`IPR2014-00802
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`UNITED STATES PATENT AND TRADEMARK OFFICE
`_____________________
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`BEFORE THE PATENT TRIAL AND APPEAL BOARD
`_____________________
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`TAIWAN SEMICONDUCTOR MANUFACTURING COMPANY, LTD.
`AND TMSC NORTH AMERICA CORP.
`Petitioner
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`v.
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`ZOND, LLC
`Patent Owner
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`U.S. Patent No. 7,811,421
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`_____________________
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`Inter Partes Review Case No. 2014-00802
`_____________________
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`PATENT OWNER’s PRELIMINARY RESPONSE
`UNDER 37 CFR § 42.107(a)
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`Patent No. 7,811,421
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`TABLE OF CONTENTS
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`I.
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`INTRODUCTION ..................................................................................................................1
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`II. TECHNOLOGY BACKGROUND ....................................................................................6
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`A. Overview of Sputtering Systems ...................................................................................6
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`B. The ‘421 Patent: Dr. Chistyakov Invents an Improved Sputtering Source....................8
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`III. SUMMARY OF PETITIONER’S PROPOSED GROUNDS ........................................13
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`IV. CLAIM CONSTRUCTION UNDER 37 C.F.R. §§ 42.104(B)(3) ...................................14
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`A. Construction of “Weakly Ionized Plasma” and “Strongly Ionized Plasma” ...............14
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`V. PETITIONER HAS FAILED TO SHOW A REASONABLE LIKELIHOOD
`OF PREVAILING. ..............................................................................................................16
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`A. Overview of Challenged Claims. ..............................................................................16
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`B. All of Petition’s Obviousness Grounds Fail to Follow the Proper Legal
`Framework For an Obviousness Analysis. ..................................................................20
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`C. All Grounds Rely on Claim Charts Submitted in Violation of Rules
`42.24(a)(i) and 42.6(a)(3) ............................................................................................21
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`D. Defects in the Challenges to the “Group A” Claims 9, 21, 35.....................................22
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`1. Defects in Grounds I and III: Petitioner Failed To Demonstrate That
`Claims 9, 21 and 35 Are Obvious In View of Mozgrin and
`Kudryavtsev............................................................................................... 23
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`a. Mozgrin Does not Anticipate Parent Claims 1, 34 or Teach the
`Corresponding Elements of Parent Claim 17...................................................24
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`i. Overview of Mozgrin ...............................................................................24
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`ii. Mozgrin Does Not Teach a Sputtering Source Comprising a
`Cathode Assembly Having a Sputtering Target Positioned
`Adjacent to an Anode.................................................................................27
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`iii. Mozgrin Does Not Describe the Claimed Pulse for Creating a
`Weak Plasma and Then a Strongly-Ionized Plasma From the
`Weak. .........................................................................................................30
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`iv. Mozgrin Does Not Teach The Claimed Generation of a Pulse
`whose Amplitude and Rise Time Are Chosen to Increase Ion
`Density Without Arcing .............................................................................32
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`v. Conclusion: Petitioner Has Not Shown a Reasonable Likelihood of
`Success that Parent Claims are Anticipated by Mozgrin ...........................33
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`b. The Petition Does Not Show A Reasonable Likelihood That Claims 9,
`21 and 35 Are Obvious in View of Mozgrin Combined with
`Kudryavtsev. ....................................................................................................43
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`i. General Scope of Kudryavtsev ................................................................35
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`ii. Incompatibility of Kudryavtsev and Mozgrin and the Absence of
`Motivation to Combine ..............................................................................37
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`iii. Differences Between Kudryavtsev and the Claims ...................................39
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`iv. Conclusion: ...............................................................................................43
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`2. Defects In Ground V: Petitioner Failed To Demonstrate A Reasonable
`Likelihood That Claims 9, 21, and 35 Are Obvious in View of Wang
`Combined with Kudryavtsev .......................................................................................43
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`a. Defects in Ground V: Wang Does not Anticipate Parent Claims 1, 17, 34 .... 43
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`i. Wang Does Not Show the Claimed Pulse for Creating a Weak Plasma and
`Then a Strongly-Ionized Plasma From the Weak Without An Occurrence
`of Arcing ....................................................................................................44
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`ii. Wang Does Not Teach The Claimed Generation of a Pulse Whose Rise
`Time Is Chosen to Increase Ion Density Without Arcing. .........................45
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`iii. Conclusion: Petitioner Has Not Shown a Reasonable Likelihood of
`Success that Parent Claims 1, 21, and 34 are Anticipated by Wang as
`Required By Ground V ..............................................................................46
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`b. Defects In Ground V: The Petition Fails to Show a Reasonable Likelihood
`that Claims 9 and 35 are Obvious in View of Wang Combined with
`Kudryavtsev .................................................................................................... 47
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`i. Differences Between Kudryavtsev and the Claims ...................................48
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`ii. Incompatibilities Between Kudryavtsev and Wang ...................................48
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`E. Defects in the Challenges to the Group B Claims. ......................................................49
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`1. The Petition Fails to Prove that Mozgrin’s Thesis is Prior Art. .................... 52
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`2. Mozgrin Thesis Does Not Teach the Claimed Invention ............................. 55
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`VI. CONCLUSION ....................................................................................................................57
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`I.
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`Introduction
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`The Petitioner has represented in a motion for joinder that this petition is
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`identical to the Intel IRP (no. IPR2014-00470) in all substantive respects,
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`includes identical exhibits, and relies upon the same expert declarant.
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`Accordingly, based upon that representation, the Patent Owner opposes
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`review on the same basis presented in the opposition to Intel’s request no.
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`IRP2014-00470 which is reproduced below:
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`The present petition is the second of three petitions filed by Intel Inc. for
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`inter partes review of U.S. Patent No. 7,811,421 (“the ‘421 patent”). The first
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`(IPR 2014-00468) seeks cancellation of all independent claims (1, 17, 34, 46,
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`47, and 48), and selected dependent claims. This second petition seeks
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`cancellation of six dependent claims (9, 14, 21, 26, 35, and 37), and a third
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`petition (IPR 2014- 00474) seeks cancellation of the remainder.
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`This second petition relies on the same arguments and evidence
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`presented against the parent claims in IPR 2014-00468, but adds new
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`arguments and evidence directed to the dependent claims. Therefore, this
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`second petition should be categorically denied for the exact same reasons given
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`by the Patent Owner in response to IPR 2014-00468, which are repeated here,1
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`but with some supplementary arguments. Furthermore, as explained below,
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`the dependent claims specifically addressed in the present petition are even less
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`likely to be found un-patentable and therefore the Petition does not justify
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`review.
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`The present petition cites as its primary prior art, two references,
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`Mozgrin2 and Wang,3 which were already considered by the Patent Office.4
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`The Petitioner tries to convince the Board that Zond misrepresented Mozgrin’s
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`teachings during prosecution of Zond’s U.S. patent number 7,147,759 (“the
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`‘759 Patent”).5 A mere glance at the record reveals to the contrary: In the
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`alleged misrepresentation, Zond argued that Mozgrin does not teach a process
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`in which “ground state atoms” are excited to form “excited atoms,” and then
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`1 Rule §46.6 prohibits incorporation by reference of the Patent Owner’s
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`response from IPR 2014-000455.
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`2 Ex. 1203, Mozgrin.
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`3 Ex. 1204, Wang patent No. 6,413,382 (“Wang”).
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`4 Ex. 1201, ‘421 Patent, list of cited references cited.
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`5 Petition at ps. 19 - 20, Ex. 1211, ‘759 Patent.
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`2
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`the excited atoms are “ionizing without forming an arc.”6 On the basis of this
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`assertion, the Petitioner accuses Zond of wrongly asserting that “Mozgrin does
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`not teach ‘without forming an arc.’”7 The Patent Owner (i.e., the Applicant at
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`that time), never argued, as alleged by the Petitioner, that the claims were
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`allowable solely because of the “without forming an arc” limitation; it instead
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`argued, inter alia, that “there is no description in Mozgrin of a multi-step
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`ionization process that first excites ground state atoms to generate excited
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`atoms, and then ionizes the excited atoms without forming an arc discharge.”8
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`That is, the Patent Owner argued that Mozgrin did not teach avoidance of an
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`arc discharge during a particular process that was the subject of the ‘759
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`patent: a multi-step ionization process. In other words, the Petitioner
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`mischaracterized the Patent Owner’s argument to the Examiner by truncating
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`it and quoting only a small portion of it in the Petition.
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`The parent claims to the dependent claim challenged here, are directed
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`to a sputtering source for sputtering material from a sputter target, and a
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`method for high deposition rate sputtering. The claimed source and method
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`generate a voltage pulse for creating the ions needed for sputtering, wherein
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`6 Ex. 1212, Response of May 2, p. 13 – 16.
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`7 Petition at p. 18.
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`8 Ex. 1212, Response to Office Action, May 2, 2006, p. 13 (emphasis omitted).
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`the pulse’s shape is chosen or adjusted to create a weakly ionized plasma and
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`then a strongly ionized plasma from the weak, but without arcing. The
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`Petition first argues that Mozgrin anticipates these parent claims, even though
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`Mozgrin is a research paper that does not describe a sputter source for
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`sputtering material from a target, and never discloses any experiments that
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`teach choosing or adjusting the pulse amplitude and rise time as claimed.
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`The Petition next cites to Wang as anticipating the parent claims. Wang
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`at least describes sputtering from a target, but as Petitioner acknowledges,
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`“Wang teaches that arcing may occur during ignition” of the plasma.9 This is
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`blatantly at odds with the claimed requirement that the generated pulse “create
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`a weakly ionized plasma … without an occurrence of arcing.” The Petition
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`tries to diminish the significance of this shortcoming by citing to Wang’s
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`observation that “the initial plasma ignition needs to be performed only
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`once.”10 But this is irrelevent.
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`Furthermore, when the Petition resorts to its obviousness theories for the
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`dependent claims, it never cures the shortcomings of the allegedly anticipatory
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`references against the parent claims. In fact, it does not address these
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`9 Petition at 36.
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`10 Petition at page 36, quoting Ex. 1204, Wang.
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`shortcomings or explicitly discuss the differences between the claims and the
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`art, as required by the Supreme Court for a proper obviousness analysis. 11 The
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`dependent claims further specify the plasma conditions that result from
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`properly “choosing” or “adjusting” the pulse rise time and amplitude: In these
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`dependent claims the resulting voltage pulse promotes a multi-step ionization
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`process that first excites ground state atoms to generate excited atoms and
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`generates “secondary electrons” from a cathode assembly. These secondary
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`electrons then ionize the excited atoms to form the strongly ionized plasma.
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`This later stage causes an “avalanche-like increase in the density” of the
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`plasma.12 But the amplitude and rise time of the pulse are chosen or adjusted
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`to promote this type of increase without forming an arc discharge. The
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`Petition cites to a prior art reference by Kuryavtsev that mentions a type of
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`multi-step ionization, but Kuryavtsev is not even directed to sputtering and
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`never mentions the claimed technique of choosing pulse rise time and
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`11 Graham v. John Deere Co., 383 U.S. 1, 17-18, 148 USPQ 459, 467 (1966);
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`KSR Int’l Co. v. Teleflex Inc., 550 U.S. 398, 399 (2007) (“[T]he [Graham] factors
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`define the controlling inquiry”); Liberty Mutual v. Progressive Casualty, CMB-
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`2012-00003, paper 7 at 2 – 3.
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`12 Ex. 1201, ‘421 Patent, col. 13, line 66.
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`amplitude to promote the claimed type of multi-step ionization without an
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`occurrence of arcing.
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`In short, the Petition does not precisely state the relief requested13 and
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`fails to demonstrate a reasonable likelihood that any challenged claim is
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`unpatentable.14 On the basis of the record presented in the present Petition,
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`review should be denied.
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`II. Technology Background
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`The claims are directed to a “sputtering source” having a “sputtering
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`target” and to a method of high deposition rate sputtering.” Accordingly, we
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`begin with a brief introduction to sputtering.
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`A. Overview of Sputtering Systems
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`Sputtering is a known technique for depositing a thin film of material on
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`a substrate. Sputtering systems include a cathode assembly 114 that includes a
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`sputtering target 116 made of a material that is desired for the thin film:
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`Fig. 2
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`Fig. 3
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`13 37 C.F.R. § 42.104(b).
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`14 37 C.F.R. § 42.108(c).
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`The sputtering source bombards the target surface 156 with ions to dislodge
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`atoms, causing them to deposit on the substrate in a thin film.15 Positive ions
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`154 are driven into the surface 156 of the sputtering target 116 by an electric
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`field at an angle of incidence and with sufficient energy to knock atoms 160,
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`170 from the target.16 The dislodged atoms “flow to a substrate where they
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`deposit as a film of target material.”17
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`To create ions for sputtering, a voltage source applies an electric field to
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`a gas that frees some electrons from their gas molecules to form a gaseous
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`mixture of electrons, positively charged molecules (i.e., ions) and neutral gas
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`molecules, i.e., a “plasma.” The density of ions produced depends, inter alia,
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`upon the strength of the applied electric field.
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`15 Ex. 1201, ‘421 patent, col 1, lines 15 – 22.
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`16 Ex. 1201, ‘421 patent, col. 5, lines 20 - 30.
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`17 Ex. 1201, ‘421 patent, col. 1, lines 20 – 21.
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`The rate at which material sputters from the target increases with the
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`density of ions in the plasma.18 One known way to increase the plasma density
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`is to strengthen the ionizing electric field. But this can induce high currents
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`that generate undesirable heating and damage to the target, as well as electrical
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`arcing that “corrupts the sputtering process.”19 One known solution to this
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`problem is to apply the strong electric field in short bursts that temporarily
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`provide the desired field strength, but at a lower average power to reduce the
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`undesirable effects.20 However, such high power pulses “can still result in
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`undesirable electric discharges and undesirable target heating.”21 The ‘421
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`patent describes an improved pulsed system for generating a strongly ionized
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`plasma for use in sputtering material from a sputter target, but without arcing.
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`B. The ‘421 Patent: Dr. Chistyakov Invents an Improved
`Sputtering Source.
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`To overcome the problems of the prior art, Dr. Chistyakov invented a
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`magnetically enhanced sputtering source having a particular structure of an
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`anode, cathode, ionization source, magnet and power supply generating a
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`18 Ex. 1201, ‘421 patent, col 3, lines 3 – 7.
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`19 Ex. 1201, ‘421 patent, col 3, lines 20 – 29.
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`20 Ex. 1201, ‘421 patent, col 3,lines 30 - 35.
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`21 Ex. 1201, ‘421 patent, col 3, lines 36 - 38.
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`particular type of voltage pulse to perform a multi-step ionization process for
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`sputtering, but without forming an arc discharge as illustrated in Fig. 4 of the
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`‘421 patent, reproduced below:
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`As illustrated by Fig. 4, Dr. Chistyakov’s magnetically enhanced sputtering
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`source includes an anode 238 and a cathode assembly 216 having a sputtering
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`target 220 made of the material to be sputtered that is positioned inside the
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`cathode 218.22 The anode 238 is positioned adjacent to the cathode assembly
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`“so as to form a gap 244 between the anode 238 and the cathode assembly 216
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`22 Ex. 1201, ‘421 patent, col. 6, line 46 – col. 7, line 6.
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`that is sufficient to allow current to flow through a region 245 between the
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`anode 238 and the cathode assembly 216.”23 The gap 244 and the total volume
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`of region 245 are parameters in the ionization process.”24 The “cathode
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`assembly 216 includes a cathode 218 and a sputtering target 220 composed of
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`target material.”25
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`“[T]he pulsed power supply 234 is a component in an ionization source
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`that generates the weakly-ionized plasma.”26 “The pulsed power supply
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`applies a voltage pulse between the cathode assembly 216 and the anode
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`238.”27 “The amplitude and shape of the voltage pulse are such that a weakly-
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`ionized plasma is generated in the region 246 between the anode 238 and the
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`cathode assembly 216.”28 “The peak plasma density of the pre-ionized plasma
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`depends on the properties of the specific plasma processing system.”29
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`23 Ex. 1201, ‘421 patent, col. 7, lines 30 - 31.
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`24 Ex. 1201, ‘421 patent, col. 7, lines 35 - 38.
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`25 Ex. 1201, ‘421 patent, col. 6, lines 47 - 49.
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`26 Ex. 1201, ‘421 patent, col. 8, lines 13 - 15.
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`27 Ex. 1201, ‘421 patent, col. 8, lines 16 - 17.
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`28 Ex. 1201, ‘421 patent, col. 8, lines 18 - 21.
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`29 Ex. 1201, ‘421 patent, col. 8, lines 27 - 29.
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`The ‘421 patent describes techniques for controlling a voltage pulse to
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`form a strongly ionized plasma that yields the desired sputtering from a
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`sputtering target, but without arcing. The ‘421 patent proposes that if the
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`shape of a pulse is chosen correctly, the density of ions generated by the pulse
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`can be increased to a desired level but in a controlled manner that avoids
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`arcing.30
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`The patent describes several systems. In one, a shaped pulse creates a
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`weakly ionized plasma and then transitions it into a strongly ionized
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`condition.31 In the other system, a continuous DC power source generates and
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`maintains a weakly ionized plasma,32 and a shaped pulse is superimposed to
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`transition the existing weak plasma into a strongly ionized state.
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`The first version is described in connection with the pulsed power supply
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`234 shown in fig. 4. The pulsed supply 234 generates a pulse for creating a
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`weakly ionized plasma:
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`In one embodiment, the pulsed power supply 234 is a component
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`of an ionization source that generates the weakly-ionized plasma.
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`The pulsed power supply applies a voltage pulse between the
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`30 Ex. 1201, ‘421 patent, col. 8, lines 18 – 21; col. 16, lines 60 – 64.
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`31 Ex. 1201, ‘421 patent, col. 8, lines 13 – 37.
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`32 Ex. 1201, ‘421 patent, col. 8, lines 45 – 48.
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`cathode assembly 216 and the anode 238. In one embodiment, the
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`pulsed power supply 234 applies a negative voltage pulse to the
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`cathode assembly 216. The amplitude and shape of the voltage
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`pulse are such that a weakly-ionized plasma is generated in the
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`region 246 between the anode 238 and the cathode assembly 216.33
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`After the weakly–ionized plasma is formed, the pulsed power supply 234
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`increases power to transition the weakly ionized plasma to a strongly-ionized
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`plasma:
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`Once the weakly-ionized plasma is formed, high-power pulses are
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`then generated between the cathode assembly 216 and the anode
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`238. In one embodiment, the pulsed power supply 234 generates
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`the high-power pulses. The desired power level of the high-power
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`pulse depends on several factors including the desired deposition
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`rate, the density of the pre-ionized plasma, and the volume of the
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`plasma, for example.34
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`The patent explains that “the shape and duration of the leading edge 356 and
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`the trailing edge 358 of the high-power pulse 354 is chosen so as to sustain the
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`weakly-ionized plasma 262 while controlling the rate of ionization of the
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`strongly-ionized plasma 268.35
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`33 Ex. 1201, ‘421 patent, col. 8, lines 13 – 22.
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`34 Ex. 1201, ‘421 patent, col. 9, lines 29 – 36.
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`35 Ex. 1201, ‘421 patent, col. 16, lines 60 – 64.
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`With regard to the second version referred to above, the ‘421 patent
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`mentions that the weakly ionized plasma can instead be generated with a
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`“direct current (DC) power supply” not shown in the patent’s figures:
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`In one embodiment, a direct current (DC) power supply (not
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`shown) is used to generate and maintain the weakly-ionized or
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`pre-ionized plasma. In this embodiment, the DC power supply is
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`adapted to generate a voltage that is large enough to ignite the pre-
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`ionized plasma.36
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`However, the claims of the ‘421 patent are directed to the technique wherein a
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`pulse first ignites a weakly ionized plasma without arcing, and then increases
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`the ion density into a strongly ionized plasma. The amplitude, rise time and
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`duration of the pulse are chosen to create a weakly ionized plasma and then
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`transition it into a strongly-ionized plasma without arcing.37
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`III. Summary of Petitioner’s Proposed Grounds
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`For the Board’s convenience, here is a summary of the Petition’s proposed
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`claim rejections:
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`Ground Claims Alleged Basis
`I
`9, 35
`103
`II
`14, 37
`103
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`36 Ex. 1201, ‘421 Patent, col. 8, lines 45 – 48.
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`Art
`Mozgrin and Kudryavtsev
`Mozgrin and Mozgrin’s Thesis
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`37 Ex. 1201, ‘421 Patent, col. 8, lines 18 – 21; col. 9, lines 16 – 19; col. 16, lines
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`60 – 64.
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`III
`IV
`V
`VI
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`21
`26
`9, 21, 35
`14, 26, 35
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`103
`103
`103
`103
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`Mozgrin, Lantsman and Kudryavtsev
`Mozgrin, Lantsman, and Mozgrin’s Thesis
`Wang and Kudryavtsev
`Wang and Mozgrin’s Thesis
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`IV. Claim Construction Under 37 C.F.R. §§ 42.104(b)(3)
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`Pursuant to Rule §42.104(b)(3), the Petitioner “must identify [] how the
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`claim is to be construed” for purposes of comparing the challenged claim the
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`cited art. The present Petition construes only the claimed phrases “strongly-
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`ionized plasma” and “weakly-ionized plasma.” For all other claim language it
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`offers no explicit construction, leaving the reader to infer the Petitioner’s
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`“interpretation” from its allegations that the claimed features are taught by the
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`prior art.
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`A. Construction of “Weakly Ionized Plasma” and “Strongly
`Ionized Plasma”
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`The Petitioner’s proposed constructions of the claim terms “strongly
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`ionized plasma,” and “weakly ionized plasma” are wrong because they are not
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`the broadest reasonable constructions consistent with the specification. In
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`particular, the Petitioner’s proposed construction of “strongly ionized plasma”
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`as a “higher density plasma” is wrong because the proposed construction reads
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`the claim term “ionized” out of the claim. That is, the Petitioner’s proposed
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`construction of “strongly ionized plasma” is incomplete because it does not
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`specify what the term “density” refers to.
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`The proper construction of “strongly ionized plasma” is “a plasma with
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`a relatively high peak density of ions.” This proposed construction specifies
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`that the term “density” refers to ions and therefore, is consistent with the claim
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`language. Moreover, the proposed construction is also consistent with the
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`specification of the ‘421 patent which indicates that a strongly ionized plasma
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`is also referred to as a “high-density plasma.”38 In addition, the proposed
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`construction is consistent with the specification of the ‘759 patent that refers to
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`“strongly ionized plasma [as] having a large ion density.”39 The term
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`‘strongly-ionized plasma’ is defined herein to mean a plasma with a relatively
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`high peak density of ions.
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`For similar reasons, the proper construction of the claim term “weakly
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`ionized plasma” is “a plasma with a relatively low peak density of ions.” In
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`particular, the specification of the ‘421 patent says that “a weakly ionized
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`plasma [has] a relatively low-level of ionization”40 Furthermore, the
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`specification of a related patent number 6,806,652 (“the ‘652 Patent”) states
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`that “[t]he term ‘weakly-ionized plasma’ is defined herein to mean a plasma
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`38 Ex. 1201, ‘421 patent, col. 12, lines 11 - 12.
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`39 Ex. 1212, ‘759 patent, col. 10, lines. 4-5.
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`40 Ex. 1201, ‘421 patent, col. 9, lines 24 – 25.
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`15
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`with a relatively low peak plasma density. The peak plasma density of the
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`weakly ionized plasma depends on the properties of the specific plasma
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`processing system.”
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`V.
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`Petitioner Has Failed to Show a Reasonable Likelihood of Prevailing.
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`A. Overview of Challenged Claims.
`
`The challenged claims 9, 21 and 35 (the “Group A” claims) each add the
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`same feature to their respective parent claims (1, 17, 34) that is generally directed
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`to choosing or adjusting the claimed voltage pulse parameters so that the pulse,
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`inter alia, yields a multistage ionization process as seen below:
`
`Claim 9
`The sputtering source of
`claim 1 wherein
`
`the voltage pulse
`generated between the
`anode and the cathode
`assembly excites atoms in
`the weakly-ionized
`plasma and generates
`secondary electrons from
`the cathode assembly, the
`secondary electrons
`ionizing a portion of the
`excited atoms, thereby
`creating the strongly-
`ionized plasma.
`
`
`Claim 21
`The sputtering source of
`claim 17 wherein
`
`the voltage pulse
`generated between the
`anode and the cathode
`assembly excites atoms in
`the weakly-ionized
`plasma and generates
`secondary electrons from
`the cathode assembly, the
`secondary electrons
`ionizing a portion of the
`excited atoms, thereby
`creating the strongly-
`ionized plasma.
`
`Claim 35
`The method of claim 34
`wherein
`
`the applying the voltage
`pulse to the cathode
`assembly generates
`excited atoms in the
`weakly-ionized plasma
`and generates secondary
`electrons from the
`sputtering target, the
`secondary electrons
`ionizing the excited
`atoms, thereby creating
`the strongly-ionized
`plasma.
`
`
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`16
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`IPR2014-00802
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`These claims are all directed to an improvement over their respective parent
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`claims, wherein the voltage pulse (which is used to create a weakly ionized
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`plasma and then transition it to a strongly ionized plasma), has an amplitude
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`and rise time that is chosen to promote a type of step-wise ionization during
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`the transition of the plasma from a weakly ionized state to a strongly ionized
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`state.
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`In the claimed type of step-wise ionization, neutral atoms in the weakly
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`ionized plasma are first induced to an “excited state.” The patent also explains
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`that less energy is required to excite an atom than to directly ionize it from its
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`ground state:
`
`For example, an argon atom requires an energy of about 11.55 eV
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`to become excited …. while neutral atoms 270 require about
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`15.76 eV of energy to ionize.41
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`The claimed pulse also generates “secondary electrons from the cathode
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`assembly,” that interact with the excited atoms to ionize them. As the
`
`specification explains, ions in the plasma strike the cathode assembly to cause
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`“secondary electron emission” from the cathode assembly.42 These secondary
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`electrons emitted from the cathode interact with the excited atoms to rapidly
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`41 Ex. 1201, ‘421 Patent, col. 13, lines 25 - 36.
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`42 Ex. 1201, ‘421 patent, col. 13, lines 36 – 39.
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`
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`17
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`ionize the excited atoms and thus further increase the ion density near the
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`cathode surface:
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`These secondary electrons interact with neutral 270 or excited
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`atoms 274 in the strongly-ionized plasma 268. This process further
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`increases the density of ions 272 in the strongly-ionized plasma
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`268 as the feed gas 256 is replenished.
`
`***
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`The excited atoms 274 are rapidly ionized by secondary electrons
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`emitted by the cathode assembly 216. This rapid ionization results
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`in a strongly-ionized plasma 268 having a large ion density being
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`formed in the area 264 proximate to the cathode assembly 216.43
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`
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`Atoms in an excited state require less energy to ionize than non-excited,
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`“ground state” atoms.44 As explained in the patent, argon for example requires
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`15.76 electron volts to ionize, whereas an excited argon atom only requires
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`about 4 electron volts to ionize. Therefore, excited atoms will ionized at a
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`much higher rate than ground state atoms:
`
`The excited atoms 274 only require about 4 eV of energy to ionize
`
`while neutral atoms 270 require about 15.76 eV of energy to
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`43 Ex. 1201, ‘421 patent, col. 13, lines 38 – 63.
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`44 Ex. 1201, ‘421 Patent, col. 13, lines 25 – 30.
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`ionize. Therefore, the excited atoms 274 will ionize at a much
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`higher rate than the neutral atoms 270.45
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`The patent teaches this type of multi-step ionization can be promoted by
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`properly choosing the shape of the voltage pulse:
`
`The parameters of the applied electric field 266 are varied to
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`determine the optimum condition for a relatively high rate of
`
`excitation of the atoms in the region 245.46
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`
`
`***
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`The shape and duration of the leading edge 356 and the trailing
`
`edge 358 of the high-power pulse 354 is chosen so as to sustain the
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`weakly-ionized plasma 262 while controlling the rate of ionization
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`of the strongly-ionized plasma 268.47
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`The Petition challenges these claims in three obviousness grounds (I, III, and
`
`V), which we will address as a group below (the “Group A Claims”).
`
`
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`The other challenged claims (14, 26, and 37) each add a feature to their
`
`respective parent claims that specifies a numerical range for the claimed pulse
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`rise time (The “Group B Claims”):
`
`Claim 14
`
`Claim 26
`
`Claim 37
`
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`45 Ex. 1201, ‘421 Patent, col. 13, lines 25 – 31.
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`46 Ex. 1201, ‘421 Patent, col. 14, lines 22 – 25.
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`47 Ex. 1201, ‘421 Patent, col. 16, lines 60 – 64.
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`19
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`
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`The sputtering source of
`claim 1 wherein the rise
`time of the voltage pulse
`is in the range of
`approximately
`0.01V/.mu.sec to
`1000V/.mu.sec
`
`
`The sputtering source of
`claim 17 wherein the rise
`time of the voltage pulse
`is in the range of
`approximately
`0.01V/.mu.sec to
`1000V/.mu.sec
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`Patent No. 7,811,421
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`The method of claim 34
`wherein the rise time of
`the voltage pulse is in the
`range of approximately
`0.01V/.mu.sec to
`1000V/.mu.sec.
`
`The Petition challenges these claims in three obviousness grounds (II, IV, and
`
`VI), which we will address as “Group B” below.
`
`
`B. All of Petition’s Obviousness Grounds Fail to Follow the Proper
`Legal Framework For an Obviousness Analysis.
`
`The Graham framework requires consideration of the following factors:
`
`(1) the scope and content of the prior art, (2