless plating process in the batch-type processing apparatus, a film forming rate of the plating film is controlled by adjusting a temperature of the plating liquid, a concentration of the plating liquid and a film forming time. Further, in consideration of the structure of the batch-type processing apparatus, even if it is attempted to move the wafer in the plating liquid, the wafer would be shaken only several centimeters. Thus, when the conventional batch-type processing apparatus is used, it may be difficult to improve a reaction rate of the plating liquid over a current level.
Patent Document 1: Japanese Patent Laid-open Publication No. 2009-249679
Patent Document 2: Japanese Patent Laid-open Publication No. 2001-073157
Meanwhile, as a single-wafer processing apparatus configured to perform an electroless plating process on wafers sheet by sheet, Japanese Patent Laid-open Publication No. 2009-249679 describes a plating apparatus including a substrate rotating device configured to rotate the substrate, a nozzle configured to discharge the plating liquid onto the substrate, and a nozzle moving device configured to move the nozzle along the substrate. In the plating apparatus described in Patent Document 1, by supplying the electroless plating liquid while rotating the substrate, a uniform flow of the plating liquid is formed on the surface of the substrate. As a result, a plating process is performed on the entire surface of the substrate uniformly.
Further, Japanese patent Laid-open Publication No. 2001-073157 describes a technique of repeating a chemical liquid coating process, a chemical liquid accumulating process and a chemical liquid removing process plural times in order to reduce an amount of the used chemical liquid. When forming a plating film having a thick thickness through this method, however, a processing time may be lengthened.
In view of the foregoing problems, the present example embodiment provides a plating method, a plating apparatus and a storage medium capable of reducing a plating time for a single substrate by improving a reaction rate of a plating liquid.
In one example embodiment, a plating method performs a plating process by supplying a plating liquid onto a substrate. The plating method includes a liquid displacement process of performing a liquid displacement by supplying the plating liquid onto the substrate while rotating the substrate at a first rotational speed in a state that a pre-treatment liquid remains on a surface of the substrate; an incubation process of forming an initial film on the substrate by stopping the rotation of the substrate or by rotating the substrate at a second rotational speed while continuously supplying the plating liquid onto the substrate; and a plating film growing process of growing a plating film by rotating the substrate at a third rotational speed while continuously supplying the plating liquid onto the substrate. Here, the first rotational speed is higher than the third rotational speed, and the third rotational speed is higher than the second rotational speed.
In another example embodiment, a plating apparatus performs a plating process by supplying a plating liquid onto a substrate. The plating apparatus includes a substrate holding/rotating device configured to hold and rotate the substrate; a discharging device configured to discharge the plating liquid toward the substrate held on the substrate holding/rotating device; a plating liquid supplying device configured to supply the plating liquid to the discharging device; and a controller configured to control the substrate holding/rotating device, the discharging device and the plating liquid supplying device. Further, the controller is configured to control the substrate holding/rotating device, the discharging device and the plating liquid supplying device to perform a liquid displacement by supplying the plating liquid onto the substrate from the discharging device while rotating the substrate at a first rotational speed through the substrate holding/rotating device in a state that a pre-treatment liquid remains on a surface of the substrate; to form an initial film on the substrate by stopping the rotation of the substrate or by rotating the substrate at a second rotational speed through the substrate holding/rotating device while continuously supplying the plating liquid onto the substrate from the discharging device; and to grow a plating film by rotating the substrate at a third rotational speed through the substrate holding/rotating device while continuously supplying the plating liquid onto the substrate from the discharging device. Here, the first rotational speed is higher than the third rotational speed, and the third rotational speed is higher than the second rotational speed.
In yet another example embodiment, a computer-readable storage medium has stored thereon a computer-executable instructions that, in response to execution, cause a plating apparatus to perform a plating method of performing a plating process by supplying a plating liquid onto a substrate. Further, the plating method includes a liquid displacement process of performing a liquid displacement by supplying the plating liquid onto the substrate while rotating the substrate at a first rotational speed in a state that a pre-treatment liquid remains on a surface of the substrate; an incubation process of forming an initial film on the substrate by stopping the rotation of the substrate or by rotating the substrate at a second rotational speed while continuously supplying the plating liquid onto the substrate; and a plating film growing process of growing a plating film by rotating the substrate at a third rotational speed while continuously supplying the plating liquid onto the substrate. Here, the first rotational speed is higher than the third rotational speed, and the third rotational speed is higher than the second rotational speed.
In accordance with the example embodiment, in a state that a pre-treatment liquid remains on a surface of a substrate, a liquid displacement is performed by supplying a plating liquid onto the substrate while rotating the substrate at a first rotational speed (liquid displacement process). Subsequently, by stopping the rotation of the substrate or rotating the substrate at a second rotational speed while continuously supplying the plating liquid onto the substrate, an initial film is formed on the substrate (incubation process). Thereafter, by rotating the substrate at a third rotational speed while continuously supplying the plating liquid onto the substrate, a plating film is grown (plating film growing process). In this case, the first rotational speed is set to be higher than the third rotational speed, and the third rotational speed is set to be higher than the second rotational speed. In this way, by rotating the substrate at the third rotational speed while continuously supplying the plating liquid onto the substrate after the initial film is formed on the substrate, it is possible to displace the plating liquid, in which a concentration of reactive species is reduced, by a new plating liquid. As a result, stable growth of the plating film can be accelerated and a plating time for a single substrate can be shortened.
Hereinafter, an example embodiment will be described with reference to
(Plating System)
As depicted in
(Substrate Loading/Unloading Chamber)
The substrate loading/unloading chamber 5 includes a carrier mounting unit 4; a transfer chamber 9 accommodating therein a transfer device 8; and a substrate transit chamber 11 accommodating therein a substrate transit table 10. Within the substrate loading/unloading chamber 5, the transfer chamber 9 and the substrate transit chamber 11 are connected to and communicate with each other via a transit opening 12. The carrier mounting unit 4 mounts thereon a multiple number of carriers 3, and each of the carriers 3 accommodates therein a multiple number of substrates 2 while holding the substrates 2 horizontally. In the transfer chamber 9, the substrates 2 are transferred, and in the substrate transit chamber 11, the substrates 2 are transited to and from the substrate processing chamber 6.
In this substrate loading/unloading chamber 5, the substrates 2 are transferred by the transfer device 8 between a single carrier 3 mounted on the carrier mounting unit 4 and the substrate transit table 10 by a preset number.
(Substrate Processing Chamber)
The substrate processing chamber 6 includes a substrate transfer unit 13 extended in a forward-backward direction (left-right direction in
The substrate transfer unit 13 includes a substrate transfer device 14 configured to be movable in the forward-backward direction. Further, the substrate transfer unit 13 communicates with the substrate transit table 10 of the substrate transit chamber 11 via a substrate loading/unloading opening 15.
In this substrate processing chamber 6, the substrates 2 are transferred into each of the plating apparatuses 20 one by one by the substrate transfer device 14 of the substrate transfer unit 13 while held on the substrate transfer device 14 horizontally. Further, in each of the plating apparatuses 20, a cleaning process and a plating process are performed on the substrates 2 one by one.
Except that the respective plating apparatuses 20 use different kinds of plating liquids, the respective plating apparatuses 20 have substantially the same configuration. Thus, hereinafter, a configuration of a single plating apparatus 20 among the multiple number of plating apparatuses 20 will be explained on behalf of the others.
(Plating Apparatus)
Below, referring to
The plating apparatus 20 includes, as illustrated in
(Substrate Holding/Rotating Device)
The substrate holding/rotating device 110 includes, as illustrated in
(Discharging Device)
Now, the discharging device 21 configured to discharge a plating liquid or the like toward the substrate 2 will be elaborated. The discharging device 21 includes a first discharge nozzle 45 which are configured to discharge a plating liquid for chemical reduction plating, such as a CoP plating liquid, toward the substrate 2. The plating liquid for the chemical reduction plating is supplied to the first discharge nozzle 45 from the plating liquid supplying device 30. Details of the first discharge nozzle 45 will be elaborated later. Further, though only one first discharge nozzle 45 is illustrated in
The discharging device 21 may further include, as illustrated in
The discharge opening 71 of the second discharge nozzle 70 is connected via a valve 76a to a plating liquid supplying device 76 configured to supply a plating liquid for displacement plating such as a Pd plating liquid. The discharge opening 72 is connected via a valve 77a to a cleaning liquid supplying device 77 configured to supply a cleaning liquid. By providing the second discharge nozzle 70 having the above-described configuration, it is possible to perform a plating process by using the plating liquid for the displacement plating and a cleaning process as well as a plating process by using the plating liquid for the chemical reduction plating within a single plating apparatus 20.
Further, as depicted in
(First Discharge Nozzle)
Now, the first discharge nozzle 45 will be elaborated. As depicted in
(Plating Liquid Supplying Device)
Now, the plating liquid supplying device 30 configured to supply the plating liquid for the chemical reduction plating, such as the CoP plating liquid, to the first discharge nozzle 45 of the discharging device 21 will be described.
As illustrated in
Further, as depicted in
The aforementioned “storage temperature” is set to be a certain temperature higher than a room temperature and lower than a temperature (plating temperature) at which precipitation of metal ions progresses through self-reaction within the plating liquid 35. Further, the “discharge temperature” is set to be certain temperatures equal to or higher than the plating temperature. In accordance with the present example embodiment, the plating liquid 35 is heated to a temperature equal to or higher than the plating temperature through two stages.
Accordingly, as compared to a case where the plating liquid 35 is heated to a temperature equal to or higher than the plating temperature within the supply tank 31, it is possible to suppress deactivation of a reducing agent in the plating liquid 35 or evaporation of a component of the plating liquid 35 within the supply tank 31. Therefore, a decrease of lifetime of the plating liquid 35 can be suppressed. Further, as compared to a case where the plating liquid 35 is stored at the room temperature within the supply tank 31 and later heated to a temperature equal to or higher than the plating temperature by the heating unit 60, it is possible to heat the plating liquid 35 to the temperature equal to or higher than the plating temperature promptly with low energy. Accordingly, precipitation of metal ions can be suppressed.
Various kinds of chemical liquids are supplied into the supply tank 31 from a multiple number of chemical liquid supplying sources (not illustrated) in which various kinds of components of the plating liquid 35 are stored. By way of non-limiting example, chemical liquids such as a CoSO4 metal salt containing Co ions, a reducing agent (e.g., hypophosphorous acid, etc.) and an additive are supplied in the supply tank 31. Here, flow rates of the various kinds of the chemical liquids are controlled so that the components of the plating liquid 35 stored in the supply tank 31 are appropriately adjusted.
(Tank Heating Unit)
The tank heating unit 50 includes, as illustrated in
Further, as illustrated in
Moreover, as illustrated in
As illustrated in
(Heating Unit)
Now, referring to
The temperature controller 62 includes a supply opening 62a through which the heat transfer medium (e.g., hot water) for temperature control is introduced from the temperature medium supplying unit 61; and a draining opening 62b through which the heat transfer medium is discharged out. The heat transfer medium supplied through the supply opening 62a comes into contact with the supply line 33 while the heat transfer medium flows in a space 62c within the temperature controller 62. With this configuration, the plating liquid 35 flowing through the supply line 33 is heated to the discharge temperature. After used for heating the plating liquid 35, the heat transfer medium is discharged out through the draining opening 62b.
Desirably, the supply line 33 within the temperature controller 62 may be formed to have a spiral shape, as illustrated in
The temperature maintaining unit 65 is configured to maintain, before the plating liquid 35 heated to the discharge temperature by the temperature controller 62 is discharged from the first discharge nozzle 45, the temperature of the plating liquid 35. The temperature maintaining unit 65 includes, as illustrated in
As shown in
(Liquid Draining Device)
Now, the liquid draining devices 120, 125 and 130 configured to drain the plating liquid or the cleaning liquid dispersed from the substrate 2 will be elaborated with reference to
The processing liquids dispersed from the substrate 2 are drained by the liquid draining devices 120, 125 and 130 through the draining openings 124, 129 and 134, respectively, while separated by their kinds. By way of example, the CoP plating liquid dispersed from the substrate 2 may be drained by the plating liquid draining device 120; the Pd plating liquid dispersed from the substrate 2 may be drained by the plating liquid draining device 125; and the cleaning liquid or the rinse liquid dispersed from the substrate 2 may be drained by the processing liquid draining device 130.
(Other Constituent Components)
As shown in
The plating system 1 including the multiple number of plating apparatuses 20 having the above-described configuration is controlled by the controller 160 according to various kinds of programs recorded on a storage medium 161 provided in the controller 160. Therefore, various processes are performed on the substrate 2. Here, the storage medium 161 stores thereon various kinds of setup data or various kinds of programs such as a plating program to be described later. The storage medium 161 may be implemented by a computer-readable memory such as a ROM or a RAM, or a disk-type storage medium such as a hard disk, a CD-ROM, DVD-ROM or a flexible disk, as commonly known in the art.
(Plating Method)
In the present example embodiment, the plating system 1 and the plating apparatus 20 are controlled by the controller 160 to perform a plating process on the substrate 2 according to a plating program recorded on the storage medium 161. In the following description, a method of performing a Pd plating process on the substrate 2 by the displacement plating and then performing a Co plating process by the chemical reduction plating in a single plating apparatus 20 will be explained with reference to
(Substrate Loading Process and Substrate Receiving Process)
First, a substrate loading process and a substrate receiving process are performed. A single sheet of substrate 2 is loaded into the one plating apparatus 20 from the substrate transit chamber 11 by the substrate transfer device 14 of the substrate transfer unit 13. In the plating apparatus 20, the cup 105 is lowered to a preset position, and the loaded substrate 2 is held by the wafer chuck 113. Then, the cup 105 is raised by the elevating device 164 up to a position where an outer peripheral end portion of the substrate 2 faces the draining opening 134.
(Cleaning Process)
Thereafter, a cleaning process (block S301) including a rinse process, a pre-cleaning process and another rinse process is performed. First, the valve 78a of the rinse liquid supplying device 78 is opened, and a rinse liquid is supplied onto the surface of the substrate 2 through the discharge opening 72 of the second discharge nozzle 70. Then, a pre-cleaning process is performed. First, the valve 77a of the cleaning liquid supplying device 77 is opened, and a cleaning liquid is supplied onto the surface of the substrate 2 through the discharge opening 72 of the second discharge nozzle 70. Further, for example, malic acid may be used as the cleaning liquid, and pure water may be used as the rinse liquid. Thereafter, the rinse liquid is also supplied onto the surface of the substrate 2 through the discharge opening 72 of the second discharge nozzle 70 in the same manner as described above. The used rinse liquid and the used cleaning liquid are disposed of through the draining opening 134 of the cup 105 and the processing liquid draining device 130. Unless otherwise mentioned, in the cleaning process (block S301) and subsequent processes to be described below, the substrate 2 is being rotated in the first rotational direction R1 by the substrate holding/rotating device 110.
(Pd Plating Process)
Subsequently, a Pd plating process (block S302) is performed. This Pd plating process (block S302) is performed as a displacement plating process while the substrate 2 is not yet dried after the cleaning process is completed. By performing the displacement plating process while the substrate 2 is not yet dried, it may be possible to avoid a case where the displacement plating process is not effectively performed since copper or the like on a plating target surface of the substrate 2 is oxidized.
In the Pd plating process, the cup 105 is lowered by the elevating device 164 to a position where the draining opening 129 and the outer peripheral end portion of the substrate 2 face each other. Then, the valve 76a of the plating liquid supplying device 76 is opened, and a Pd-containing plating liquid is discharged onto the surface of the substrate 2 through the discharge opening 71 of the second discharge nozzle 70 at a desired flow rate. As a result, Pd plating is performed on the surface of the substrate 2. The used plating liquid is drained out through the draining opening 129 of the cup 105. Thereafter, the used plating liquid drained out through the draining opening 129 is collected through the liquid draining device 125. Then, the plating liquid is reused or wasted.
(Rinse Process)
Thereafter, as a pre-treatment to be performed prior to the Co plating process, a rinse process (block S303) is performed, for example. By way of example, in the rinse process (block S303), the rinse liquid is supplied onto the surface of the substrate 2 as a pre-treatment liquid. Further, after the rinse process, the substrate 2 may be cleaned through a chemical liquid process using a chemical liquid. Thereafter, in order to remove the chemical liquid, another rinse process may be performed by using the rinse liquid.
(Co Plating Process)
Then, a Co plating process (block S304) is performed in the same plating apparatus 20 as used in performing the above-described processes (blocks S301 to S303). This Co plating process (block S304) is performed as a chemical reduction plating process. The Co plating process (block S304) includes, as shown in
In the Co plating process, an element that is precipitated to form a plating layer may not be limited to Co, and another element may also be precipitated at the same time. By way of example, when a plating liquid used in the Co plating process contains not only Co ions but also ions of other element, Co and the other element may be precipitated concurrently. Here, description will be provided for a case where Co ions and P ions are contained in the plating liquid and, thus, a plating layer (CoP) containing P as well as Co is formed. In the following description, even if the element other than Co is contained in the plating layer, the plating layer obtained through the Co plating process will be referred to as a “Co plating layer.”
Among the aforementioned processes (blocks S305 to S307), the liquid displacement process (block S305) is a process for displacing the rinse liquid (e.g., pure water) supplied on the substrate 2 in the rinse process (block S303) and remaining on the surface of the substrate 2 by the plating liquid 35 for forming CoP. The incubation process (block S306) is a process for forming an initial Co plating layer 84 on an entire region of a Pd plating layer 83 to be described later while continuously supplying the plating liquid 35 onto the substrate 2 after performing the liquid displacement process (block S305). Here, the initial Co plating layer 84 refers to a plating layer having a thickness in a range of, but not limited to, from several nanometers to several tens of nanometers. Further, the plating film growing process (block S307) is a process for forming the Co plating layer 84 having a sufficient thickness in a range of, but not limited to, from about 100 nanometers to about 1 micrometer by allowing the plating reaction to further progress on the initial Co plating layer 84 formed in the incubation process (block S306) while continuously supplying the plating liquid 35 onto the substrate 2.
Below, the Co plating process will be described in detail with reference to
(Liquid Displacement Process)
First, the controller 160 controls the substrate holding/rotating device 110 to rotate the substrate 2 held on the substrate holding/rotating device 110 at a first rotational speed (
By discharging the plating liquid 35 toward the substrate 2 by using the first discharge nozzle 45, the rinse liquid 79 existing on the substrate 2 is displaced by the plating liquid 35 for forming CoP, as illustrated in
(Incubation Process)
Subsequently, while continuously supplying the plating liquid 35 onto the substrate 2 by using the first discharge nozzle 45, the controller 160 controls the substrate holding/rotating device 110. That is, the rotation of the substrate 2 held on the substrate holding/rotating device 110 is stopped, or the substrate 2 is rotated at a second rotational speed lower than the first rotational speed (
That is, while continuously discharging the plating liquid 35 toward the substrate 2 by using the first discharge nozzle 45, as depicted in
Further, a time required for the incubation process (block S306) is set to be longer than a time required for the liquid displacement process (block S305). Desirably, the time for the incubation process (block S306) may be set to be in the range, but not limited to, from about 10 seconds to about 10 minutes.
Moreover, in the incubation process (block S306), when supplying the plating liquid 35 onto the substrate 2, the first discharge nozzle 45 may be stopped at the central position near the central portion of the substrate 2 or may be moved horizontally between the central position (indicated by a reference numeral 45′ in
As shown in
(Plating Film Growing Process)
Subsequently, while continuously supplying the plating liquid 35 onto the substrate 2 by using the first discharge nozzle 45, the controller 160 controls the substrate holding/rotating device 110 to rotate the substrate 2 held on the substrate holding/rotating device 110 at a third rotational speed (
That is, while continuously discharging the plating liquid 35 toward the substrate 2 by using the first discharge nozzle 45, as illustrated in
Furthermore, in the plating film growing process (block S307), when supplying the plating liquid 35 onto the substrate 2, the first discharge nozzle 45 may be stopped at the central position near the central portion of the substrate 2 or may be moved between the central position (indicated by the reference numeral 45′ in
As depicted in
Moreover, in the plating film growing process (block S307), the substrate 2 need not continuously be rotated at the constant rotational speed, and the rotational speed of the substrate 2 may be temporarily decreased or the rotation of the substrate 2 may be temporarily stopped. If the third rotational speed is set to be excessively low, however, the above-described effect of suppressing a decrease of the concentration of the reactive species in the plating liquid 35 and thus accelerating the stable growth of the plating film may not be obtained. Meanwhile, if the third rotational speed is set to be excessively high, for example, over the first rotational speed, the Co plating layer 84 may not be grown uniformly on the entire surface of the substrate 2.
In the Co plating process (block S304), the cup 105 is lowered by the elevating device 164 to a position where the draining opening 124 and the outer peripheral end portion of the substrate 2 face each other. Accordingly, the used plating liquid 35 is drained out through the draining opening 124 of the cup 105. After drained, the used plating liquid 35 is collected through the liquid draining device 120 and, then, reused or wasted.
In this way, the Co plating process (block S304) including the liquid displacement process (block S305) (first process), the incubation process (block S306) (second process) and the plating film growing process (block S307) (third process) is completed.
(Cleaning Process)
Thereafter, a cleaning process (block S308) including a rinse process, a post-cleaning process and another rinse process is performed on the surface of the substrate 2 on which the Co plating process has been performed. Since the cleaning process (block S308) is substantially the same as the above-described cleaning process (block S301), detailed elaboration thereof will be omitted.
(Drying Process)
Then, a drying process (block S309) for drying the substrate 2 is performed. By way of example, by rotating the turntable 112, the liquid adhering to the substrate 2 may be dispersed outward by a centrifugal force, so that the substrate 2 may be dried. That is, the turntable 112 may serve as a drying device configured to dry the surface of the substrate 2.
As discussed above, in the single plating apparatus 20, the Pd plating is first performed on the surface of the substrate 2 by the displacement plating, and the Co plating is then performed by the chemical reduction plating.
Thereafter, the substrate 2 may be transferred into another plating apparatus 20 for Au plating.
In this another plating apparatus 20, an Au plating process is performed on the surface of the substrate 2 by the displacement plating. Except that a plating liquid and a cleaning liquid different from those of the Pd plating process are used, the method of the Au plating is substantially the same as that of the Pd plating process as described above. Thus, detailed description thereof will be omitted here.
(Effects of Example Embodiment)
In accordance with the example embodiment, as described above, in the state that the rinse liquid remains on the surface of the substrate 2, the liquid displacement is performed by supplying the plating liquid 35 onto the substrate 2 while rotating the substrate 2 at the first rotational speed (liquid displacement process (block S305)). Subsequently, while continuously supplying the plating liquid 35 onto the substrate 2, the substrate 2 is stopped or rotated at the second rotational speed, so that the initial plating film is formed on the substrate 2 (incubation process (block S306)). Thereafter, while continuously supplying the plating liquid 35 onto the substrate 2, the substrate is rotated at the third rotational speed, so that the plating film grows (plating film growing process (block S307)). Here, the first rotational speed is set to be higher than the third rotational speed, and the third rotational speed is set to be higher than the second rotational speed. By way of non-limiting example, the first rotational speed may be set to be in the range from about 100 rpm to about 300 rpm; the second rotational speed may be set to be in the range from about 0 rpm to about 30 rpm; and the third rotational speed may be set to be in the range from about 30 rpm to about 100 rpm. Accordingly, particularly in the plating film growing process (block S307), it is possible to displace the plating liquid 35, in which a concentration of the reactive species is reduced, by a new plating liquid 35, so that the stable growth of the plating film can be accelerated. As a result, a plating time for a single substrate can be shortened.
Further, the present example embodiment has been described for the case where the CoP plating liquid is used as the plating liquid 35 for the chemical reduction plating discharged toward the substrate 2 from the first discharge nozzle 45. However, the plating liquid 35 may not be limited to the CoP plating liquid, and various other kinds of plating liquids 35 can be employed. By way of non-limiting example, various plating liquids 35 such as a CoWB plating liquid, a CoWP plating liquid, a CoB plating liquid or a NiP plating liquid may be used as the plating liquid 35 for the chemical reduction plating.
Number | Date | Country | Kind |
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2011-144814 | Jun 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/065755 | 6/20/2012 | WO | 00 | 12/27/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/002096 | 1/3/2013 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
20050095830 | Weidman | May 2005 | A1 |
20060234508 | Shirakashi | Oct 2006 | A1 |
20090253258 | Hara et al. | Oct 2009 | A1 |
20100075027 | Toshima | Mar 2010 | A1 |
Number | Date | Country |
---|---|---|
2001-073157 | Mar 2001 | JP |
2004-15028 | Jan 2004 | JP |
2009-249679 | Oct 2009 | JP |
4593662 | Dec 2010 | JP |
Entry |
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International Search Report for PCT/JP2012/065755 dated Jul. 24, 2012. |
Number | Date | Country | |
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20140127410 A1 | May 2014 | US |