The Gillette Companyv.Zond, LLCDownload PDFPatent Trial and Appeal BoardSep 30, 201511465574 (P.T.A.B. Sep. 30, 2015) Copy Citation Trials@uspto.gov Paper 58 571-272-7822 Entered: September 30, 2015 UNITED STATES PATENT AND TRADEMARK OFFICE ____________ BEFORE THE PATENT TRIAL AND APPEAL BOARD ____________ THE GILLETTE COMPANY, FUJITSU SEMICONDUCTOR LIMITED, FUJITSU SEMICONDUCTOR AMERICA, INC., ADVANCED MICRO DEVICES, INC., RENESAS ELECTRONICS CORPORATION, RENASAS ELECTRONICS AMERICA, INC., GLOBALFOUNDRIES U.S., INC., GLOBALFOUNDRIES DRESDEN MODULE ONE LLC & CO. KG, GLOBALFOUNDRIES DRESDEN MODULE TWO LLC & CO. KG, TOSHIBA AMERICA ELECTRONIC COMPONENTS, INC., TOSHIBA AMERICA INC., TOSHIBA AMERICA INFORMATION SYSTEMS, INC., and TOSHIBA CORPORATION, Petitioners, v. ZOND, LLC, Patent Owner. ____________ Case IPR2014-00799 1 Patent 7,808,184 B2 ____________ Before KEVIN F. TURNER, DEBRA K. STEPHENS, JONI Y. CHANG, SUSAN L. C. MITCHELL, and JENNIFER MEYER CHAGNON, Administrative Patent Judges. MITCHELL, Administrative Patent Judge. FINAL WRITTEN DECISION Inter Partes Review 1 Cases IPR2014-00855, IPR2014-00995, and IPR2014-01042 have been joined with the instant inter partes review. IPR2014-00799 Patent 7,808,184 B2 2 35 U.S.C. § 318(a) and 37 C.F.R. § 42.73 I. INTRODUCTION We have jurisdiction under 35 U.S.C. § 6(c). This Final Written Decision is entered pursuant to 35 U.S.C. § 318(a) and 37 C.F.R. § 42.73. For the reasons set forth below, we determine that Petitioners have shown, by a preponderance of the evidence, that claims 1–5 and 11–15 of U.S. Patent No. 7,808,184 B2 (Ex. 1001, “the ’184 patent”) are unpatentable under 35 U.S.C. § 103(a). A. Procedural History Taiwan Semiconductor Manufacturing Company, Ltd. and TSMC North America Corp. (collectively, “TSMC”) filed a Petition (Paper 1, “Pet.”) seeking inter partes review of claims 1–5 and 11–15 (“the challenged claims”) of the ’184 patent. TSMC included a Declaration of Mr. Richard DeVito (Ex. 1002) to support its positions. Patent Owner Zond, LLC (“Zond”) filed a Preliminary Response (Paper 7, “Prelim. Resp.”). Pursuant to 35 U.S.C. § 314(a), on October 1, 2014, we instituted an inter partes review of the challenged claims to determine if the claims are unpatentable under 35 U.S.C. § 103 as obvious over the combination of Wang and Kudryavtsev. Paper 10 (“Dec.”). Subsequent to institution, we granted revised Motions for Joinder filed by other Petitioners (collectively, “Gillette”) listed in the Caption above, joining Cases IPR2014-00855, IPR2014-00995, and IPR2014-01042 with the instant trial (Papers 17 and 18), and also granted a Joint Motion to Terminate with respect to TSMC (Paper 41). Zond filed a Patent Owner Response (Paper 34, “PO Resp.”), along with a Declaration of Larry D. IPR2014-00799 Patent 7,808,184 B2 3 Hartsough, Ph.D. (Ex. 2015) to support its positions. Gillette filed a Reply (Paper 46, “Reply”) to the Patent Owner Response, along with a supplemental Declaration of Dr. John Bravman (Ex. 1031). An oral hearing 2 was held on May 28, 2015. A transcript of the hearing is included in the record. Paper 57 (“Tr.”). B. Related Matters Gillette indicates that the ’184 patent was asserted against Petitioner, as well as other defendants, in seven district court lawsuits pending in the District of Massachusetts. Pet. 1. C. The ’184 Patent The ’184 patent relates to methods for generating strongly-ionized plasmas in a plasma generator. Ex. 1001, Abs. When creating a plasma in a chamber, a direct current (“DC”) electrical discharge, which is generated between two electrodes with a feed gas, generates electrons in the feed gas, that ionize atoms to create the plasma. Id. at 1:16–20. For an application, such as magnetron plasma sputtering, a relatively high level of energy must be supplied, which may result in overheating the electrodes or the work piece. Id. at 1:21–26. Such overheating may be addressed by complex cooling mechanisms, but such cooling can cause temperature gradients in the chamber causing a non-uniform plasma process. Id. at 1:26–30. These temperature gradients may be reduced by pulsing the DC power, but high-power pulses may result in arcing at plasma ignition and termination. 2 The oral arguments for the instant review and IPR2014-00477, IPR2014-00479, and IPR2014-00803 were consolidated. IPR2014-00799 Patent 7,808,184 B2 4 Id. at 1:31–36. Arcing is problematic because it can cause the release of undesirable particles in the chamber, thereby contaminating the work piece. Id. at 1:36–37, 4:8–11. According to the ’184 patent, a pulsed power supply may include circuitry that minimizes or eliminates the probability of arcing in the chamber by limiting the plasma discharge current to a certain level and dropping the generated voltage for a certain period of time if the limit is exceeded. Id. at 4:6–15. Figure 2, reproduced below, shows measured data of discharge voltage as a function of discharge current for admitted prior-art, low-current plasma 152, and high-current plasma 154 created by the claimed methods using the pulsed power supply. Id. at 1:58–60. Figure 2 shows current-voltage characteristic 154 that represents actual data for plasma generated by the pulsed power supply in the plasma IPR2014-00799 Patent 7,808,184 B2 5 sputtering system depicted in Figure 1 (not reproduced here). Id. at 5:28–30. The current-voltage characteristic 154 is in a high-current regime that generates a relatively high plasma density (greater than 10 12 –10 13 cm -3 ). Id. at 5:40–43. The pulsed power supply generates waveforms that create and sustain the high-density plasma with current-voltage characteristics in the high-current regime. Id. at 5:55–59. The ’184 patent explicitly defines the term “high-current regime” as “the range of plasma discharge currents that are greater than about 0.5 A/cm 2 for typical sputtering voltages of between about -300V to -1000V. Id. at 5:43–46. The power density is greater than about 250 W/cm 2 for plasmas in the high-current regime.” Id. at 5:43–48. The ’184 patent also describes a multi-stage ionization process wherein a multi-stage voltage pulse that is generated by the pulsed power supply creates a strongly-ionized plasma. See id. at 2:1–3, 7:4–7 (describing Figure 4 (not reproduced here) as such an example); id. at 14:50–15:46 (describing Figure 5C (not reproduced here) as an illustrative multi-stage voltage pulse). Such a multi-stage voltage pulse initially generates a weakly-ionized plasma in a low-current regime (shown as 152 in Figure 2 above), and then eventually generates a strongly-ionized or high-density plasma in a high-current regime. Id. at 7:10–13. “Weakly-ionized plasmas are generally plasmas having plasma densities that are less than about 10 12 – 10 13 cm -3 and strongly-ionized plasmas are generally plasmas having plasma densities that are greater than about 10 12 –10 13 cm -3 .” Id. at 7:14–18. IPR2014-00799 Patent 7,808,184 B2 6 D. Illustrative Claim Of the challenged claims, claims 1 and 11 are the only independent claims. Challenged claims 2 through 5 depend from claim 1, and challenged claims 12 through 15 depend from claim 11. Claim 1, reproduced below, is illustrative: 1. A method of generating a strongly-ionized plasma, the method comprising: a) supplying feed gas proximate to an anode and a cathode assembly; and b) generating a voltage pulse between the anode and the cathode assembly, the voltage pulse having at least one of a controlled amplitude and a controlled rise time that increases an ionization rate so that a rapid increase in electron density and a formation of a strongly-ionized plasma occurs without forming an arc between the anode and the cathode assembly. Ex. 1001, 22:44–54 (emphasis added). E. Prior Art Relied Upon Gillette relies upon the following prior art references: Wang US 6,413,382 B1 July 2, 2002 (Ex. 1005) D.V. Mozgrin, et al., High-Current Low-Pressure Quasi-Stationary Discharge in a Magnetic Field: Experimental Research, 21 PLASMA PHYSICS REPORTS 400–409 (1995) (Ex. 1003) (“Mozgrin”). A. A. Kudryavtsev and V.N. Skrebov, Ionization Relaxation in a Plasma Produced by a Pulsed Inert-Gas Discharge, 28(1) SOV. PHYS. TECH. PHYS. 30–35 (Jan. 1983) (Ex. 1004) (“Kudryavtsev”). D.V. Mozgrin, High-Current Low-Pressure Quasi-Stationary Discharge in a Magnetic Field: Experimental Research, Thesis at IPR2014-00799 Patent 7,808,184 B2 7 Moscow Engineering Physics Institute (1994) (Ex. 1007) (“Mozgrin Thesis”). 3 F. Ground of Unpatentability We instituted the instant trial based on the following ground of unpatentability (Dec. 28): Claims Basis References 1–5 and 11–15 § 103(a) Wang and Kudryavtsev II. ANALYSIS A. Claim Construction In an inter partes review, claim terms in an unexpired patent are given their broadest reasonable construction in light of the specification of the patent in which they appear. 37 C.F.R. § 42.100(b); see also In re Cuozzo Speed Techs., LLC, 793 F.3d 1268, 1279 (Fed. Cir. 2015) (“Congress implicitly approved the broadest reasonable interpretation standard in enacting the AIA,” 4 and “the standard was properly adopted by PTO regulation.”). Significantly, claims are not interpreted in a vacuum but are part of, and read in light of, the specification. United States v. Adams, 383 U.S. 39, 49 (1966) (“[I]t is fundamental that claims are to be construed in the light of the specifications and both are to be read with a view to 3 The Mozgrin Thesis is a Russian-language reference. TSMC provided a certified English-language translation (Ex. 1006). 4 The Leahy-Smith America Invents Act, Pub. L. No. 11229, 125 Stat. 284 (2011) (“AIA”). IPR2014-00799 Patent 7,808,184 B2 8 ascertaining the invention . . . .”). Claim terms are given their ordinary and customary meaning as would be understood by one of ordinary skill in the art in the context of the entire disclosure. In re Translogic Tech., Inc., 504 F.3d 1249, 1257 (Fed. Cir. 2007). An inventor may rebut that presumption by providing a definition of the term in the specification with reasonable clarity, deliberateness, and precision. In re Paulsen, 30 F.3d 1475, 1480 (Fed. Cir. 1994). In the absence of such a definition, limitations are not to be read from the specification into the claims. In re Van Geuns, 988 F.2d 1181, 1184 (Fed. Cir. 1993). 1. “weakly-ionized plasma” and “strongly-ionized plasma” Both independent claims 1 and 11 recite “formation of a strongly-ionized plasma.” Challenged dependent claims 4 and 14 each requires creating a “weakly-ionized plasma” before creating a “strongly- ionized plasma.” Ex. 1001, 22:59–65, 24:3–9. Prior to institution, Zond and Gillette submitted constructions of the terms “weakly-ionized plasma” and “strongly-ionized plasma.” Prelim. Resp. 11–12; Pet. 13–15. In the Decision on Institution, we adopted Zond’s proposed constructions, in light of the Specification, as the broadest reasonable interpretation. Dec. 9–11; Ex. 1001, 7:14–18. We construed the claim term “weakly-ionized plasma” as “a plasma with a relatively low peak density of ions,” and the claim term “strongly-ionized plasma” as “a plasma with a relatively high peak density of ions.” Dec. 11. Subsequent to institution, notwithstanding that neither Zond, nor its expert witness, expressly challenged our claim construction as to this term IPR2014-00799 Patent 7,808,184 B2 9 (PO Resp. 15–24; Ex. 2015 ¶ 21), Zond improperly attempts to import extraneous limitations into the claim by arguing that the measure of the peak density of ions is necessary to determine whether a strongly-ionized plasma is formed. See PO Resp. 3–4, 45. It is well settled that if a feature is not necessary to give meaning to a claim term, it is “extraneous” and should not be read into the claim. Renishaw PLC v. Marposs Societa’ per Azioni, 158 F.3d 1243, 1249 (Fed. Cir. 1998); E.I. du Pont de Nemours & Co. v. Phillips Petroleum Co., 849 F.2d 1430, 1433 (Fed. Cir. 1988). We observe that the claim terms “weakly-ionized plasma” and “strongly-ionized plasma” are relative terms. The cross-examination testimony of Gillette’s declarant, Mr. DeVito, in which he discusses our construction, confirms that Mr. DeVito agrees the terms are relative (Ex. 2014, 166:21–24) and that three to four orders of magnitude difference in the peak density of ions between the initial ionized state and a plasma density that may be considered strongly-ionized is sufficient (id. at 166:25– 170:25). Gillette’s second declarant, Dr. John C. Bravman, also confirms that weakly-ionized and strongly-ionized plasma are relative terms, as the ’184 patent uses overlapping ranges of plasma density to describe them (see Ex. 1031 ¶¶ 31–32 (citing Ex. 1001, 7:14–18)), and that one of ordinary skill in the art would not understand strongly-ionized plasma to require any specific magnitude in the peak density of ions. Id. ¶ 30. Dr. Bravman also notes that strongly-ionized plasma is the same as high-density plasma. Id. ¶ 33 (citing Ex. 1001, 7:11–14). For the foregoing reasons, we decline to adopt Zond’s assertion that the measure of the peak density of ions is necessary to determine whether a IPR2014-00799 Patent 7,808,184 B2 10 strongly-ionized plasma is formed. Rather, upon review of the parties’ explanations and supporting evidence before us, we discern no reason to modify our claim constructions set forth in the Decision on Institution with respect to this claim term, which adopted Zond’s originally proposed construction. Dec. 9–11. Therefore, for purposes of this Final Written Decision, we construe, in light of the Specification, the claim term “weakly-ionized plasma” as “a plasma with a relatively low peak density of ions,” and the claim term “a strongly-ionized plasma” as “a plasma with a relatively high peak density of ions.” 2. “a voltage pulse having at least one of a controlled amplitude and a controlled rise time” Independent claims 1 and 11 recite the feature of “generating a voltage pulse . . . having at least one of a controlled amplitude and a controlled rise time” to achieve increasing an ionization rate so that a rapid increase in electron density and a formation of a strongly-ionized plasma occurs without forming an arc between the anode and the cathode assembly. 5 During the pretrial stage of this proceeding, Gillette did not proffer an explicit construction for this feature (see Pet. 12–13), but Zond offered a construction, focusing on the meaning of the term “control.” Prelim. Resp. 13. In our Decision on Institution, we adopted Zond’s proposed construction, in light of the ’184 patent Specification, as the broadest 5 Claim 11 adds that such amplitude or controlled rise time of the voltage pulse “shifts an electron energy distribution in the plasma to higher energies” to achieve the increased ionization rate. See Ex. 1001, 23:21–28. IPR2014-00799 Patent 7,808,184 B2 11 reasonable interpretation, which is “generating a voltage pulse whose amplitude and/or rise time are directed or restrained” to achieve the increased ionization rate for a rapid increase in electron density and a formation of a strongly-ionized plasma without arcing. Dec. 11–12; see, e.g., Ex. 1001, 6:8–9 (stating the pulsed power supply “can be programmed to generate voltage pulses having various shapes”); id. at 8:41–60 (referring to Fig. 4, describing specific, relatively fast rise time of the voltage shifts the electron energy distribution to higher energies for formation of the strongly-ionized plasma). Subsequent to institution, Zond seeks a further clarification of our construction in light of our application of our construction to the prior art. PO Resp. 15–18. 6 Zond takes issue with our claim construction as not encompassing the broadest reasonable interpretation. Id. at 18. Zond asserts 6 Zond contends that our use of Figure 3 of the ’184 patent in the Decision on Institution to show control of a voltage pulse is misplaced because Figure 3 shows only weakly-ionized plasma. PO Resp. 15–18. We relied on the description of Figure 3 to illustrate the difference between a desired or idealized square pulse and an actual voltage pulse that shows oscillations. Dec. 22–23. As Gillette acknowledges, both Figure 3 and Figure 8 of the ’184 patent, which Zond asserts describes “the compelling advantages of combining voltage amplitude control with voltage rise time control,” PO Resp. 14, show an idealized square pulse showing a target voltage level versus the actual output voltage amplitude and rise time showing numerous fluctuations. See Ex. 1001, Figs. 3, 8; Reply 5–7. The difference in the attainment of a strongly-ionized plasma in Figure 8 is explained not by how the voltage pulse was “controlled,” but by use of the high-power voltage mode that “supplies a sufficient amount of uninterrupted power” to drive the plasma to a strongly-ionized state. Ex. 1001, 13:52–57, 18:64–66; Reply 6– 7. IPR2014-00799 Patent 7,808,184 B2 12 that we “concluded that the claimed pulse control encompasses any change in voltage amplitude that is incidental to directing a pulse to a target power level (or set point) as in Wang, regardless of whether the voltage amplitude is the parameter under control.” Id. Zond asserts that Mr. DeVito agrees that this limitation requires a target voltage level or set point. Id. at 19 (citing Ex. 2014, 173:14–174:20). Zond also utilizes the Eronini 7 reference to explain how a desired value or “set point,” also known as a “controlled variable,” is achieved in a closed loop system using a feedback signal to control the manipulated variable, here the voltage pulse. PO Resp. 19–20. Zond concludes that: [T]he proper interpretation of the claim language—“voltage pulse having at least one of a controlled amplitude and a controlled rise time”—requires controlling these voltage parameters to target levels or set points as shown in the specification, and not to any uncontrolled variation or manipulation that may occur incidental to controlling a different parameter, such as power. In other words, any variations or manipulations in voltage that may occur as a supply controls power to a target level do not equate with a control of voltage. Id. at 21. Zond points to Figure 5C of the ’184 patent as exemplary of a power supply programmed to direct the voltage amplitude to successive target levels or set points 306, 370, 380. Id. at 22 (citing Ex. 1001, 11:55– 61). Zond concludes that “[t]his example shows that the specification describes a power supply that achieves the claimed conditions (of a rapid increase in electron density without arc) by controlling the voltage amplitude 7 Eronini Umez-Eronini, SYSTEM DYNAMICS AND CONTROL 10–13 (1999) (EX. 2021). IPR2014-00799 Patent 7,808,184 B2 13 and rise times to target levels.” Id. at 24. Therefore, according to Zond, “generating a voltage pulse . . . having at least one of a controlled amplitude and a controlled rise time that increases an ionization rate so that a rapid increase in electron density and a formation of a strongly ionized plasma occurs without forming an arc” should be construed as “generating a voltage pulse whose amplitude and/or rise time are controlled variables that are directed or restrained to a target voltage level and/or a rise time level to increase an ionization rate so that a rapid increase in electron density and a formation of a strongly ionized plasma occurs without forming an arc.” Id. at 22. Gillette counters that Zond’s newly proposed construction is unsupported by the Specification of the ’184 patent. Reply 1. For instance, Gillette asserts that the ’184 patent teaches that “the actual output voltage amplitude and rise time . . . is not ‘directed or restrained’ to the target value because there are numerous fluctuations that exceed and/or undershoot the target voltage level, and a lag in rise time is observed as compared to the target value.” Reply 6. We agree with Gillette and decline to adopt Zond’s newly proposed construction. Dr. Bravman testifies that Figure 5C of the ’184 patent, which is annotated by Dr. Bravman as shown below, shows a difference between a desired voltage pulse (annotated in red) and an actual voltage pulse (annotated in green). The ’184 patent states with respect to Fig. 5A–5C: “The desired pulse shapes requested from the pulsed power supply 102 are superimposed in dotted lines 304, 304’, and 304” onto each of the respective multi-stage voltage pulses 302, 302’, and 302”. IPR2014-00799 Patent 7,808,184 B2 14 Ex. 1031 ¶ 38. We also agree that for every figure in the ’184 patent that shows the target and actual voltage pulses, such as Figure 8, which Zond asserts “demonstrates the compelling advantages of combining voltage amplitude control with voltage rise time control” (PO Resp. 14), the actually generated voltage pulse deviates significantly from the desired target voltage pulse. See Ex. 1031 ¶¶ 37–39. Therefore, based on the Specification of the ’184 patent, we agree with Dr. Bravman that “control as construed using the broadest reasonable interpretation includes direction and restraint of a voltage pulse’s amplitude and rise time that do or do not exactly follow the target voltage amplitude and/or rise time.” Id. ¶ 40. We thus continue to construe the claim phrase “generating a voltage pulse having at least one of a controlled amplitude and a controlled rise time” as “generating a voltage pulse whose amplitude and/or rise time are IPR2014-00799 Patent 7,808,184 B2 15 directed or restrained” to achieve the increased ionization rate for a rapid increase in electron density and a formation of a strongly-ionized plasma without arcing. 3. “without forming an arc” Neither party offers an explicit construction of the claim phrase “without forming an arc,” but we discern that Zond’s arguments are based on an incorrect interpretation of this claim phrase. Therefore, we construe the claim phrase “without forming an arc.” Specifically, Zond asserts that a key claim limitation missing from the teachings of the prior art, is the absence of arcing in the transition from a weakly-ionized plasma to a highly-ionized plasma. PO Resp. 4. Zond describes Figure 4 as set forth in the ’184 patent as showing no arcing, as evidenced by the relatively steep continuous rise in current to achieve “controlled rapid growth to a strongly-ionized plasma without arcing.” Id. at 8, 10 (“By carefully controlling the target pulse voltage amplitude and voltage rise times at selected moments and by selected amounts, the system increases the electron density to quickly transition a plasma to a strongly- ionized condition, while still restraining the plasma from arcing.”); id. at 11– 12 (stating Figs. 5A–5C show rapidly achieving a strongly-ionized plasma without arcing). Finally, Zond identifies Figure 8 of the ’184 patent as evidencing a single-stage voltage pulse that ignites and grows a plasma to high density without arcing. Zond concludes that: IPR2014-00799 Patent 7,808,184 B2 16 Thus, this example demonstrates that compelling advantages of combining voltage amplitude control with voltage rise time control: Dr. Chistyakov was able to find a controlled voltage level coupled with a controlled rise time for his programmable supply that could both ignite a plasma and stably grow it into a plasma that was dense enough for sputtering, but without arcing. PO Resp. 14. The Specification of the ’184 patent contains only a few references to arcing. For instance, the Specification of the ’184 patent, in describing Figure 1, which illustrates a cross-sectional view of a plasma sputtering apparatus having a pulsed direct current (DC) power supply according to one embodiment of the invention, discloses the following: The pulsed power supply 102 can include circuitry that minimizes or eliminates the probability of arcing in the chamber 104. Arcing is generally undesirable because it can damage the anode 124 and cathode assembly 116 and can contaminate the wafer or work piece being processed. In one embodiment, the circuitry of the pulse supply 102 limits the plasma discharge current up to a certain level, and if this limit is exceeded, the voltage generated by the power supply 102 drops for a certain period of time. Ex. 1001, 4:6–15 (emphasis added). In describing Figure 2, the Specification of the ’184 patent states that “[s]puttering with discharge voltages greater than –800V can be undesirable because such high voltages can increase the probability of arcing and can tend to create sputtered films having relatively poor film quality.” Id. at 5:23–27. The Specification of the ’184 patent also describes other ways to reduce arcing. For instance, ’184 patent discusses Figure 9, which depicts a IPR2014-00799 Patent 7,808,184 B2 17 plasma sputtering apparatus according to the invention and describes the gap between the anode and the cathode assembly. See Ex. 1001, 19:4–7. The Specification of the ’184 patent states that “[t]he gap 514 can reduce the probability that an electrical breakdown condition (i.e., arcing) will develop in the chamber 104.” Id. at 19:34–36, 20:40–41 (“The geometry of the gap 514 can be chosen to minimize the probability of arcing . . . .”). Zond does not explain adequately why one with ordinary skill in the plasma art would have interpreted the claim term “without forming an arc,” in light of the Specification, to require the ionization of excited atoms be performed completely free of arcing. See Tr. 22–29; In re NTP, Inc., 654 F.3d 1279, 1288 (Fed. Cir. 2011) (stating that the Board’s claim construction “cannot be divorced from the specification and the record evidence”); see also In re Cortright, 165 F.3d 1353, 1358 (Fed. Cir. 1999) (stating that the Board’s claim construction “must be consistent with the one that those skilled in the art would reach”). Nor does Zond direct our attention to credible evidence that would support its attorney’s arguments regarding the disputed claim term at issue. See PO Resp. 2–4, 7–14. Here, nothing in the Specification indicates that no arcing occurs in the formation of the strongly-ionized plasma. Rather, the Specification explicitly states that such a probability may be minimized or eliminated. Ex. 1001, 4:6–8. Given the disclosure in the Specification, we decline to adopt Zond’s implicit construction—absolutely no arcing—because it would be unreasonable to exclude the disclosed embodiments. See Phillips v. AWH Corp., 415 F.3d 1303, 1315 (Fed. Cir. 2005) (en banc) (stating that the Specification is “the single best guide to the meaning of a disputed term”). IPR2014-00799 Patent 7,808,184 B2 18 Instead, we construe the claim term “without forming an arc” as “substantially eliminating the possibility of arcing,” consistent with an interpretation that one of ordinary skill in the art would reach when reading the claim term in the context of the Specification. Finally, although Zond acknowledges that “Wang’s teachings of a ‘reduction’ in arcing upon ignition are inapposite to the ’184 patent’s requirement of avoiding arcing during the rapid increase in electron density and a formation of the strongly-ionized plasma” (id. at 2), Zond faults Wang’s alleged teaching that arcing was unavoidable upon plasma ignition (id. at 14). Zond is attempting to import improperly a limitation not in the claims. Independent claims 1 and 11 require formation of a strongly-ionized plasma without an arc, but do not require that the ignition or the formation of a weakly-ionized plasma occur without an arc. See Ex. 1001, 22:52–54, 23:6–8; Renishaw, 158 F.3d at 1249; E.I. du Pont de Nemours, 849 F.2d at 1433. B. Principles of Law A patent claim is unpatentable under 35 U.S.C. § 103(a) if the differences between the claimed subject matter and the prior art are such that the subject matter, as a whole, would have been obvious at the time the invention was made to a person having ordinary skill in the art to which said subject matter pertains. KSR Int’l Co. v. Teleflex Inc., 550 U.S. 398, 406 (2007). The question of obviousness is resolved on the basis of underlying factual determinations including: (1) the scope and content of the prior art; (2) any differences between the claimed subject matter and the prior art; IPR2014-00799 Patent 7,808,184 B2 19 (3) the level of ordinary skill in the art; and (4) objective evidence of nonobviousness. Graham v. John Deere Co., 383 U.S. 1, 17–18 (1966). In that regard, an obviousness analysis “need not seek out precise teachings directed to the specific subject matter of the challenged claim, for a court can take account of the inferences and creative steps that a person of ordinary skill in the art would employ.” KSR, 550 U.S. at 418; see Translogic, 504 F.3d at 1259. The level of ordinary skill in the art may be reflected by the prior art of record. See Okajima v. Bourdeau, 261 F.3d 1350, 1355 (Fed. Cir. 2001); In re GPAC Inc., 57 F.3d 1573, 1579 (Fed. Cir. 1995); In re Oelrich, 579 F.2d 86, 91 (CCPA 1978). We analyze the asserted grounds of unpatentability in accordance with the above-stated principles. C. Claims 1–5 and 11–15 — Obviousness over Wang and Kudryavtsev Gillette asserts that claims 1–5 and 11–15 are unpatentable under 35 U.S.C. § 103(a) as obvious over the combination of Wang and Kudryavtsev. Pet. 43–60. As support, Gillette provides detailed explanations as to how each claim limitation is met by the references and rationales for combining the references (id.), as well as a Declaration of Mr. Richard DeVito (Ex. 1002) in support of its Petition, and a Declaration of Dr. John C. Bravman (Ex. 1031) in support of its Reply. Zond responds that the combination of Wang and Kudryavtsev does not disclose every claim element. PO Resp. 25–50, 54–60. Zond also argues that there is insufficient reason to combine the technical disclosures of Wang and Kudryavtsev. Id. at 50–52. To support its contentions, Zond IPR2014-00799 Patent 7,808,184 B2 20 proffers a Declaration of Dr. Larry D. Hartsough (Ex. 2015). Zond also asserts that secondary considerations mitigate against a determination of obviousness, but does not provide support for this contention from its declarant. PO Resp. 53–54. We have reviewed the entire record before us, including the parties’ explanations and supporting evidence presented during this trial. We begin our discussion with a brief summary of Wang and Kudryavtsev, and then we address the parties’ contentions in turn. Wang Wang discloses a power pulsed magnetron sputtering apparatus for generating a very high plasma density. Ex. 1005, Abs. Wang also discloses a sputtering method for depositing metal layers onto advanced semiconductor integrated circuit structures. Id. at 1:4–15. IPR2014-00799 Patent 7,808,184 B2 21 Figure 1 of Wang, reproduced below, illustrates a cross-sectional view of a power pulsed magnetron sputtering reactor: As shown in Figure 1 of Wang, magnetron sputtering apparatus 10 has pedestal 18 for supporting semiconductor substrate 20, anode 24, cathode 14, magnet assembly 40, and pulsed DC power supply 80. Id. at 3:57–4:55, 4:35–36. According to Wang, the apparatus is capable of creating high density plasma in region 42, which ionizes a substantial fraction of the sputtered particles into positively charged metal ions and also increases the sputtering rate. Id. at 4:13–34. Wang further recognizes that, if a large portion of the sputtered particles are ionized, the films are deposited more uniformly and effectively—the sputtered ions can be accelerated towards a negatively charged substrate, coating the bottom and sides of holes that are narrow and deep. Id. at 1:24–29. IPR2014-00799 Patent 7,808,184 B2 22 Figure 6 of Wang, reproduced below, illustrates how the apparatus applies a pulsed power to the plasma: As shown in Figure 6 of Wang, the target is maintained at background power level PB between high power pulses 96 with peak power level PP. Id. at 7:13–39. Background power level PB exceeds the minimum power necessary to support a plasma in the chamber at the operational pressure (e.g., 1kW). Id. Peak power PP is at least 10 times (preferably 100 or 1000 times) background power level PB. Id. The application of high peak power PP causes the existing plasma to spread quickly and increases the density of the plasma. Id. According to Mr. DeVito, Wang’s apparatus generates a low-density (weakly-ionized) plasma during the application of background power PB, and a high-density plasma during the application of peak power PP. Ex. 1002 ¶¶ 116, 123; see Pet. 42–43, 45–46. Kudryavtsev Kudryavtsev discloses a multi-step ionization plasma process, comprising the steps of exciting the ground state atoms to generate excited atoms and then ionizing the excited atoms. Ex. 1004, Abs., Figs. 1, 6. IPR2014-00799 Patent 7,808,184 B2 23 Figure 1 of Kudryavtsev illustrates the atomic energy levels during the slow and fast stages of ionization. Figure 1 of Kudryavtsev is reproduced below: As shown in Figure 1 of Kudryavtsev, ionization occurs with a “slow stage” (Fig. 1a) followed by a “fast stage” (Fig. 1b). During the initial slow stage, direct ionization provides a significant contribution to the generation of plasma ions (arrow Γ1e showing ionization (top line labeled “e”) from the ground state (bottom line labeled “1”)). Mr. DeVito explains that Kudryavtsev pre-ionized a gas and then applied a voltage pulse. Ex. 1002 ¶ 125; Pet. 46. Under these conditions, Kudryavtsev discloses: an explosive increase in ne [plasma density]. The subsequent increase in ne then reaches its maximum value, equal to the rate of excitation . . . which is several orders of magnitude greater than the ionization rate during the initial stage. Ex. 1002 ¶ 125 (quoting Ex. 1004, 31). Kudryavtsev also recognizes that “in a pulsed inert-gas discharge plasma at moderate pressures . . . [i]t is shown that the electron density increases explosively in time due to accumulation of atoms in the lowest excited states.” Ex. 1004, 30, Abs., Fig. 6. IPR2014-00799 Patent 7,808,184 B2 24 Voltage Pulse Having a Controlled Amplitude or Rise Time Gillette relies upon Wang to disclose the limitations recited in claims 1–5 and 11–15 (Pet. 12–29; Ex. 1005 ¶¶ 103–136), and further relies on Kudryavtsev to provide additional support for teaching “the pulsed power supply generating at the output a voltage pulse having at least one of a controlled amplitude and a controlled rise time that increases an ionization rate of sputtered material atoms so that a rapid increase in electron density and a formation of a strongly-ionized plasma occurs.” Pet. 45–49. Gillette asserts: Like Wang, Kudryavtsev pre-ionizes a gas and applies a voltage pulse. . . . Under these conditions, Kudryavtsev observed a fast stage, corresponding to “an explosive increase in ne [plasma density]. The subsequent increase in ne then reaches its maximum value, equal to the rate of excitation . . . which is several orders of magnitude greater than the ionization rate during the initial stage.” Id. at 46 (citations omitted). Citing to Mr. DeVito’s testimony, Gillette asserts that if such an “explosive increase” in density in Wang is not experienced, it would have been obvious to adjust the operating parameters like pulse length or pressure to trigger Kudryavtsev’s fast stage of ionization. Id. at 47 (citing Ex. 1002 ¶ 126). Gillette concludes that: One of ordinary skill would have been motivated to use Kudryavtsev’s fast stage of ionization in Wang so as to increase plasma density and thereby increase the sputtering rate. Also, Kudryavtsev’s fast stage would reduce the time required to reach a given plasma density in Wang. Further, use of Kudryavtsev’s fast stage in Wang would have been a combination of old elements that yielded the predictable results of rapidly increasing the ionization rate and electron density. IPR2014-00799 Patent 7,808,184 B2 25 Finally, because Wang’s pulse, or the pulse used in the combination of Wang and Kudryavtsev, produced Kudryavtsev’s fast stage of ionization, the rise time and amplitude of the pulse result in increasing the ionization rate so that a rapid increase in electron density and formation of a strongly-ionized plasma occurs. Id. at 47–48 (citing Ex. 1002 ¶ 126). Zond argues that neither Wang nor Kudryavtsev teaches the claimed voltage control or the avoidance of arcing during the rapid increase in electron density and formation of a strongly-ionized plasma. PO Resp. 25– 50. For instance, citing Dr. Hartsough’s testimony in support, Zond asserts that: Wang is not controlling voltage rise time so as to achieve the claimed objectives, and he never suggests controlling rise time of either voltage or of power: He is controlling power level only to obtain as fast a rise time in power as he can, and the actual rise time of power that results is an uncontrolled variation that occurs incidental to his attempt to control power to a constant target level. PO Resp. 42; Ex. 2015 ¶¶ 103–104, 114–116. In its Reply, Gillette asserts that Zond concedes that all the limitations in claim 1 are met by the prior art except for control of voltage amplitude or rise time to avoid arcing when rapidly forming a strongly-ionized plasma. Reply 2 (citing PO Resp. 25). Gillette points to Dr. Hartsough’s testimony admitting that Figure 10 in the ’184 patent shows a prior art power supply that can generate voltage pulses according to the invention described in the ’184 patent. Id. at 3 (“Again, Dr. Chistyakov says that these pulses are according to the present invention, and – so I will use my understanding of IPR2014-00799 Patent 7,808,184 B2 26 what he said there, since a controlled rise time is part of his present invention, that these power supplies could do that.”) (quoting Ex. 1029, 84:25–86:23). We start our analysis with where the parties appear to agree on what the prior art teaches. For instance, referring to Figure 1 of Wang set forth above, Wang teaches supplying a feed gas proximate to processing region 22, which is defined by the anode and cathode assembly, and pulsed DC power supply 80 that generates a train of voltage pulses between the anode and cathode assembly. Pet. 44–46; Ex. 1002 ¶¶ 117–122 (citing Ex. 1005, Figs. 1, 6, and 7, 3:66–4:1, 4:5–8, 4:20–21, 7:61–62). We find Zond’s contention that Wang is directed to power pulses throughout its disclosure, rather than a voltage pulse, is misplaced and contrary to the pertinent evidence of record. See PO Resp. 2, 26–32, 40–45. As Gillette indicates in its Petition, Wang discloses a pulsed DC power supply connected to the target that produces “a train of negative voltage pulses.” Pet. 44 (citing Ex. 1005, 7:61–62 (emphasis added), Fig. 7). Mr. DeVito explains that “[t]hose voltage pulses create Wang’s peak power pulses, PP, which are applied to Wang’s weakly-ionized plasma, i.e., the plasma generated by the background power PB. . . . Because Wang’s anode is grounded, when one of Wang’s voltage pulses is applied to the cathode/target 14, a voltage pulse is generated between the anode and the cathode assembly.” Ex. 1002 ¶¶ 120–122; see Pet. 44–45. Also, Dr. Bravman explains that “[g]enerally, a pulsed power supply outputs a voltage pulse. The current responds to the applied voltage pulse, depending on the impedance of the load, leading to an increase in the current IPR2014-00799 Patent 7,808,184 B2 27 and concomitant lowering of the voltage.” Ex. 1031 ¶ 53. Therefore, to generate a power pulse, a power supply first provides a voltage pulse with a specific amplitude and rise time. Id. ¶ 54. Dr. Bravman demonstrates how Wang shows such behavior by noting Wang’s teaching that a typical “pulsed power supply will output relative high voltage and almost no current in the ignition phase and a lower voltage and substantial current in the maintenance phase.” Id. ¶ 55 (quoting Ex. 1005, 5:32–35). Dr. Bravman points to Dr. Hartsough’s testimony that Figure 5 of U.S. Patent No. 6,896,775 (“the ’775 patent”) assigned to Zond, illustrates a typical power supply also as described in Wang. Id. ¶ 56 (citing Ex. 1028, 149:22–150:20). Dr. Bravman testifies that, in his opinion, Figure 5 of the ’775 patent behaves in a nearly identical manner as Figure 8 of the ’184 patent, reproduced below with annotations by Dr. Bravman. Id. ¶ 57. IPR2014-00799 Patent 7,808,184 B2 28 Id. ¶ 58. Dr. Bravman explains that “[i]n both cases, when the voltage pulse is initially applied (red region), voltage (green) is initially higher with low current (purple). Then, when the strongly-[ionized] plasma is generated (blue region), the voltage (green) becomes lower with the corresponding rise in current (purple).” Id. We credit Dr. Bravman’s testimony, which is consistent with the Specification of the ’184 patent and the prior art as set forth above, in addition to Dr. Hartsough’s statements concerning the similarity of Figure 5 of the ’775 patent to the teachings in Wang. Based on the evidence before us, we are persuaded that Gillette has demonstrated, by a preponderance of evidence, that the combination of Wang and Kudryavtsev discloses a voltage pulse having at least one of a controlled amplitude and a controlled rise time that increases an ionization rate so that a rapid increase in electron density and a formation of a strongly- ionized plasma occurs. Without Forming an Arc Between the Anode and Cathode Assembly Zond also asserts Wang fails to teach a critical claim limitation of a lack of arcing during the formation of a strongly-ionized plasma through control of pulse voltage. See PO Resp. 30–32. Zond argues that, because Wang admits arcing occurs upon plasma ignition with the discussed power control technique and that Figure 6 of Wang demonstrates use of a background power so arcing would be significantly reduced, but not eliminated, Wang does not teach the “lack of arcing” limitation. Id. at 30– 31. This particular argument of Zond is not persuasive because, as we have stated in our claim construction, given the disclosure in the Specification, we IPR2014-00799 Patent 7,808,184 B2 29 decline to construe the claims to require the transformation of the weakly- ionized plasma to a strongly-ionized plasma occur with a guarantee of eliminating all possibility of an electrical breakdown condition or arcing, because it would be unreasonable to exclude the disclosed embodiments, all of which stop short of such a guarantee. See Phillips, 415 F.3d at 1315 (stating that the Specification is “the single best guide to the meaning of a disputed term”). Zond also argues that Kudryavtsev’s teaching of an “explosive” build–up of electron density would transition into an arc as evidenced by the resultant measured voltage and current waveforms shown in Figure 2 of Kudryavtsev. PO Resp. 33–40 (citing Ex. 2015 ¶¶ 121–131, 134). Therefore, according to Zond, Kudryavtsev does not teach “that the applied voltage amplitude or voltage rise time were controlled in the manner claimed to achieve a rapid increase in electron density without arcing.” Id. at 46. Gillette counters that Wang teaches the avoidance of arcing because the impedance changes relatively little between the two power levels PB and PP indicating no arcing, which Gillette asserts Dr. Hartsough admits. Reply 2–3 (citing Ex. 1005, 7:49–51; Ex. 1028, 89:8–24). Gillette also disagrees that Kudryavtsev causes an arc condition. See Ex. 1031 ¶¶ 65–66. A preponderance of the evidence before us supports Gillette’s position that the combination of Wang and Kudryavtsev discloses the claim feature. See Pet. 49–50 (citing Ex. 1002 ¶¶ 131–132). As Gillette notes, Wang explains that arcing may occur during plasma ignition before the first pulse shown in Figure 6. Id. at 49 (citing Ex. 1005, 7:3–6). Indeed, Wang recognizes that plasma ignition in a sputtering reactor has a tendency to IPR2014-00799 Patent 7,808,184 B2 30 generate arcing, dislodging large particles from the target or chamber. Ex. 1005, 7:3–8. This is because plasma ignition is an electronically noisy process, and each power pulse would need to ignite the plasma (as illustrated in Figure 4 of Wang) if background power level PB is not maintained between the high power pulses. Id. at 7:8–12. Figure 6 of Wang (reproduced previously in our initial discussion of Wang) is reproduced again below: As shown in Figure 6 of Wang, the target is maintained at background power level PB between power pulses 96, rising to peak level PP. Ex. 1005, 7:13–25. Background level PB is chosen to exceed the minimum power necessary to support a plasma with little, if any, actual sputter deposition. Id. The initial plasma ignition needs to be performed only once, and at a very low power level, so that particulates produced by arcing are much reduced. Id. at 7:26–55. According to Mr. DeVito, because “the plasma need not be reignited thereafter, arcing will not occur during subsequent applications of the background and peak power levels, PB and PP.” Ex. 1002 ¶ 132. IPR2014-00799 Patent 7,808,184 B2 31 We agree with Gillette that Wang teaches the avoidance of arcing (as Dr. Hartsough admits), and, in contrast to Zond’s assertions, we further agree with Gillette that Kudryavtsev does not teach that arcing must occur. See Ex. 1004, 34 (discussing uniformity of ionization across cross section of discharge tube). Based on the evidence before us, we are persuaded Gillette has demonstrated, by a preponderance of evidence, that the combination of Wang and Kudryavtsev discloses a voltage pulse having at least one of a controlled amplitude and a controlled rise time that increases an ionization rate of sputtered material atoms so a rapid increase in electron density and a formation of a strongly-ionized plasma occurs without forming an arc between the anode and the cathode assembly. Rationale to Combine Wang and Kudryavtsev Finally, Zond points to the physical differences between Kudryavtsev’s and Wang’s systems, concluding “[c]ombining the teachings of Kudryavtsev’s flash tube with no magnet with Wang’s pulsed magnetron sputter reactor would not have lead one of ordinary skill in the art to an expected result.” PO Resp. 50–51. For instance, Zond asserts that Kudryavtsev’s system does not use magnets or magnetic fields, in contrast to Wang’s magnetron; Wang’s and Kudryavtsev’s reactors have very different dimensions; and the location of the application of the voltage pulse in Kudryavtsev’s system is substantially different from Wang’s. Id. at 51–52. 8 8 Zond also attempts to argue secondary considerations. PO Resp. 53–54. Zond’s arguments, however, are unsupported attorney argument to which we give little weight. See Meitzner v. Mindick, 549 F.2d 775, 782 (CCPA 1977) IPR2014-00799 Patent 7,808,184 B2 32 Gillette supports its conclusion that one of ordinary skill in the art would have been motivated to use Kudryavtsev’s explosive ionization in Wang to increase plasma density, concomitantly increasing the sputtering rate, with testimony from each of Mr. DeVito and Dr. Bravman. Reply 10 (citing Ex. 1002 ¶¶ 126–130; Ex. 1031 ¶¶ 67–68; Pet. 47–49). Gillette concludes that “[a]s Dr. Bravman explains, a person of ordinary skill in the art would have combined the teachings of Wang with Kudryavtsev, despite the physical differences that may exist, just as Mozgrin had done in applying Kudryavtsev in designing his magnetron sputtering system.” Reply 12 (citing Ex. 1031 ¶ 69). Upon consideration of the evidence before us, we are persuaded by Gillette’s contentions. Gillette merely relies upon Kudryavtsev’s teaching that an “explosive increase” in plasma density is achieved by applying a voltage pulse to a weakly-ionized plasma. Pet. 46–47. Zond’s arguments concerning the differences between Wang’s and Kudryavtsev’s systems are not persuasive. “It is well-established that a determination of obviousness based on teachings from multiple references does not require an actual, physical substitution of elements.” In re Mouttet, 686 F.3d 1322, 1332 (Fed. (finding argument of counsel cannot take the place of evidence lacking in the record); see also PO Resp. 54 n.108 (cited excerpts of Mr. DeVito’s deposition concerning experimentation to combine the teachings of Kudryavtsev with Wang do not support a conclusion that the experimentation is undue; Mr. DeVito simply testifies to the time that it would take to build the appropriate chamber to perform the testing); Reply 12–13 (citing Ex. 2014, 306:2–6, 307:1–13; Ex. 1031 ¶ 72) (supporting conclusion that experimentation to combine teachings of Wang and Kudryavtsev is unnecessary, and if done, is not undue). IPR2014-00799 Patent 7,808,184 B2 33 Cir. 2012) (citation omitted); In re Etter, 756 F.2d 852, 859 (Fed. Cir. 1985) (en banc) (noting that the criterion for obviousness is not whether the references can be combined physically, but whether the claimed invention is rendered obvious by the teachings of the prior art as a whole). In that regard, one with ordinary skill in the art is not compelled to follow blindly the teaching of one prior art reference over the other without the exercise of independent judgment. Lear Siegler, Inc. v. Aeroquip Corp., 733 F.2d 881, 889 (Fed. Cir. 1984); see also KSR, 550 U.S. at 420–21 (stating that a person with ordinary skill in the art is “a person of ordinary creativity, not an automaton,” and “in many cases . . . will be able to fit the teachings of multiple patents together like pieces of a puzzle”). More importantly, Wang discloses that application of the high peak power PP to the background power PB “quickly causes the already existing plasma to spread and increases the density of the plasma” to form a strongly- ionized plasma. Ex. 1005, 7:29–30 (emphasis added); Ex. 1002 ¶ 123. Mr. DeVito testifies that “[l]ike Kudryavtsev’s voltage pulse, application of Wang’s voltage pulse (which produces the peak power PP) to the weakly- ionized plasma rapidly increases the plasma density and the density of the free electrons.” Ex. 1002 ¶ 125; see also id. ¶ 127 (“Because Wang applies voltage pulses that ‘suddenly generate an electric field,’ one of ordinary skill reading Wang would have been motivated to consider Kudryavtsev and to use Kudryavtsev’s fast stage in Wang.”). On this record, we credit Mr. DeVito’s testimony, as it is consistent with the prior art disclosures. Moreover, we are persuaded by Mr. DeVito’s testimony that if one of ordinary skill did not experience Kudryavtsev’s IPR2014-00799 Patent 7,808,184 B2 34 “explosive increase” in plasma density in Wang, triggering a fast stage of ionization (as disclosed by Kudryavtsev) in Wang’s apparatus would have been a combination of known techniques yielding the predictable results of rapidly increasing the ionization rate and electron density. See id. ¶ 126. We further are not persuaded by Zond’s argument that applying Kudryavtsev’s model on plasma behavior to Wang’s sputtering apparatus would have been beyond the level of ordinary skill, or that one with ordinary skill in the art would not have had a reasonable expectation of success in combining the teachings. PO Resp. 50–53. Obviousness does not require absolute predictability, only a reasonable expectation that the beneficial result will be achieved. In re Merck & Co., 800 F.2d 1091, 1097 (Fed. Cir. 1986). As Dr. Bravman testifies, Kudryavtsev’s theoretical framework on plasma behavior is not intended to be limited to a particular type of plasma apparatus. Ex. 1031 ¶ 67. Indeed, Kudryavtsev discloses a study of the ionization relaxation in plasma when the external electric field suddenly increases. Ex. 1004, 30. Specifically, Kudryavtsev discloses that “the electron density increases explosively in time due to accumulation of atoms in the lowest excited states.” Id. at Abs. (emphasis added). Kudryavtsev also describes the experimental results that confirm the model. Id. at 32–34. Moreover, Kudryavtsev expressly explains that “the effects studied in this work are characteristic of ionization whenever a field is suddenly applied to a weakly ionized gas.” Id. at 34 (emphasis added); see Ex. 1031 ¶ 65. Dr. Bravman also testifies that a person having ordinary skill in the art “would have looked to Kudryavtsev to understand how plasma would react to a quickly applied voltage pulse, and how to achieve an explosive increase IPR2014-00799 Patent 7,808,184 B2 35 in electron density,” when generating a strongly-ionized plasma in view of Wang’s application for the benefit of improved sputtering and manufacturing processing capabilities. Ex. 1031 ¶ 68. Dr. Bravman further explains that such an artisan would know how to apply the teachings of Kudryavtsev to Wang’s system for performing sputtering, by making any necessary changes to accommodate the differences of pressures, dimensions, sizes, magnets, or other features through routine experimentation. Id. ¶ 69. On this record, we credit Dr. Bravman’s testimony because his explanations are consistent with the prior art of record. Accordingly, we are persuaded Gillette has articulated a reason with rational underpinning why one with ordinary skill in the art would have combined the technical teachings of Wang and Kudryavtsev. Remaining Limitations of Challenged Claims Zond does not address specifically whether the references teach or suggest a “method of generating a strongly-ionized plasma” comprising: (a) “supplying feed gas proximate to an anode and a cathode assembly,” and (b) “generating a voltage pulse between the anode and the cathode assembly” as required by both independent claims 1 and 11. See PO Resp. 25–54; Reply 2; Ex. 1001, 22:44–49. We are persuaded on this record that Gillette has shown sufficiently that Wang teaches these features. See Pet. 42–52; Ex. 1002 ¶¶ 113–135. In addition to the limitations discussed above found in independent claims 1 and 11, and those discussed below with respect to other dependent claims, dependent claims 2–4 and 12–14 add limitations that Gillette asserts IPR2014-00799 Patent 7,808,184 B2 36 are taught by the combination of Wang and Kudryavtsev. Zond does not address these limitations. See Reply 2. We are persuaded on the record before us that Gillette has demonstrated by a preponderance of the evidence that the combination of Wang and Kudryavtsev would have suggested the additional limitations of the dependent claims to one with ordinary skill in the art at the time of the invention. See Pet. 52–55; Ex. 1002 ¶¶ 138–146. Dependent Claims 5 and 15 Dependent claims 5 and 15 recite the method of claims 1 and 11, respectively, wherein “the voltage pulse comprise[s] a multi-stage voltage pulse.” Ex. 1001, 22:66–67, 24:10–11. Referring to Figure 5C of the ’184 patent, Zond asserts that the claim term “multi-stage voltage pulse” means “a voltage controlled pulse having at least two stages, wherein each stage is a discrete portion of the pulse during which the target voltage (or voltage amplitude set-point) differs from that of the other stage(s).” PO Resp. 55. Zond asserts that Wang teaches a single stage of power for its pulses, not a voltage pulse having at least two distinct target voltage amplitudes, id. at 55–56, and transient variations in voltage are not distinct “stages,” id. at 57. Gillette counters that “[i]n the context of the ’184 patent, the term ‘stage’ refers to different stages or regions of plasma generation when a voltage pulse is applied, and the term ‘multi-stage voltage pulse” means a voltage pulse that has multiple (i.e., two or more) stages or regions of plasma generation.” Reply 14 (citing Ex. 1031 ¶ 88); see id. at 13 (citing Ex. 1031 ¶¶ 85–87 (describing use of “region” and “stage” in Figs. 3, 7A, and 8)). IPR2014-00799 Patent 7,808,184 B2 37 We agree with Gillette that the Specification of the ’184 patent describes “stages” of a voltage pulse as different stages or regions of plasma generation. See, e.g., Ex. 1001, 6:20–23 (describing Fig. 3 where “[t]he voltage pulse 202 includes an ignition stage 205 that is characterized by a voltage 206 having a magnitude and a rise time that is sufficient to ignite a plasma from a feed gas. . . . After the ignition stage 205, the discharge current 208 continues to rise even as the voltage 210 decreases.”) (emphases added), 7:22–11:54 (describing Fig. 4 stating “[t]he multi-stage voltage pulse 252 is a single voltage pulse having multiple stages” and linking these stages to plasma development), 11:66–14:5 (describing Fig. 5A as “a two- stage voltage pulse 302 having a transient region included in both the low- power stage and the high-power stage of the pulse” and linking these stages to plasma development). Mr. DeVito testifies that one of ordinary skill in the art would have understood that Wang’s voltage pulse is a multi-stage voltage pulse because the voltage pulse generated by Wang’s power supply would have two or more stages or regions of plasma generation. Ex. 1002 ¶ 150; Pet. 56. Mr. DeVito further explains how the amplitude of the voltage changes throughout the voltage pulse in Wang to achieve the increase in the plasma’s density. Ex. 1002 ¶¶ 147–154; Pet. 56–57; see also Ex. 1031 ¶¶ 82–92 (Dr. Bravman agrees with Mr. DeVito’s conclusions). We credit Dr. DeVito and Dr. Bravman’s testimony as consistent with the Specification of the ’184 patent and the prior art. Based on the evidence before us, we are persuaded that Gillette has demonstrated by a preponderance of the evidence that the IPR2014-00799 Patent 7,808,184 B2 38 combination of Wang and Kudryavtsev teaches a “multi-stage voltage pulse,” as recited in claims 5 and 15. III. CONCLUSION For the foregoing reasons, we conclude that Gillette has demonstrated, by a preponderance of the evidence, that claims 1–5 and 11–15 are unpatentable under 35 U.S.C. § 103(a) over Wang and Kudryavtsev. IV. ORDER For the foregoing reasons, it is ORDERED that claims 1–5 and 11–15 of the ’184 patent are held unpatentable; FURTHER ORDERED that, because this is a Final Written Decision, parties to the proceeding seeking judicial review of the decision must comply with the notice and service requirements of 37 C.F.R. § 90.2. IPR2014-00799 Patent 7,808,184 B2 39 For PETITIONER: Gillette: David L. Cavanaugh david.cavanaugh@wilmerhale.com Larissa B. Park larissa.park@wilmerhale.com Fujitsu: David L. McCombs david.mccombs.ipr@haynesboone.com David M O’Dell david.odell.ipr@haynesboone.com Richard C. Kim rckim@duanemorris.com AMD: Brian M. Berliner bberliner@omm.com Ryan K. Yagura ryagura@omm.com Xin-Yi Zhou vzhou@omm.com Renesas: John J. Feldhaus jfeldhaus@foley.com Pavan Agarwal pagarwal@foley.com IPR2014-00799 Patent 7,808,184 B2 40 Mike Houston mhouston@foley.com GlobalFoundries: David Tennant dtennant@whitecase.com Dohm Chankong dohm.chankong@whitecase.com Toshiba: Robinson Vu Robinson.vu@bakerbotts.com For PATENT OWNER: Bruce Barker bbarker@chsblaw.com Dr. Gregory J. Gonsalves gonsalves@gonsalveslawfirm.com Copy with citationCopy as parenthetical citation