Ex Parte Schowalter et al

Patent Trial and Appeal BoardApr 28, 2016

12020006 (P.T.A.B. Apr. 28, 2016)

UNITED STA TES p A TENT AND TRADEMARK OFFICE APPLICATION NO. FILING DATE 12/020,006 01125/2008 23517 7590 05/02/2016 MORGAN, LEWIS & BOCKIUS LLP (BO) 1111 PENNSYLVANIA A VENUE, N.W. WASHINGTON, DC 20004 FIRST NAMED INVENTOR Leo J. Schowalter UNITED STATES DEPARTMENT OF COMMERCE United States Patent and Trademark Office Address: COMMISSIONER FOR PATENTS P.O. Box 1450 Alexandria, Virginia 22313-1450 www .uspto.gov ATTORNEY DOCKET NO. CONFIRMATION NO. CIS-01117303632001 1050 EXAMINER JACKSON JR, JEROME ART UNIT PAPER NUMBER 2815 NOTIFICATION DATE DELIVERY MODE 05/02/2016 ELECTRONIC Please find below and/or attached an Office communication concerning this application or proceeding. The time period for reply, if any, is set in the attached communication. Notice of the Office communication was sent electronically on above-indicated "Notification Date" to the following e-mail address( es): kcatalano@morganlewis.com patents@morganlewis.com PTOL-90A (Rev. 04/07) UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD Ex parte LEO J. SCHOW ALTER, JOSEPH A. SMART, JAMES R. GRANDUSKY, and SHIWEN LIU Appeal2013-008996 Application 12/020,006 Technology Center 2800 Before ADRIENE LEPIANE HANLON, CATHERINE Q. TIMM, and JAMES C. HOUSEL, Administrative Patent Judges. HANLON, Administrative Patent Judge. DECISION ON APPEAL A. STATEMENT OF THE CASE The Appellants filed an appeal under 35 U.S.C. Â§ 134 from a final rejection of claims 1-8, 10-17, 19-21, and 23-31under35 U.S.C. Â§ 103(a) as unpatentable over Schowalter et al., 1 in view of Flynn et al.,2 and Bennett et al.3 We have jurisdiction under 35 U.S.C. Â§ 6(b). 1 US 2004/0033690 Al, published February 19, 2004 ("Schowalter"). 2 US 2003/0213964 Al, published November 20, 2003 ("Flynn"). 3 Brian R. Bennett & Jesus A. del Alamo, High Quality InGaAs/InP and InAlAs/InP Heterostructures Beyond the Matthews-Blakeslee Critical Layer Appeal2013-008996 Application 12/020,006 We REVERSE. The subject matter on appeal is directed to a semiconductor heterostructure comprising an aluminum nitride single-crystal substrate and at least one strained layer epitaxially grown there over, wherein a thickness of the strained layer(s) exceeds a predicted critical thickness associated therewith by at least a factor of 5 or 10 as calculated with the Matthews-Blakeslee theory. According to the evidence of record: If the lattice mismatch between the epilayer and substrate is small and the layer is thin, the mismatch will be accommodated entirely by strain in the layer. . . . If the layer is sufficiently thick and mismatched, the formation of misfit dislocations at the substrate/epilayer interface becomes energetically favorable. These dislocations relieve strain, allowing the epilayer lattice to relax back toward its natural cubic symmetry. The point at which misfit dislocations begin to form is known as the critical layer thickness. Bennett 650, col. 1. The Appellants disclose that "[ u ]nexpectedly, we have found that it is possible to grow pseudomorphic layers[4J with thicknesses much greater than the predicted critical thickness." Spec. 5, 11. 15-17. According to the Appellants, the ability to grow highly strained alloys of III-nitride on certain AlN substrates is dependent on: (i) substrate crystal quality, (ii) surface preparation, (iii) crystal orientation of the substrate surface, (iv) alloy concentration, (v) Thickness, 650-53. The copy of the Bennett article in the Official file of the instant Application does not bear a publication date. The Appellants state that the Bennett article is from "Proceedings of the Fourth International Conference on Indium Phosphide and Related Materials" held on April 21-24, 1992. See Appeal Brief dated February 5, 2013 ("App. Br."), at 7. 4 The Appellants define "pseudomorphic" as "epitaxial layers strained to at least approximately 80% of a lattice parameter of an underlying substrate (i.e., less than approximately 20% relaxed to its innate lattice parameter)." Spec. 5, 11. 24-27. 2 Appeal2013-008996 Application 12/020,006 growth conditions including substrate temperature and V-III ratio during growth, and/or (vi) rate of grading of the alloy concentration. Spec. 7, 11. 3-6. Representative claim 1 is reproduced below from the Claims Appendix of the Appeal Brief. The limitations at issue are italicized. 1. A semiconductor heterostructure comprising: an aluminum nitride single-crystal substrate; and at least one strained layer epitaxially grown thereover, the layer comprising at least one of AlN, GaN, InN, or any binary or tertiary alloy combination thereof, wherein a thickness of the strained layer exceeds a predicted critical thickness associated therewith by at least a factor of 5, as calculated with the Matthews-Blakeslee theory, f} lt . Â·1' "''""~' ("') I:â€¢ f -'Â·-Â·Â· . ~ ........ l.t,x. "'Â·. r.1â€¢.1iÂ±~ -t-Â· Â·.1 \, Â·. ti-.-. :-::-::-:: \ .'t ' 1 { ~ 8?rf' { i Â·-'Â· v) cos >!. â€¢ h Â· Â·Â· Â· where he is the predicted critical thickness, bis the magnitude of the Burgers vector of a dislocation formed between the layer and the substrate, f is the lattice mismatch between the layer and the substrate, vis the Poisson's ratio of the layer, "A is the angle between the slip direction of the layer and the direction in the plane of the layer perpendicular to the line of intersection of the slip plane of the layer and the interface between the layer and the substrate, and a is the angle between the dislocation and the Burgers vector of the dislocation. App. Br. 19 (emphasis added). B. DISCUSSION The Examiner finds Schowalter discloses III-N layers, such as AlGaN, epitaxially grown on an AlN substrate. Ans. 3--4.5 There is no dispute on this record that Schowalter does not disclose the thickness of the AlGaN layers or 5 Examiner's Answer dated May 10, 2013. 3 Appeal2013-008996 Application 12/020,006 disclose whether the AlGaN layers are strained layers. Nonetheless, the Examiner finds that "the growth of AlGaN on AlN is inherently growth of a strained layer [in Schowalter] because AlGaN does not have the same lattice constant as AlN." Ans. 4. The Examiner cites paragraphs 24 and 25 of Schowalter and page 5 line 12 to page 6, line 1 of the Appellants' Specification for support. Ans. 4-7. The Appellants argue the Examiner's finding of inherency is not supported by the record. More specifically, the Appellants argue: [A ]s those of skill in the art realize, the formation of a layer of material on a substrate having a different lattice constant does not necessarily result in that layer being strained. Indeed, that is the very point of the critical-thickness criterion expressed in the instant claims and illustrated in exemplary fashion in Figure 1 of the present application - indicating when such layers should be strained and when they should be lattice-relaxed (or simply "relaxed"). Reply Br. 4;6 see also Reply Br. 4 (contending that Appellants' description of Pig. 1 "demonstrates two regimes of AlGaN growth on AlN, strained-layer growth below the critical thickness and relaxed-layer growth above the critical thickness"). The Appellants' argument is supported by the record. See In re Oelrich, 666 F.2d 578, 581 (CCPA 1981) ("Inherency ... may not be established by probabilities or possibilities. The mere fact that a certain thing may result from a given set of circumstances is not sufficient." (quoting Hansgirg v. Kemmer, 102 F.2d 212, 214 (CCPA 1939))). As for the claimed thickness of the strained layer, the Examiner turns to Bennett. The Examiner finds "Bennett discloses heterojunction layers of strained III-V materials often have critical layer thicknesses 3-10 times larger than the predicted critical layer thickness from the M[ atthews ]-B [lakeslee] formula." Ans. 6 Reply Brief dated July 10, 2013. 4 Appeal2013-008996 Application 12/020,006 3--4. The Examiner concludes that "it would have been obvious for one of skill to try to make epitaxial layers thicker than any predicted M[atthews]-B[lakeslee] result, knowing the formula to be inexact and knowing that the thickest layers possible were clearly desirable in the art. "7 Final 6 (emphasis added). 8 The Appellants argue: In relying on Bennett to reject the instant claims, the Examiner effectively equates two different classes of materials - cubic zinc- blende crystals (such as InGaAs and InAlAs) and hexagonal crystals (such as AlN, GaN, and InN) - that evidence on the record[9J clearly indicates may not be equated, and he provides no reasoned justification for doing so. App. Br. 9. Indeed, the disclosure of Bennett is limited to epitaxial layers of InGaAs and InAlAs grown by molecular beam epitaxy on InP, 10 and, on appeal, the Examiner fails to address the differences in the epitaxial layers and substrates disclosed in Schowalter and Bennett. See Bennett 652, col. 2. InKSR Int'! Co. v. Teleflex Inc., 550 U.S. 398, 421 (2007), the Supreme Court explained "obvious to try" as follows: When there is a design need or market pressure to solve a problem and there are a finite number of identified, predictable solutions, a person of ordinary skill has good reason to pursue the known options within his or her technical grasp. If this leads to the anticipated success, it is likely the product not of innovation but of ordinary skill and common sense. In that instance the fact that a combination was 7 The Examiner relies on Flynn to show that III-N based layers were known to be used to form heterojunction transistors. Ans. 3. 8 Final Office Action dated August 3, 2012. 9 Declaration of Leo J. Schowalter, Ph.D., dated May 23, 2012, at ,-i,-i 6, 7. 10 In paragraph 24, relied on by the Examiner, Schowalter discloses that AlGaN may be epitaxially grown on single crystal AlN substrates by, for example, organometallic vapor phase epitaxy and other formation processes. 5 Appeal2013-008996 Application 12/020,006 obvious to try might show that it was obvious under Â§ 103. [Emphasis added.] In this case, the Examiner has failed to show that epitaxially growing a strained AlGaN layer on an AlN substrate, wherein the strained AlGaN layer has a thickness as claimed, was known to be a predictable solution, at the time of the Appellants' invention, for increasing the thickness of Schowalter' s epitaxial layer. The Examiner concludes that Schowalter enables the growth of a strained epitaxial layer having the claimed thickness, citing the Appellants' statement on page 12 of the Appeal Brief that "the instant specification ... recognizes the suitability of Schowalter' s substrate preparation techniques in the context of growth of strained layers beyond their critical thickness." Ans. 9. However, enablement and obviousness are separate statutory requirements. The test for obviousness, for example, "is what the combined teachings of the references would have suggested to those of ordinary skill in the art." 11 In re Keller, 642 F.2d 413, 425 (CCPA 1981). As explained inin re McLaughlin, 443 F.2d 1392, 1313-14 (CCPA 1971): Any judgment on obviousness is in a sense necessarily a reconstruction based upon hindsight reasoning, but so long as it takes into account only knowledge which was within the level of ordinary skill at the time the claimed invention was made and does not include knowledge gleaned only from applicant's disclosure, such a reconstruction is proper. [Emphasis added.] Suffice it to say that absent the Appellants' disclosure, there is no evidence on this record showing that an AlGaN layer epitaxially grown on the AlN substrate of Schowalter to the claimed thickness would have been expected to be strained 11 "[E]nablement requires that the specification teach those in the art to make and use the invention without undue experimentation." In re Wands, 858 F.2d 731, 737 (Fed. Cir. 1988). 6 Appeal2013-008996 Application 12/020,006 rather than relaxed. See Spec. 1, 11. 28-30 ("as the thickness of the epitaxial layer is increased, the strain energy in the epitaxial layer will grow and, typically, the layer will find some way to reduce the strain energy"). For the reasons set forth above, the Â§ 103(a) rejection of claims 1-8, 10-17, 19-21, 23, 26-30 is not sustained. Independent claim 24 recites, inter alia, "wherein a total thickness of the plurality of strained layers exceeds a predicted critical thickness associated therewith by at least a factor of 10, as calculated with the Matthews-Blakeslee theory." App. Br. 23. The Examiner states: Flynn discloses devices with multiple stacked strained layers[12J â€¢â€¢â€¢ and together the references suggest that critical layer thickness of the strained layers would be obvious beyond the M[atthews]-B[lakeslee] predicted thickness because the [Schowalter] substrate is enabling for such thickness critical layers. Ans. 9. As discussed above, the mere fact that the instant Application discloses that the Schowalter substrate is suitable for epitaxially growing a strained layer having the claimed thickness is not sufficient to demonstrate that the subject matter recited in claim 24 would have been obvious to one of ordinary skill in the art at the time of the Appellants' invention. For this reason, theÂ§ 103(a) rejection of claims 24, 25, and 31 is not sustained. C. DECISION The decision of the Examiner is reversed. 12 Flynn discloses that "thin strained layers or superlattices can be employed with layers having less than the critical thickness, to relieve strain in the epitaxial device structure." Flynn ,-i 331. 7 Appeal2013-008996 Application 12/020,006 REVERSED 8