`IPR2014-01065
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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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`
`ADVANCED MICRO DEVICES, INC., RENESAS
`ELECTRONICS CORPORATION, RENESAS ELECTRONICS
`AMERICA, INC., GLOBALFOUNDRIES U.S., INC.,
`GLOBALFOUNDRIES DRESDEN MODULE ONE LLC & CO.
`KG, GLOBALFOUNDRIES DRESDEN MODULE TWO LLC &
`CO. KH, TOSHIBA AMERICA, INC., TOSHIBA AMERICAN
`INFORMATION SYSTEMS, INC., AND TOSHIBA
`CORPORATON
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`Petitioner
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`v.
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`ZOND, LLC
`Patent Owner
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`U.S. Patent No. 7,604,716
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`_____________________
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`Inter Partes Review Case No. 2014-01065
`_____________________
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`PATENT OWNER’s PRELIMINARY RESPONSE
`UNDER 37 CFR § 42.107(a)
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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 Plasma Generation Systems ......................................................................6
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`B. The ‘716 Patent: Dr. Chistyakov Invents an Improved Plasma Source. .....................9
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`III. SUMMARY OF PETITIONER’S PROPOSED GROUNDS ........................................15
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`IV. CLAIM CONSTRUCTION UNDER 37 C.F.R. §§ 42.104(B)(3) ...................................15
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`A. Construction of “Weakly Ionized Plasma” and “Strongly Ionized Plasma” ...........15
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`B. Construction of “Ionizing a Feed Gas in a Chamber” ................................................17
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`C. Construction of “a Weakly Ionized Plasma that Substantially Eliminates the
`Probability of Developing an Electrical Breakdown Condition in the
`Chamber” ....................................................................................................................18
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`V. PETITIONER HAS FAILED TO SHOW A REASONABLE LIKELIHOOD
`OF PREVAILING. ..............................................................................................................20
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`A. Defects in Ground I: Petitioner Failed To Demonstrate That Claims 14 – 18,
`and 25 - 32 Are Obvious In view of Mozgrin Combined with Kudryavtsev.........20
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`1. Overview of Independent Claim 14. .....................................................................20
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`2. Legal Standards For Comparison of the Claim to the Prior Art. ..........................23
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`2. Scope and Content of Prior Art. ..............................................................................25
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`a. Overview of Mozgrin ..........................................................................................25
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`b. Overview of Kudravtsev .....................................................................................27
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`3. Differences Between Claim 14 and the Prior Art. ..................................................31
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`a. Differences Between Mozgrin and Claim 14 .......................................................31
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`b. Petitioner Fails to Prove Inherency .......................................................................34
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`c.
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`Incompatibilities of Kudravtsev and Mozgrin ......................................................36
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`d. Differences Between Claim 14 and Kudravtsev ...................................................39
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`e. Conclusion: Petitioner Fails to Show a Reasonable Likelihood that
`Claim 14 is Obvious in View of Mozgrin Combined With
`Kudryavtsev. .........................................................................................................40
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`f. Differences Between the Prior Art and the Other challenged Claims 15 –
`18, 25 - 32. .............................................................................................................41
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`B. Defects In Ground II: Petitioner Failed To Demonstrate A Reasonable
`Likelihood That the Challenged Claims Are Obvious in View of Wang
`Combined with Kudryavtsev.....................................................................................44
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`1. Overview of Wang. .............................................................................................44
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`2. Differences Between Wang and the Claims. ........................................................46
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`3. Petition Fails to Prove Inherency. .........................................................................49
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`4.
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`Incompatibilities of Kudravtsev and Wang ..........................................................50
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`5. Differences Between Claim 14 and Kudravtsev ...................................................52
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`6. Conclusion: Petitioner Fails to Show a Reasonable Likelihood that
`Claim 14 is Obvious in View of Wang Combined With
`Kudryavtsev. ...................................................................................................52
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`7. Differences Between the Prior Art and the Other Challenged Claims
`15 – 18, 25 - 32. ...............................................................................................53
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`C. Petition Violates Page Restrictions by Incorporating Sixty-Six Pages of
`Claim Charts. ........................................................................................................54
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`VI. CONCLUSION ....................................................................................................................55
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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
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`“is identical to the Intel IPR no. IPR2014-00522 in all substantive respects,
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`includes identical exhibits, and relies upon the same export 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 opposition to Intel’s request no. IPR-
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`2014-00522, which is reproduced below:
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`The present petition for inter partes review of U.S. Patent No. 7,604,716
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`(“the ‘716 patent”) is the third of four petitions filed by Intel challenging the
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`‘716 patent. This petition challenges two of the patent’s four independent
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`claims (nos. 14, 26) and several other claims that depend from claims 14, 26.
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`The challenges are based on two prior art references, Mozgrin1 and
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`Wang,2 that were already considered by the Patent Office, combined with a
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`prior art article by Kudryavtsev.3 As explained in detail below, the challenged
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`claims require, inter alia, a multi-stage ionization process in which atoms in a
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`weakly ionized gas are first excited from the ground state before being ionized
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`1 Ex. 1203, Mozgrin.
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`2 Ex. 1204, Wang patent No. 6,413,382 (“Wang”).
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`3 Ex. 1205, Kudryavtsev.
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`to form a strongly ionized plasma, but without developing an electrical
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`breakdown condition. This is in contrast to a conventional ionization process
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`in which atoms are ionized directly from the ground state, without first
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`achieving an excited state.
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`The Petition tacitly acknowledges that neither primary reference,
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`Mozgrin nor Wang, explicitly discusses or even hints of such an ionization
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`process. So the Petition instead argues that Mozgrin and Wang inherently
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`implement the claimed multi-stage ionization, citing to Kudryavtsev as proof.
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`But as a matter of law, “inherency may not be established by probabilities or
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`possibilities.”4 As the Board observed in a similar case: “it is well settled that
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`the ‘very essence of inherency is that one of ordinary skill in the art would
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`recognize that a reference unavoidably teaches the property in question.”5 “The
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`mere fact that a certain thing may result from a given set of circumstances is
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`not sufficient.”6
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`4 Id.
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`5 UBE Maxwell Co. v. LG Chem, LTD, IPR203-00470, Paper 25, page 12, citing
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`Agilent Technologies, Inc. v. Affymetrics, Inc., 567 1366, 1383 (Fed. Cir. 2009).
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`6 In re Oelrich, 666 F.3d 578, 581 (CCPA 1981).
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`By this standard, the Petition falls far short of proving inherency. As we
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`explain below, Kudryavtsev’s calculations predict that his tubular electrode
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`structure may or may not yield multi-stage ionization depending on a variety
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`of conditions, namely, the gas pressure p, the radius R of the tubular electrode
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`structure, the strength of the applied electric field E, and the density of ground
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`state argon atoms, n1. As shown in Kudryavtsev’s figure 6 below, direct
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`ionization predominates under the conditions represented by region II of this
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`diagram, electron density does not increase under the condition in region III; and in
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`region I “step-wise ionization predominates.”7:
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`Therefore Kudryavtsev does not prove that Mozgrin’s system or Wang’s
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`system would inherently provide the claimed multi-stage ionization, since even
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`in Kudryavtsev’s tubular electrode structure, the type of ionization depends on
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`a variety of factors.
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`7 Ex. 1205, Kudryatsev, page 34.
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`Kudryavtsev does not prove that Mozgrin’s or Wang’s radically different
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`electrode structures and operating conditions would inherently provide the
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`claimed multi-stage ionization. For example, both Mozgrin and Wang use
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`electrodes that are much more closely spaced than Kudryavtsev’s electrodes,
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`and which were immersed in a magnetic field that can dramatically influence
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`ion formation and ion density. Yet Kudryavtsev does not consider such a
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`magnetic field in his mathematical model or in his experimental set up.
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`Therefore, there is no indication in Kudryavtsev of how the presence of the
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`magnetic field in Mozgrin and Wang would influence the type of ionization.
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`The Petition also relies on two claim charts filed in violation of rules
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`§42.24(a)(i) and §42.6. The claim charts total forty pages, thereby exceeding
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`the page limitation when combined with the sixty-page petition.8
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`Lastly, the Petitioner reiterates its boilerplate argument that Zond
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`misrepresented Mozgrin’s teachings during prosecution of Zond’s U.S. patent
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`number 7,147,759 (“the ‘759 Patent”).9 Yet as we have responded to each
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`such assertion, 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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`8 Petition (60 pages); Ex. 1215 (40 Pages), and Ex. 1216 (15 pages).
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`9 Petition at p. 18, Ex. 1211, ‘759 Patent.
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`in which “ground state atoms” are excited to form “excited atoms,” and then
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`the excited atoms are “ionizing without forming an arc.”10 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.’”11 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.”12
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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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`10 Ex. 1212, Response of May 2, p. 13 – 16.
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`11 Petition at p. 18.
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`12 Exhibit 1212, Response to Office Action, May 2, 2006, p. 13 (emphasis
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`omitted).
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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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`A. Overview of Plasma Generation Systems
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`The claims at issue in this petition are all directed to an apparatus for
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`generating a strongly-ionized plasma. A “plasma” is a gaseous mixture of
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`electrons, positive ions and neutral molecules that can be formed by applying a
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`strong electric field to a gas.15 A simplified illustration of a plasma formed
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`between a pair of electrodes 238, 216 is shown below in figure 2B of the ‘716
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`patent:16
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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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`15 Ex. 1201, ‘716 Patent, col. 1, lines 8 - 15.
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`16 Ex. 1201, ’716 Patent, Fig. 2B.
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`A plasma is on average electrically neutral because there are approximately as
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`many negative electrons in the plasma as positive ions. However, the density
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`of charged particles can vary greatly depending on the strength of the applied
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`electric field and the length of time it is applied.
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`Figure 2D from the ‘716 patent17 below shows a “strongly ionized
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`plasma” having a significantly higher density of charged particles than in the
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`figure above, due in part to a stronger electric field applied across the
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`electrodes:
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`17 Ex. 1201, ‘716 Patent, Fig. 2D.
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`In pulsed systems, the strong electric field for generating a dense plasma is
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`applied in short bursts or pulses that temporarily provide the field strength
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`needed to form a dense plasma, but at a lower average power.18 The duration
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`of these pulses can be preset “to reduce the probability of establishing electrical
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`breakdown condition leading to an undesirable electrical l discharge” that can
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`“corrupt the plasma process and can cause contamination in the vacuum
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`chamber.”19 However, very large voltage pulses “can still result in undesirable
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`electrical discharged regardless of their duration.”20
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`18 Ex. 1201, ‘716 Patent, col. 3, lines 42 - 45.
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`19 Ex. 1201, ‘716 Patent, col. 3, lines45 - 50.
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`20 Ex. 1201, ‘716 Patent, col. 3, lines 50 - 51.
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`B. The ‘716 Patent: Dr. Chistyakov Invents an Improved
`Plasma Source.
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`Dr. Chistyakov invented an improved plasma source that forms a
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`strongly-ionized plasma in multiple stages: The source first ionizes a feed gas
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`to form a weakly ionized plasma, and then applies an electrical pulse across
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`the plasma that generates an electric field that provides the optimum
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`conditions for exciting neutral atoms in the weak plasma.21 The electric field
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`then ionizes the excited atoms to generate a strongly ionized plasma. The
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`weakly ionized plasma and the electric pulse thus cooperate to achieve a
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`strongly ionized plasma using a multi-stage ionization process, without
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`developing an electrical breakdown condition as explained below.
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`Dr. Chistyakov explained that forming a weakly ionized plasma having
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`a low level of ionization that is sufficient to provide some electrical
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`conductivity through the plasma can prevent the occurrence of a breakdown
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`condition when higher power pulses are applied:
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`The probability of establishing a breakdown condition is
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`substantially eliminated because the weakly-ionized plasma 232
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`has a low-level of ionization that provides electrical conductivity
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`through the plasma. This conductivity substantially prevents the
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`21 Ex. 1201, ‘716 Patent, col. 8, lines 49 – 53.
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`setup of a breakdown condition, even when high power is applied
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`to the plasma.22
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`Dr. Chistyakov further teaches that the type of high power pulse applied to the
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`weakly ionized plasma and the size of the gap between the electrodes can
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`determine whether the gas atoms directly ionize from the ground state, or
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`instead first enter an excited state and then ionize from the exited state. The
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`specification of the ‘716 patent explains the two types of ionization in more
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`detail.
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`The “typical ionization process is referred to as ‘direct ionization’ or
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`‘atomic ionization by electron impact’.”23 In this ionization process, a free
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`electron collides with a neutral atom with enough energy to ionize the atom,
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`thereby producing another free electron.24 In the multi-stage ionization process
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`described in the ‘716 patent, the electric field applied to a weakly ionized
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`plasma is chosen to excite atoms in the weakly ionized plasma from the
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`ground state into an excited state. The excited atoms are then ionized from
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`this excited state, rather than directly from the ground state.
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`22 Ex. 1201. ‘716 Patent, col. 6, lines 16 – 26.
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`23 Ex. 1201, ‘716 Patent, col. 2, liens 6 1- 63.
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`24 Ex. 1201, ‘716 Patent, col. 2, line 61 – col. 4, line 4.
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`The patent explains that a ground state atom requires more energy to
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`directly ionize that to enter an excited state:
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`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.25
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`Once an atom is in an excited state, it obviously requires less energy to ionized
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`than is required to directly ionize the atom from the ground state:
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`The excited [argon] atoms 274 only require about 4 eV of energy
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`to ionize while neutral atoms 270 require about 15.76 eV of energy
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`to ionize.26
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`Therefore, excited atoms will ionized at a much higher rate than ground state
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`atoms:
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`Therefore, the excited atoms 274 will ionize at a much higher rate
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`than the neutral atoms 270.27
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`The patent teaches that this type of ionization (in which ions are first excited
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`before being ionized), can be promoted by tailoring the parameters of the
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`electric pulse for the system’s electrode gap and other operating conditions of
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`the plasma.
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`25 Ex. 1201, ‘716 Patent, col. 8, lines 53 - 63.
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`26 Ex. 1201, ‘716 Patent, col. 8, lines 63 - 65.
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`27 Ex. 1201, ‘716 Patent, col. , lines 25 – 31.
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`The dimensions of the gap 220 and the parameters or the electric
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`field 236 are varied in order to determine the optimum condition
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`for a relatively high rate of excitation of the atoms in the region
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`222.
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`***
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`Under appropriate excitation conditions, the proportion of the
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`energy applied to the weakly-ionized plasma 232, which is
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`transformed to the excited atoms 244, is very high for a pulsed
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`discharge in the feed gas 22628
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` The ‘716 patent explains the relationship between the size of the electrode gap
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`and the applied voltage pulse, stating that they are together chosen to optimize
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`the excitation of atoms:
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`[T]he distance or gap between the cathode 204 and the anode 216
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`is chosen so as to maximize the rate of excitation of the atoms.
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`The value of the electric field 236 in the region 222 depends on
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`the voltage level applied by the pulsed power supply 202 and the
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`size of the gap 220 between the anode 216 and the cathode 204. In
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`some embodiments, the strength of the electric field 236 can vary
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`between about 2V/cm and 10.sup.5 V/cm depending on various
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`system parameters and operating conditions of the plasma system.
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`***
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`28 Ex. 1201, ‘716 Patent, col. 8, lines 49 – 52; col. 9, lines 27 - 30.
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`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
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`excitation of the atoms in the region 245.29
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`***
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`The shape and duration of the leading edge 356 and the trailing
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`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 268.30
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`The patent explains that this increased ionization efficiency can cause an
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`“avalanche like” increase in ion density:
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`This increased efficiency eventually results in an avalanche-like
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`increase in the density of the strongly-ionized plasma 238.31
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`Accordingly, to avoid an electrical breakdown in the plasma, the ‘716 patent
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`proposes that this type of ionization be generated under conditions that avoid
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`an electrical breakdown. For purposes of the claims at issue here, we note that
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`one proposed technique is to first generate a weakly ionized plasma that is
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`sufficiently conductive so as to inhibit a breakdown condition when a high
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`29 Ex. 1201, ‘716 Patent, col. 8, lines 30 - 53.
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`30 Ex. 1201, ‘716 Patent, col. 12, lines 23 - 28.
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`31 Ex. 1101, ‘716 Patent, col. 9, lines 24 - 26.
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`powered pulse chosen to promote multi-stage ionization is applied to the
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`electrodes:
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`The probability of establishing a breakdown condition is
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`substantially eliminated because the weakly-ionized plasma 232
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`has a low-level of ionization that provides electrical conductivity
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`through the plasma. This conductivity substantially prevents the
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`setup of a breakdown condition, even when high power is applied
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`to the plasma.32
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`Furthermore, the patent proposes choosing the pulse shape to control the rate
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`of ionization:
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`The shape and duration of the leading edge 306 and the trailing
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`edge 310 of the high-power pulse 304 is chosen to control the rate
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`of ionization of the strongly-ionized plasma.33
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`The claims at issue in this petition (independent claims 14, 26 and selected
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`dependent claims) are directed to a method and apparatus for generating a
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`strongly-ionized plasma using the multi-stage ionization process and
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`breakdown suppression techniques described above. The Petition alleges that
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`these claim are obvious in view of three prior art references, Mozgrin, Wang
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`and Kudryavtsev, as summarized in the table below.
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`32 Ex. 1201. ‘716 Patent, col. 6, lines 16 – 26.
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`33 Ex. 1201. ‘716 Patent, col. 12, lines 23 - 27.
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`III. Summary of Petitioner’s Proposed Grounds
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`Ground
`I
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`Claims
`14 – 18, 25 - 32
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`Alleged Basis
`103
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`Art
`Mozgrin and Kudryavtsev
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`II
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`14 – 18, 25 - 32
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`103
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`Wang and Kudryavtsev
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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 to 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 or parsing of the claim, inviting the reader to
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`infer the Petitioner’s interpretation of the claim language from its allegations
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`that the claimed features are taught by the 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 ‘716 patent which indicates that a strongly ionized plasma
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`is also referred to as a “highly-ionized plasma.”34 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.”35 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 ‘716 patent says that “a weakly ionized
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`plasma [has] a relatively low-level of ionization”36 Furthermore, the
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`34 Ex. 1201, ‘716 patent, col. 7, lines 15 - 16.
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`35 Ex. 1211, ‘759 patent, col. 10, lines. 4-5.
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`36 Ex. 1201, ‘716 patent, col. 6, lines 22 - 24.
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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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`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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`B. Construction of “Ionizing a Feed Gas in a Chamber”
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`The Petitioner does not construe the claimed phrase “ionizing a feed gas
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`in a chamber” from claim 14, but its comparison to the claim treats the
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`language as if it describes any gas in a chamber, regardless of whether the gas
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`is being fed into the chamber during ionization. However, this renders
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`superfluous the word “feed” in the expression “feed gas in a chamber” – “a
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`methodology of claim construction that [the Federal Circuit] has
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`denounced.”37 Even under the broadest reasonable interpretation standard, the
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`claim term “feed” cannot be read out of the claim and cannot be deemed
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`superfluous over the claimed “gas in a chamber.”
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`“A feed gas,” as its name implies, is a flow of gas. As explained in the
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`specification, the “electric field in the gap 472 between the electrode 452 and
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`the cathode 204' is adapted to ignite the plasma from the feed gas 226 flowing
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`37 Stumbo v. Eastman Outdoors, Inc., 508 F.3d 1358, 1362 (Fed. Cir. 2007).
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`through the gap 472.”38 The claimed step thus requires ionization of gas in the
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`chamber that is being fed into the chamber. Accordingly the claimed step of
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`“ionizing a feed gas in a chamber” refers ionization of a gas in a chamber as that
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`gas is being fed into the chamber.
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`Claim Language at Issue
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`Proposed Construction
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`“ionizing a feed gas in a chamber”
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`ionization of a gas in a chamber as
`that gas is being fed into the
`chamber
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`C. Construction of “a Weakly Ionized Plasma that Substantially
`Eliminates the Probability of Developing an Electrical
`Breakdown Condition in the Chamber”
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`The Petitioner does not offer an interpretation of the following language
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`from claims 14, 26: “a weakly ionized plasma that substantially eliminates the
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`probability of developing an electrical breakdown condition in the chamber.”
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`However, in its comparison to the prior art, the Petition treats the language as
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`encompassing any pre-ionized plasma to which an electric pulse is applied.
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`However, this interpretation renders superfluous the claimed requirement that
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`the weakly ionize plasma “substantially eliminates the probability of
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`developing an electrical breakdown condition in the chamber.”39
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`38 Ex. 1201, ‘716 Patent, col. 18, lines 9 – 12.
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`39 Stumbo v. Eastman Outdoors, Inc., 508 F.3d 1358, 1362 (Fed. Cir. 2007).
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`The claim language requires the weakly-ionized plasma provide a
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`specified plasma condition. In the context of the other claim language, this
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`language requires the weak plasma to substantially eliminate the probability of
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`developing a breakdown condition, not only when the weak plasma is formed,
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`but also when the claimed electrical pulse is applied across the weak plasma
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`that excites atoms and forms a strongly ionized plasma (see claim step b).
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`The specification identifies the characteristics of the weakly-ionized
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`plasma that achieve this condition. The specification states that the plasma
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`must have a low level of ionization that provide sufficient conductivity to
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`prevent the setup of a breakdown condition when high power is applied to the
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`plasma:
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`The probability of establishing a breakdown condition is
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`substantially eliminated because the weakly-ionized plasma 232
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`has a low-level of ionization that provides electrical
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`conductivity through the plasma. This conductivity substantially
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`prevents the setup of a breakdown condition, even when high
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`power is applied to the plasma.40
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`Thus, the claimed ionization step forms a low-level of ionization from the feed
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`gas that substantially eliminates the probability of breakdown. Furthermore,
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`when an electrical pulse is applied to that plasma to excite neutral atoms in the
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`40 Ex. 1201. ‘716 Patent, col. 6, lines 16 – 26.
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`weak plasma to thereby generate a strongly ionized plasma, the conductivity of
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`the weakly plasma must be sufficient to prevent an electrical breakdown.
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`Claim Language at Issue
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`Proposed Construction
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`a weakly ionized plasma that
`substantially eliminates the
`probability of developing an
`electrical breakdown condition in
`the chamber
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`plasma having a level of ionization that is
`low enough and sufficiently conductive to
`substantially eliminate the setup of a
`breakdown condition when the weakly
`ionized plasma is formed and when an
`electrical pulse is applied across the
`plasma to excite neutral atoms in the
`weakly-ionized plasma to thereby
`generate a strongly ionized plasma
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`V.
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`Petitioner Has Failed to Show a Reasonable Likelihood of Prevailing.
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`A. Defects in Ground I: Petitioner Failed To Demonstrate That
`Claims 14 – 18, and 25 - 32 Are Obvious In view of Mozgrin
`Combined with Kudryavtsev
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`1. Overview of Independent Claim 14.
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`The Petitioner alleges in Ground I that independent claim 14 is obvious
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`in view of the combined teachings of Mozgrin and Kudryavtsev.
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`The challenged claim 14 is generally directed to a combination of steps
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`for generating a strongly ionized plasma without developing an electrical
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`breakdown condition. The first step ionizes a feed gas in a chamber to form a
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`weakly ionized plasma that substantially eliminates the probability of
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`developing an electrical breakdown condition in the plasma. As explained in
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`the claim construction above, “a feed gas” as its name implies, is a gas that
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`feeds or flows into the chamber. The claimed step ionizes that gas feed within
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`the chamber to form a plasma having a low level of ionization that is
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`sufficiently conductive to substantially eliminate the probability of developing
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`an electrical breakdown condition in the plasma when an electrical pulse is
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`applied across this weakly ionized plasma, as specified in the next step of the
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`claimed method.
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` The claimed method supplies an electrical pulse across the weakly-
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`ionized plasma that excites atoms in the weakly ionized plasma to thereby
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`generate a strongly ionized plasma without developing an electrical breakdown
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`condition in the chamber. The specification explains this type of “multi-stage”
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`ionization in more detail, as discussed above. Briefly, in the first stage, neutral
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`atoms in the weakly ionized plasma are induced to an “excited state,” and then
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`the excited atoms are ionized. This multi-stage ionization is different from the
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`typical ionization process in which atoms are directly