`
`1, Rachel J. Watters, am a librarian, and the Director of Wisconsin TechSearch
`
`(“WTS”), located at 215 North Randall Avenue, Madison Wisconsin, 53706. WTS is
`
`an interlibrary loan department at the University of Wisconsin-Madison.
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`I have worked
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`as a librarian at the University of Wisconsin library system since 1998.
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`I have been
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`employed at WTS since 2002, first as a librarian and, beginning in 2011, as the Director.
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`Through the course of my employment, I have become well informed about the
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`operations of the University of Wisconsin library system, which follows standard library
`
`practices.
`
`This Declaration relates to the dates of receipt and availability of the following:
`
`CRC Handbook of Chemistry and Physics, 71st edition (1990-1991),
`pages 12-103 through 12-108.
`
`rocedures or materials at the Universit 0 Wisconsin-
`Standard 0 eratin
`
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`
`
`Madison Libraries. When a volume was received by the Library, it would be checked
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`in, stamped with the date of receipt, added to library holdings records, and made
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`available to readers as soon after its arrival as possible. The procedure normally took a
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`few days or at most 2 to 3 weeks.
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`Exhibit A to this Declaration is a true and accurate copy of the title page, library
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`date stamp, and pages 12-103 through 12-108 of CRC Handbook ofCnemistry and
`
`Physics, 71st edition (1990-1991), from the University of Wisconsin—Madison Library
`
`collection. The date stamp on the back cover page indicates that the CRC Handbook of
`
`Intel Corp. et al. Exhibit 1021
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`Declaration of Rachel J. Watters on Authentication of Publication
`
`Chemistry and Physics, 71st edition (1990-1991), was received by Memorial Library,
`
`University of Wisconsin, on July 16, 1990.
`
`Based on the information in Exhibit A, it is clear that the volume was received by
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`the library on or before July 16, 1990, catalogued and available to library patrons within
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`a few days or at most 2 to 3 weeks after July 16, 1990.
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`I declare that all statements made herein of my own knowledge are true and that
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`all statements made on information and belief are believed to be true; and further that
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`these statements were made with the knowledge that willful false statements and the like
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`so made are punishable by fine or imprisonment, or both, under Section 1001 of Title 18
`
`of the United States Code.
`
`Date: September 16, 2016 Wisconsin TechSearch
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`Wendt Commons Library
`215 North Randall Avenue
`
`Madison, Wisconsin 53706
`
`Intel Corp. et al. Exhibit 1021
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`CRC Handbook
`
`EXHW
`
`of
`
`Chemistry and Physics
`
`A Ready-Reference Book of Chemical and Physical Data
`
`Editor-in-Chief
`
`David R. Lide, Ph.D.
`
`CRC Press
`
`Boca Raton Ann Arbor Boston
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`EXHIBIT A
`
`©1974, 1975, 1976, 1977, 1978, 1979, 1980, 1981, 1982, 1983, 1984, 1985, 1986, 1987, 1988, 1989, 1990 by CRC Press, Inc.
`
`©1964, 1965, 1966, 1967, 1968, 1969, 1970, 1971, 1972, 1973 by THE CHEMICAL RUBBER CO.
`Copyright 1918, 1920 by The Chemical Rubber Company (Copyright renewed 1946, 1948 by The Chemical Rubber Publishing Company)
`
`Copyright 1922 (Copyright renewed 1950), 1925 (Copyright renewed 1953), 1926 (Copyright renewed 1954), 1927 (Copyright renewed 1955), 1929
`(Copyright renewed 1957), 1936, 1937 (Copyright renewed 1965 by The Chemical Rubber Co.), 1939, 1940 (Copyright renewed 1968 by the Chemical
`Rubber Co.), 1941 (Copyright renewed 1969 by The Chemical Rubber Co.), 1942 (Copyright renewed 1970 by The Chemical Rubber Co.), 1943
`(Copyright renewed 1971 by The Chemical Rubber Co.), 1944 (Copyright renewed 1972 by The Chemical Rubber Co.), 1945 (Copyright renewed
`1973 by The Chemical Rubber Co.), 1947, 1949, 1950, 1951, 1952 (Copyright renewed 1980 by CRC Press, Inc.), 1953 (Copyright renewed 1981a
`by CRC Press, Inc.), 1954 (Copyright renewed 1982 by CRC Press, Inc.), 1955 (Copyright renewed 1983 by CRC Press, Inc.), 1956 by Chemical
`Rubber Publishing Company
`
`@1957, 1958, 1959, 1960, 1962 by Chemical Rubber Publishing Company
`
`All Rights Reserved
`Library of Congress Card No. 13-11056
`PRINTED IN U.S.A.
`
`ISBN—0—8493-O47 1 -7
`
`Intel Corp. et a1. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`JUL 16 1990
`EXHIBIT
`*RErl'em‘:'t\tce Ct'.'tl..t.§?CTt
`£‘aiEMQ:F§§Al_ 1.52-5.; ,‘;g:;y ‘
`ATOMIC WEIGHTS, MELTING AND BOILING POINTSBFJ-CERCUS M“; .
`THE ELEMENTS (CONTINUED)
`V
`‘
`‘
`
`.
`
`Symbol
`
`Atomic
`number
`
`Atomic
`weight
`
`Footnotes
`
`Melting
`point (‘’C)
`
`'
`
`'
`
`Radium
`Radon
`Rhenium
`Rhodium
`Rubidium
`Ruthenium
`Samarium
`Scandium
`Selenium
`Silicon
`Silver (Argentum)
`Sodium (Natrium)
`Strontium
`V Sulfur
`Tantalum
`Technetium
`Tellurium
`Terbium
`Thallium
`Thorium
`Thullium
`Tin (Slannum)
`Titanium
`Tungsten (Wolfram)
`Unnihexium
`Unnilpentium
`Unnilquadium
`Unnilseptiurn
`Uranium
`Vanadium
`Wolfram (see Tungsten)
`Xenon
`Ytterbium
`Yttrium
`Zinc
`Zirconium
`
`226.025
`(222)
`186.207(1)
`l02.90550(3)
`85.4678(3)
`l0l.07(2)
`150.36(3)
`44.955910(9)
`7896(3)
`28.0855(3)
`l07.8682(2)
`22.989768(6)
`87.62(l)
`32.0_66(_6)
`l80.9479(l)
`(98)
`l27.60(3)
`I58.92534(3)
`204.3833(2l
`232.038 1 ( 1)
`168.9342l(3)
`1l8.7l0(7)
`4788(3)
`l83.85(3)
`(263)
`(262)
`(261)
`(262)
`238.0289(1)
`50.9415(l)
`
`13 1 .29(2)
`173.o4(3)
`88.90585(2)
`6539(2)
`9l.224(2)
`
`700
`~71
`3180
`1965 i_3
`38.89
`2310
`1074 .
`1541
`217
`1410
`961.93
`97.81 i 0.03
`769
`112.8
`2996
`2172
`449.5 i 0.3
`1356
`303.5
`1750
`1545
`2319681
`1660 i 10
`3410 i 20
`
`-
`
`5627 (est.)
`3727 i 100
`686
`3900
`1794
`2836
`684.9 i 1.0
`2355
`2212
`882.9
`1384
`444.674
`5425 i 100
`4877
`989.8 i 3.8
`3230
`1457 i 10
`3800 (approx.)
`1950
`2270
`3287
`5660
`
`,
`
`'
`
`1132 i 0.8
`1890: 10
`
`—l1l.9
`819
`1552
`419.58
`1852 i 2
`
`g
`
`geological exceptional specimens are known in which the element has an isotopic composition outside the limits for nonnal
`material. The difference between the atomic weight of the element in such specimens and that given in the Table may exceed
`considerably the implied uncertainty.
`m modified isotopic compositions may be found in commercially available material because it has been subjected to an undisclosed
`or inadvertent isotopic separation. Substantial deviations in atomic weight of the element from that given in the Table can occur.
`range in isotopic composition of non'na1 terristrial material prevents a more precise atomic weight being given; the tabulated A‘ (E)
`value should be applicable to any normal material.
`Iriple point; (grapl1ite~liquid-gas), 3627 : 50°C at a pressure of 101 MPa and (graphite-diamond-liquid), 3830 to 3930°C at a
`pressure of 12 to 13 GPa.
`Longest half-life isotope mass is chosen for the tabulated Ar (E) value.
`
`r
`
`Mmg.
`
`L.|BRt‘-\Ft-
`
`2
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`SPECIFIC HEAT AND ENTHALPY OF SOME SOLIDS AT LOW EXHIBIT A
`TEMPERATURES
`R. J. Corruccini and J. J. Gniewek
`For a more extensive listing of data one is referred to N.B.S. Monograph 21 (1960)
`Joules/g X 453.6 = joules/lb X 0.239 = cal/g X 0.4299 = Btu/lb
`Metals
`
`Aluminum
`
`Beryllium
`T:
`
`Bismuth
`
`
`Cadmium
`2..
`
`C,
`jg" deg“ K
`0.00010“
`0.000051
`0.000108
`0.000176
`0.000261
`0.00050
`0.00088
`0.0014
`0.0040
`0.0089
`0.0175
`0.0315
`0.0515
`0.0775
`0.142
`0.214
`0.287
`0.357
`0.422
`0.481
`
`H—H..
`jg"
`—
`0.000025
`0.000105
`0.000246
`0.000463
`0.00121
`0.0026
`0.0049
`0.018
`0.048
`0.112
`0.232
`0.436
`0.755
`1.85
`3.64
`6.15
`9.37
`13.25
`17.76
`
`C,,
`jg" deg" K
`—
`0.000025
`0.000051
`0.000079
`0.000109
`0.000180
`0.000271
`0.000389
`0.000842
`0.00161
`0.00279
`0.00450
`—
`0.00996
`0.0192
`0.0341
`0.0562
`0.0906
`0.139
`0.199
`
`I
`
`H—H.,
`jg"
`—
`0.000013
`0.000051
`0.000116
`0.000209
`0.000496
`0.000944
`0.00160
`0.00457
`0.0105
`0.0212
`0.0392
`—
`0.109
`0.253
`0.523
`0.971
`1.69
`2.82
`4.51
`
`c,,
`jg" deg" K
`—
`0000005913
`0.0000461
`0.000170
`0.000493
`0.00214
`0.00547
`0.0104
`0.0238
`0.0363
`0.0477
`0.0572
`—
`0.0727
`0.0346
`0.0935
`0.100
`0.105
`0.103
`0.111
`
`H—H.,
`jg"
`—
`000000158
`0.0000233
`0.000123
`0.000432
`0.00288
`0.0102
`0.0259
`0.111
`0.262
`0.472
`0.734
`—
`1.38
`2.17
`3.06
`4.03
`5.05
`6.12
`7.21
`
`c,,
`jg" deg" K
`—
`0.000008
`0.000033
`0.000090
`0.00021
`0.00130
`0.0043
`0.0080
`0.025
`0.046
`0.066
`0.086
`—
`0.117
`0.141
`0.159
`0.172
`0.132
`0.190
`0.196
`
`H—l-Ia
`jg"
`
`0.000003
`0.000022
`0.000082
`0.00022
`0.0015
`0.0070
`0.109
`0.102
`0.28
`0.56
`0.94
`
`1.96
`3.26
`4.76
`6.43
`8.20
`10.1
`12.0
`
`Chromium
`
`
`Copper
`Germanium”
`Gold
`
`
`Cl,
`jg" deg“ K
`0.0000285
`0.000058
`0.000039
`0.00014
`0.000206
`0.000206
`0.000312
`0.000451
`0.00102
`0.00210
`0.00392
`0.00683
`0.0171
`0.0358
`0.0621
`0.093
`0.127
`0.161
`0.193
`
`'
`
`H—Hn
`jg"
`0.0000142
`0.0000573
`0.000131
`0.000237
`0.000567
`0.000567
`0.00107
`0.00182
`0.00528
`0.0123
`0.0274
`0.0532
`0.163
`0.421
`0.904
`1.68
`2.77
`4.21
`5.98
`
`Cp
`jg" deg" K
`0.000012
`0.000028
`0.000053
`0.000091
`0.00023
`0.00023
`0.00047
`0.00086
`0.0027
`0.0077
`0.016
`0.027
`0.060
`0.099
`0.137
`0.173
`0.205
`0.232
`0.254
`
`H—H.,
`jg"
`0.000006
`0.000025
`0.000064
`0.00013
`0.00044
`0.00044
`0.00112
`0.0024
`0.0107
`0.034
`0.090
`0.195
`0.61
`1.40
`2.58
`4.13
`6.02
`8.22
`10.6
`
`CF,
`g" deg" K
`0000000528
`000000423
`0.0000144
`0.0000344
`0.000125
`0.000125
`0.000335
`0.000813
`0.00445
`0.0125
`0.0240
`0.0366
`0.0617
`0.0358
`0.108
`0.131
`0.153
`0.173
`0.191
`
`H—H°
`jg"
`0000000132
`0.00000211
`0.0000107
`0.0000343
`0.000179
`0.000179
`0.000612
`0.00169
`0.0136
`0.0540
`0.145
`0.296
`0.786
`1.52
`2.50
`3.70
`5.12
`6.74
`3.55
`
`Cl,
`jg" deg" K
`0.000006
`0.000025
`0.000070
`0.00016
`0.00050
`0.00050
`0.0012
`0.0022
`0.0074
`0.0159
`0.0263
`0.0371
`0.0572
`0.0726
`0.0842
`0.0928
`0.0992
`0.1043
`0.1083
`
`H—H.,
`jg"
`0.000002
`0.000016
`0.000061
`0.00017
`0.00078
`0.00073
`0.0024
`0.0056
`0.028
`0.036
`0.191
`0.349
`0.821
`1.47
`2.25
`3.14
`4.10
`5.12
`6.13
`
`T
`°K
`1
`1
`2
`3
`4
`6
`8
`10
`15
`20
`25
`30
`35
`40
`50
`60
`70
`30
`90
`100
`
`T
`"K
`1
`2
`3
`4
`6
`6
`8
`10
`15
`20
`25
`30
`40
`50
`60
`70
`80
`90
`100
`
`Indium
`ax-Iron‘
`‘y-Iron“
`
`
`Lead
`21.21..
`
`T
`°K
`1
`1
`2
`2
`
`3
`3
`3.40”
`3.40
`4
`4
`5
`5
`6
`6
`7
`
`Cp
`jg"deg" K
`0.000029
`0.000019“
`0.000133
`0.000141"
`
`0.000410
`0.000464“
`0.000584
`0.000669”
`0.00095
`—
`—
`—
`0.00359
`
`—
`
`H—H.,
`jg"
`0.00001 1
`0.000006“
`0.000085
`0.000073“
`
`0.000341
`0.000357“
`0.000537
`0.000581“
`0.00099
`*
`—
`7
`0.00520
`—
`—
`
`C,
`jg"deg“K
`0.000090
`4
`0.000133
`4-
`
`0.000279
`—
`—
`—
`0.000382
`—
`4
`—
`0.000615
`—
`—
`
`H—H,,
`jg"
`0.000045
`»
`0.000131
`—
`
`0.000412
`—
`—
`—
`0.000742
`—
`—
`—
`0.00173
`#
`—
`
`CF,
`jg"d=g" K
`—
`—
`—
`—
`
`H—H¢
`jg"
`—
`—
`—
`7
`
`CF
`jg"deg“K
`0.000026
`0.000012“
`0.00012
`0.00009“
`
`—
`—
`—
`4
`—
`—
`—
`—
`—
`—
`—
`
`—
`
`—
`—
`—
`#
`—
`—
`—
`—
`—
`—
`
`0.00033
`0.00031“
`—
`-'
`0.0007
`0.0007“
`0.0015
`0.0015“
`0.00.7.9
`0.0030”
`0.0043
`
`H——Hu
`jg"
`0.000010
`0.000003“
`0.00007
`0.00005”
`0.00028
`
`0.00023“
`
`#
`—
`0.0008
`0.0007“
`0.0018
`0.0018”
`0.0039
`0.0040“
`0.008
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`SPECIFIC HEAT AND ENTHALPY OF SOME SOLIDS AT LOW EXHIBIT A
`TEMPERATURES (continued)
`Copper
`Germanium”
`
`Chromium
`
`T
`“K
`7
`8
`10
`15
`20
`25
`30
`40
`50
`60
`70
`80
`90
`100
`
`C,
`jg" deg“ K
`—
`0.00855
`0.0155
`0.036
`0.0608
`00857
`0.108
`0.141
`0.162
`0.176
`0.186
`0.193
`0.198
`0.203
`
`11-11..
`jg"
`—
`0.0170
`0.0408
`0.170
`0.413
`0.778
`1.265
`2.52
`4.04
`5.73
`7.53
`9.42
`11.38
`13.39
`
`C,
`jg" deg" K
`—
`0.00090
`0.00124
`0.00249
`0.0045
`0.0075
`0.0124
`0.029
`0.055
`0.087
`0.121
`0.154
`0.186
`0.216
`
`H—H,
`jg"
`—
`0.003233
`0.00537
`0.0145
`0.0316
`0.061
`0.110
`0.31
`0.73
`1.43
`2.46
`3.84
`5.55
`7.56
`
`C,
`g" deg“ K
`
`H—H.,
`jg"
`—
`4
`
`.
`.
`.
`.
`.
`.
`.
`
`.
`.
`.
`.
`.
`
`C,
`jg" deg" K
`000503
`0.0073
`0.0137
`0.0335
`0.0531
`00681
`0.0796
`00944
`0.103
`0.108
`0.112
`0.114
`0.116
`0.118
`
`H—H,
`jg"
`0.008“
`0.014
`0.034
`0.150
`0.368
`0.672
`1.042
`1.920
`2.91
`3.97
`5.07
`6.20
`7.35
`853
`
`Molybdenum
`
`C,
`jg" deg" K
`0.0000229
`0.0000472
`
`0.0000745
`
`0.000106
`
`H—H.,
`jgum'
`0.0000105
`0.0000445
`
`0.000105
`
`0.000194
`
`Palladium
`
`C,
`jg" deg“ K
`0.000120
`0.000242
`
`11-11.,
`jg"
`0.000060
`0000241
`
`C,
`jg" deg" K
`0.000099
`0.000203
`
`0.000369
`
`0.000503
`
`0.000546
`
`0000318
`
`0.00098
`
`0.000447
`
`H_H,,
`jg"
`00000493
`0.000200
`
`0.000459
`
`0.000840
`
`0.002213
`
`.
`
`0.00210
`0.00471
`0.00922
`0.0160
`0.0258
`0.0507
`0.0777
`0.101
`0.122
`0.139
`0.154
`0.167
`
`0.00807
`0.0245
`0.0586
`0.120
`0.223
`0.600
`1.24
`2.14
`3.26
`4.56
`6.03
`7.63
`
`0.000498
`0.00131
`0.00287
`0.00577
`0.00960
`0.0236
`0.0410
`0.0619
`0.0838
`0.104
`0.123
`0.139
`
`'-1
`7%’
`
`12233445566778899
`
`10
`15
`20
`25
`30
`40
`
`\'0\LnGoo
`axooaOOO
`
`Platinum
`
`Silicon‘
`
`T
`“K
`
`S8°<§5‘8‘$8‘é’8BGEooo.6u.6_
`
`C,
`jg" deg“ K
`0.000035
`0.000074
`0.000122
`0.000186
`0.00037
`0.00067
`0.00112
`00033
`0.0074
`00137
`0.0212
`0.038
`0055
`0.068
`0079
`0.088
`0094
`0.100
`
`H —— H,
`jg“
`0.0000175
`0.000071
`0.000168
`0.000320
`0.00085
`0.00188
`0.00365
`0.0135
`0.0395
`0.092
`0.182
`0.048
`0.95
`1.56
`2.29
`3.12
`4.02
`5.01
`
`C,
`jg“ deg“ K
`0.000048
`0.000097
`0.000147
`0.000201
`0.00032
`0.00047
`0.00065
`0.00135
`0.00271
`0.00561
`0.0106
`0.266
`0.0489
`0.9724
`0.094
`0.114
`0.132
`0.147
`
`jg"
`0.000024
`0.000096
`0.000218
`0.000392
`0.00091
`0.00170
`0.00281
`0.00765
`0.0174
`0.0373
`0.0071
`0.256
`0.633
`1.238
`2.07
`3.11
`4.34
`5.74
`
`C,
`jg" deg" K
`0.000000263
`000000210
`0.00000709
`00000168
`0.0000596
`0000140
`0.000275
`0.00109
`000337
`000849
`00171
`0.0440
`0.0785
`0.115
`0.152
`0.188
`0.224
`0.259
`
`H — H,
`jg"
`0.0000000658
`000000105
`000000532
`00000168
`0.0000853
`0.000279
`0.000679
`0.00374
`00138
`0.0423
`0.105
`0.400
`1.00
`1.97
`3.31
`501
`7.06
`9.47
`
`C,
`jg“ deg" K
`0.0000072
`0.0000239
`0.0000595
`0.000124
`000039
`0.00091
`00018
`0.0064
`0.0155
`0.0287
`0.0442
`0.078
`0.108
`0.133
`0.151
`0.166
`0.177
`0.187
`
`H — H.
`jg“
`0.0000032
`00000176
`0.0000574
`0.000146
`000062
`0.00187
`000452
`0.0233
`0.076
`0.185
`0.368
`0.979
`1.91
`3.12
`4.54
`6.13
`7.85
`9.67
`
`12_104
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`SPECIFIC HEAT AND ENTHALPY OF SOME SOLIDS AT LOW
`
`EXHIBIT A
`
`T
`“K
`1
`1
`2
`2
`3
`3
`1.72"
`3.72
`4
`4
`4.39“
`4.39
`5
`6
`8
`10
`12
`14
`15
`16
`18
`20
`25
`30
`40
`50
`60
`70
`80
`90
`100
`
`-
`
`TEMPERATURES (continued)
`Tantalum
`Tin twhitel
`Sodium”
`Titanium
`
`C,,
`H—H.,
`C,
`H—H.,
`C,
`H—H..
`C,
`H—H,,
`‘deg ‘K
`is”
`Jg"'dee"K
`jg"
`Jg“deg '
`jg"
`jg"dcg"K
`is"
`J:
`0.000081
`0.000035
`0.000032
`0.000016
`0.0000170
`0.0000079
`0.000071
`0.000035
`—
`—
`0.0000063‘
`0.0000021‘
`0.0000041‘
`0.0000009“
`—
`—
`0.000289
`0.000204
`0.000068
`0.000065
`0.000047
`0.0000383
`0.000146
`0.000143
`—
`—
`0.000054‘
`0.000026‘
`0.000048“
`0.0000228“
`—
`—
`0.00076
`0.00070
`0.000112
`0.000155
`0.000109
`0.000113
`0.000226
`0.000329
`~
`—
`0.000178"
`0.000138"
`0.000151“
`0.000116‘
`—
`—
`’
`T
`—
`—
`0.000198
`0.000221
`—
`#
`—
`—
`—
`—
`0.000285‘
`0.000270‘
`—
`—
`0.00160
`0.00184
`0.000171
`0.000295
`0.000245
`0.0(Xl283
`0.000317
`0.000599
`—
`—
`0.000352‘
`0.000400‘
`—
`—
`—
`—
`—
`—
`0.000201
`(l.000368
`—
`—
`—
`~
`~
`—
`0.000433“
`0.000553‘
`—
`—
`—
`—
`0.00298
`0.00408
`—
`—
`0.00054
`0.00065
`—
`—
`0.0051
`0.0()81
`0.000333
`0.000776
`0.00127
`0.00151
`0.00054
`0.00145
`0.0122
`0.0247
`0.000648
`0.00173
`0.0042
`0.0068
`0.00084
`0.00281
`0.0238
`0.0602
`0.00117
`0.00352
`0.0081
`0.0190
`0.00126
`0.00489
`0.0397
`0.123
`—
`—
`—
`—
`—
`—
`0.063
`0.225
`—
`—
`—
`—
`—
`_
`K
`T
`0.00360
`0.0145
`0.226
`0.093
`0.0033
`().0l56
`0.093
`0.380
`——
`—
`—
`—
`—
`—
`0.124
`0.597
`—
`—
`—
`—
`—
`_
`0.155
`0.875
`0.00823
`0.0432
`0.040
`0.251
`0.0070
`0.040
`0.259
`1.90
`0.0153
`0.102
`0.058
`0.498
`00134
`0.090
`0.364
`3.45
`().0240
`0.202
`0.076
`0.834
`0.0245
`0 182
`0.544
`8.03
`0.0430
`0.540
`0.106
`1.75
`0.0571
`0.581
`0.695
`14.2
`0.0604
`1.06
`0. 130
`2.93
`0.0992
`1.358
`0.793
`21.7
`0.0754
`1.74
`0.148
`4.33
`0.1467
`2.592
`(1.86
`30.0
`00.189
`4.27
`0.162
`5.88
`0.189
`427
`0.91
`38.9
`0.0976
`3.49
`0.173
`7.55
`0.230
`6.37
`0.95
`48.2
`0.105
`4.50
`0.182
`9.33
`0.267
`8.86
`0.98
`57.9
`0.111
`5.58
`0.189
`11.18
`0.300
`11.69
`Tungsten
`Zinc
`
`c,,
`H —— H.,
`C,
`H — H.,
`jg“deg"K
`jg"
`jg"dcg"K
`is"
`0.0000074
`0.0000037
`0.00001 1
`0.000005
`0.0000158
`0.0000152
`0.000028
`0.000023
`0.0000262
`0.0000360
`0.000058
`0.000065
`0.0000393
`0.0000685
`0.0001 1
`0.00014
`0.0000783
`0.000182
`().00029
`0.00053
`0.000141
`0.000396
`0.00096
`0.0016
`0.000234
`0.000765
`0.0025
`0.0050
`0.000725
`0.00297
`0.011
`0.034
`0.00189
`0.00927
`0.026
`0.125
`0.00421
`0.0237
`0.049
`0.31
`0.00783
`0.0534
`0.076
`0.62
`0.0184
`0.181
`0.125
`1.62
`0.0332
`0.436
`0.171
`3.11
`0.0483
`0.843
`0.208
`5.01
`0.0605
`1.39
`0.236
`7.23
`0.0715
`2.05
`0.258
`9.70
`0.0810
`2.81
`0.277
`12.38
`0.0888
`3.66
`0.293
`15.24
`
`T
`“K
`1
`2
`3
`4
`6
`8
`10
`15
`20
`25
`30
`40
`50
`60
`70
`80
`90
`100
`
`Superconducting.
`In germanium the electronic specific heat is markedly dependent on impurities. The values given are for pure germanium (negligible electronic specific heat).
`at-Iron is the form that is thermodynamically stable at low temperatures.
`It has the body—centered cubic lanice which is the basis of the ferritic steels.
`y-Iron is stable between 910 and 1400°C. It has the lace-centered cubic structure which is the basis of the austenitic steels.Since pure y-iron is not stable at low temperatures
`the above values were calculated by application of the Kopp—Neumann rule to experimental data on two austenitic Fe-Mn alloys and are 01' uncenain accuracy.
`Superconducting transition temperature.
`Superconducting transition temperature of mercury.
`Melting temperature of mercury.
`is markedly dependent on impurities. Values of the coefficient. ya, from zero to 2.4 X 10"‘jg" deg’: K have been reponed.
`In silicon the electronic specific heat. 'yT,
`The values in the above table are for pure silicon (y = 0).
`It has been shown (Barrett 1956. Hull & Rosenberg 1959) that sodium panially transforms at low temperatures from the normal body-centered cubic structure to close
`packed hexagonal. The transformation is ofthe manensitic type and is promoted by co1d—working at the low temperatures. Inasmuch as none ofthe calorimetric measurements
`on sodium were accompanied by crystallographic analysis. the tabulated data below lO0°K are to some degree ambiguous.
`Superconducting transition temperature of tin.
`Superconducting transition temperature of tantalum.
`
`12-105
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`CONSTANTS OF DEBYE-SOMMERFELD EQUATION
`
`Tmax = maximum temperature to which the equation
`C‘ = yT + aT3; G = l2-rr“R/50"-1; O€T€Tmax;
`can be used with the limiting value of 9.
`
`EXHIBIT A
`
`Substance
`
`1057
`
`-y
`
`jg“ deg‘: K
`50.4
`25
`0.32
`5.6
`28.3
`10.8!
`“‘
`3.75
`15.8
`90
`|5.|
`54
`251
`23
`120
`85
`98
`34.]
`-18
`"
`5.65
`60
`31.5
`l-1.7
`71
`7
`9.6
`
`Metals
`Aluminum
`Beryllium
`Bismuth
`Cadmium
`Chromium
`Copper
`Germanium
`Gold
`Indium
`um-lmn
`Lead
`Mzigne.sium
`oi-Mungunese
`Mulyhdcnum
`Nickel
`Niobium
`Pulludtum
`Platinum
`Rhodium
`Silicon
`Silver
`Sndium"
`Tuntulum
`Ttnluhitc)
`Titanium
`Tungsten
`ZIFIL‘
`Aiilt_\\
`I I3
`Constuntun‘
`1011
`.\‘lunc|“‘
`Other tnlurguntu suhstunccs
`Diuttinnd
`—
`[cc
`—
`P)I'L‘\‘
`—
`Organic .\uh\l;1ncc5
`Gl_\pt;t|
`Lucttc
`Pnl_t~I_\rcnc
`
`#
`—
`—
`
`mjg—atom" deg” K
`1.36
`0.226
`0.067
`0.63
`1.47
`0.687
`“
`0.74
`[.81
`5.0
`3.1
`1.32
`13.8
`1.113
`7.0
`7.9
`10.5
`6.7
`4.9
`-'
`(1.610
`[.37
`5.7
`1.75
`3.4
`1,3
`0.63
`
`6 9
`6.5
`
`—
`—
`—
`
`—
`—
`—
`
`10°01
`
`jg" deg” K
`0.93
`0.138
`5.66
`2.69
`0. I65
`0.746
`0.528
`2.19
`13.1
`0.349
`10.6
`l.|9
`0.328
`0.238
`0.39
`0.64
`0.39
`0.72
`0.173
`0.263
`1.58
`21.4
`0.69
`2.21
`0.54
`0.16
`1.10
`
`0.56
`0.63
`
`0.0152
`15.2
`3. I4
`
`27
`35
`63
`
`0“
`
`deg K
`425
`1160
`118
`186
`610
`344.5
`370
`165
`109
`464
`96
`406
`476
`440
`440
`320
`274
`240
`473
`640
`225
`I58
`250
`I95
`420
`405
`300
`
`384
`374
`
`2200
`192
`—
`
`—
`—
`—
`
`T"“"‘
`
`deg K
`4
`20
`2
`3
`4
`10
`2
`15
`2
`10
`4
`4
`12
`4
`4
`1
`4
`3
`4
`4
`4
`4
`4
`2
`10
`4
`4
`
`I5
`20
`
`50
`l()
`5
`
`4
`4
`4
`
`“
`
`Superconducting.
`
`12-106
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`THERMAL PROPERTIES OF PURE METALS
`From Handbook of Tables for Applied Engineering Science by R, E. 13012 and G. L. Tuvc, The Chemical Rubber C0,. 1970
`At Atmospheric Pressure
`Liquid Metal
`A1 100“K
`A1 25°C (77°Fl
`Vapor pressure
`
`A
`
`Latent
`heal 01
`fusion,
`cal/g
`
`Thermal
`conduc-
`tivity,
`watts
`cm"C
`
`Specific
`heat,
`cal/g"C
`
`Specific
`heat,
`cal/g°C
`
`10” atm 10"‘ atm I0 " alm
`Specific
`Coe1T. of
`heat 44
`Thermal
`linear
`(liquid)
`conduc-
`expansion,
`at 2000°K
`tivity,
`(X 10—6 )
`(°Cl" watts/cm°C’ cal/g"C
`
`Boiling point temperatures, “K
`
`95
`38.5
`324
`12.4
`13.2
`79
`66
`49
`15
`33
`65
`5.5
`88.0
`64
`2.7
`69
`71
`
`68
`34
`24
`3
`145
`50
`16
`430
`26.5
`27
`41
`17
`14.1
`100
`46
`12
`98
`27
`
`3.00
`—
`—
`—
`1.03
`1.58
`—
`4.83
`3.45
`——
`1.32
`0.396
`1.69
`—
`—
`1.79
`1.58
`
`0.552
`A
`0.79
`—
`~
`—
`—
`—
`4.50
`—
`0.592
`—
`0.85
`0.312
`2.35
`——
`—
`1.32
`
`'
`
`0.115
`0.040
`0.049
`0.026
`0.047
`0.046
`0.057
`0.061
`0.026
`0.022
`0.052
`0.028
`0.016
`0.064
`0.029
`0.033
`0.055
`
`0.045
`—
`0.024
`0.019
`0.150
`#
`—
`0.062
`0.045
`0.234
`0.026
`0.024
`0.039
`0.072
`0.021
`0.022
`0.061
`0.063
`
`0.215
`0.050
`0.436
`0.030
`0.055
`0.110
`0.10
`0.092
`0.031
`0.031
`0.108
`0.031
`0.243
`0.114
`0.033
`0.060
`0.106
`
`0.064
`0.031
`0.032
`0.032
`0.180
`0.058
`0.077
`0.17
`0.057
`0.293
`0.034
`0.03
`0.054
`0.125
`0.032
`0.028
`0.116
`0.093
`
`25
`9
`12
`13
`30
`6
`12
`16.6
`14.2
`6
`12
`29
`25
`22
`—
`5
`13
`
`7
`5
`9
`54
`83
`13
`37
`3
`19
`70
`6.5
`12
`20
`8.5
`4.5
`13.4
`8
`35
`
`2.37
`0.185
`2.18
`0.084
`0.93
`0.91
`0.69
`3.98
`3.15
`1.47
`0.803
`0.346
`1.59
`—
`0.0839
`1.4
`0.899
`
`0.52
`0.61
`0.73
`0.08
`0.99
`1.50
`0.005
`0.835
`4.27
`1.34
`0.54
`0.41
`0.64
`0.2
`1.78
`0.25
`0.60
`1.15
`
`0.26
`0.062
`0.78
`0.036
`0.063
`0.224
`0.164
`0.118
`0.0355
`0.0434
`0.197
`0.033
`0.32
`0.20
`—
`0.089
`0.175
`
`0.083
`0.039
`0.043
`0.041
`~
`0.092
`—
`0.217
`0.068
`—
`0.040
`0.047
`0.058
`0.188
`0.040
`0.048
`0.207
`—
`
`1,782
`1,007
`1,793
`1,155
`655
`1,992
`2,167
`1,862
`2,023
`3.253
`2,093
`1,230
`857
`1,495
`393
`3,344
`2,156
`
`3,523
`—
`2,817
`2,200
`606
`—
`—
`2,340
`1,582
`701
`3,959
`3,251
`1,857
`2,405
`4,139
`2,861
`2,525
`752
`
`1,333
`741
`1,347
`851
`486
`1,530
`1,652
`1,391
`1,510
`2,515
`1,594
`889
`638
`1,131
`287
`2,558
`1,646
`
`2,721
`—
`2,155
`1,596
`430
`—
`4-
`1,749
`1,179
`504
`3,052
`2,407
`1,366
`1,827
`3,228
`2,128
`1,948
`559
`
`1,063
`612
`1,085
`677
`388
`1,247
`1,345
`1,120
`1,211
`2,062
`1,297
`698
`509
`913
`227
`2,079
`1,343
`
`2,232
`—
`1,757
`1,252
`335
`—
`—
`1,427
`952
`394
`2,495
`1,919
`1,080
`1,484
`2,656
`1,699
`1,591
`449
`
`Metal
`
`Aluminum _
`Antimony
`Beryllium
`Bismuth
`Cadmium
`Chromium
`Cobalt
`Copper
`Gold
`Iridium
`Iron
`Lead
`Magnesium
`Manganese
`Mercury
`Molybdenum
`Nickel
`Niobium
`(Columbiuml
`Osmium
`Platinum
`Plutonium
`Potassium
`Rhodium
`Selenium
`Silicon
`Silver
`Sodium
`Tantalum
`Thorium
`Tin
`Titanium
`Tungsten
`Uranium
`Vanadium
`Zinc
`
`‘ (watts/cm°C) x 860.421 = Ca|(gm)hr' 'cm" “C71
`(watts/cm°C) x 57,818 = Btu hr" it" ' “F.
`
`THERMAL CONDUCTIVITY OF DIELECTRIC CRYSTALS
`
`Conductivity
`mW-cm"-K
`
`Conductivity
`mW-cm“-K
`
`Name
`
`Remarks
`
`83 K
`
`273 K
`
`Name
`
`Remarks
`
`83 K
`
`273 K
`
`Marble
`Do
`Do
`Calcite
`
`D0
`
`Sylvite
`KC1
`KC1
`NaCl
`NaCl
`Rock salt
`Sylvite
`KC1
`KC1
`KC1
`KBr
`NaBr
`K1
`KF
`NaF
`R131
`RbCl
`
`Small crystals, 99.9% CaCO,
`99.99% CaC0,
`Large crystals
`Main crystal axis perpendicu-
`lar to rod axis
`Main crystal axis parallel to
`rod axis
`Natural crystal
`Pressed at 8000 aim
`From a melt
`Do
`Pressed at 8000 atm
`Do
`Do
`Pressed at 1250 atm
`Pressed at 2500 atm
`Pressed at 8900 atm
`Pressed at 8000 atm
`Do
`Do
`Do
`Do
`Do
`Do
`
`42
`54
`50
`180
`
`293
`
`159
`314
`402
`343
`251
`180
`343
`243
`368
`402
`92
`50
`121
`234
`519
`59
`29
`
`33
`38
`33
`46
`
`54
`
`75
`88
`92
`92
`71
`63
`84
`75
`92
`96
`38
`25
`29
`71
`105
`33
`21
`
`90% KBr, 10% KC1
`75% KBr, 25% KC1
`50% KBr, 50% KC1
`25% KBr, 75% KC1
`10"/0 KBr, 90°70 KC1
`50% KC1, 50% NaCl
`KNO;
`Mercuric chloride
`NH.Cl
`NH1Br
`Ba(NO,),
`Copper sulfate
`Magnesium sulfate
`1<.t=e(CN,)
`Chrom alum
`Potassium alum
`Potassium bichromate Main crystal axis perpendicu-
`lar to rod axis
`Main crystal axis parallel to
`rod axis
`Mineral
`Do
`Do
`Do
`
`Do
`
`Topaz
`Zincblendc
`Beryll
`Tourmaline
`
`Do
`Do
`Do
`Pressed at 8000 atm
`D0
`Do
`Do
`Do
`Do
`Do
`D0
`
`50
`29
`25
`46
`30
`188
`17
`17
`109
`67
`33
`29
`25
`17
`13
`13
`17
`
`17
`
`63
`88
`38
`
`29
`21
`25
`33
`50
`71
`21
`13
`25
`25
`13
`21
`25
`17
`21
`21
`21
`
`17
`
`234
`264
`84
`46
`
`12-107
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021
`
`
`
`THERMAL CONDUCTIVITY OF CERTAIN METALS
`
`From NSRDS—NBS 8
`R. W. Powell, C. Y. Ho, and P. E. Liley
`The thennal conductivity, k, is given in the units W-cm-cm’2~K".
`To convert to cal-crn-cm‘2-h"-K“ multiply the values listed in the tables by 860.421.
`To convert to Btu-ft-ft‘:-h‘ l-°F“ multiply the values listed in the tables by 57.818.
`[.70 is the residual electrical resistivity and the value of p at 4.2°K is used approximately as po.
`Aluminum
`Copper
`Gold
`Iron
`Manganin
`Platinum
`99.996+%
`99.999*%
`99.999’'%
`99.998*%
`99.999%
`pa = 0.00315 pa = 0.000851
`pa = 0.0055
`po= 0.0327
`pa = 0.0106
`uohm cm
`uohm cm
`uohm cm
`pohm em
`pohm cm
`0
`0
`0
`0
`0
`7.8
`28.7
`4.4
`0.75
`2.31
`15.5
`57.3
`8.9
`1.49
`4.60
`23.2
`85.5
`13.1
`2.24
`6.79
`30.8
`113
`17.1
`2.97
`8.8
`
`0
`0.0007
`0.0018
`0.0031
`0.0046
`
`T,K
`0
`1
`2
`3
`4
`
`| B | T A
`
`Silver
`99.999"%
`po = 0.00062
`uohm cm
`0
`39.4
`78.3
`115
`147
`
`Tungsten
`99.99+%
`po = 0.0017
`uohm cm
`0
`14.4
`28.7
`42.6
`55.6
`
`38.1
`45.1
`51.5
`57.3
`62.2
`
`66.1
`69.0
`70.8
`71.5
`71.3
`
`70.2
`68.4
`63.5
`56.5
`40.0
`
`28.5
`21.0
`16.0
`12.5
`10.0
`
`6.7
`5.0
`4.0
`3.4
`3.0
`2.47
`2.37
`
`2.35
`2.36
`2.37
`2.40
`2.40
`
`2.37
`2.32
`2.26
`2.20
`2.13
`
`138
`159
`177
`189
`195
`
`196
`193
`185
`176
`166
`
`156
`145
`124
`105
`68
`
`43
`29
`20.5
`15.3
`12.2
`
`8.5
`6.7
`5.7
`5.14
`4.83
`4.28
`4.13
`
`4.04
`4.01
`3.98
`3.94
`3.92
`
`3.88
`3.83
`3.77
`3.71
`3.64
`
`[0.93]“
`[0.96]
`[0.99]
`[1.02]
`
`3.57
`3.50
`3.42
`(3.34)‘r
`
`20.7
`23.7
`26.0
`27.5
`28.2
`
`28.2
`27.7
`26.7
`25.5
`24.1
`
`22.6
`20.9
`17.7
`15.0
`10.2
`
`7.6
`6.1
`5.2
`4.6
`4.2
`
`3.8
`3.58
`3.52
`3.48
`3.45
`3.35
`3.27
`
`3.20
`3.18
`3.15
`3.13
`3.12
`
`3.09
`3.04
`2.98
`2.92
`2.85
`
`(2.78)
`(2.71)
`(2.62)
`(2.51)
`
`5
`6
`7
`8
`9
`
`10
`11
`12
`13
`14
`
`15
`16
`18
`20
`25
`
`30
`35
`40
`45
`50
`
`60
`70
`80
`90
`100
`150
`200
`
`250
`273
`300
`350
`400
`
`500
`600
`700
`800
`900
`
`1000
`1100
`1200
`1300
`1400
`
`1500
`1600
`
`0.0062
`0.0078
`0.0095
`0.0111
`0.0128
`
`0.0145
`0.0162
`0.0180
`0.0197
`0.0215
`
`0.0232
`0.0250
`0.0285
`0.0322
`0.0410
`
`0.0497
`0.0583
`0.067
`0.075
`0.082
`
`0.097
`0.110
`0.120
`0.127
`0.133
`0.156
`0.172
`
`0.193
`0.206
`0.222
`0.250
`(0.279)
`
`(0.338)
`(0.397)
`
`'
`
`3.71
`4.42
`5.13
`5.80
`6.45
`
`7.05
`7.62
`8.13
`8.58
`8.97
`
`9.30
`9.56
`9.88
`9.97
`9.36
`
`8.14
`6.81
`5.55
`4.50
`3.72
`
`2.65
`2.04
`1.68
`1.46
`1.32
`1.04
`0.94
`
`0.865
`0.835
`0.803
`0.744
`0.694
`
`0.613
`0.547
`0.487
`0.433
`0.380
`
`0.326
`0.297
`0.282
`0.299
`0.309
`
`0.318
`(0.327)
`
`172
`187
`193
`190
`181
`
`168
`154
`139
`124
`109
`
`96
`85
`66
`51
`29.5
`
`19.3
`13.7
`10.5
`8.4
`7.0
`
`5.5
`4.97
`4.71
`4.60
`4.50
`4.32
`4.30
`
`4.28
`4.28
`4.27
`4.24
`4.20
`
`4.13
`4.05
`3.97
`3.89
`3.82
`
`(3.74)
`(3.66)
`(3.58)
`
`10.5
`11.8
`12.6
`12.9
`12.8
`
`12.3
`11.7
`10.9
`10.1
`9.3
`
`8.4
`7.6
`6.1
`4.9
`3.15
`
`2.28
`1.80
`1.51
`1.32
`1.18
`
`1.01
`0.90
`0.84
`0.81
`0.79
`0.762
`0.748
`
`0.737
`0.734
`0.730
`0.726
`0.722
`
`0.719
`0.720
`0.723
`0.729
`0.737
`
`0.748
`0.760
`0.775
`0.791
`0.807
`
`0.824
`0.842
`0.860
`0.877
`(0.895)
`
`(0.913)
`
`67.1
`76.2
`82.4
`35 3
`35 1
`
`82.4
`77.9
`72.4
`66.4
`60.4
`
`54.8
`49.3
`40.0
`32.6
`20.4
`
`13.1
`8.9
`6.5
`5.07
`4.17
`
`3.18
`2.76
`2.56
`2.44
`2.35
`2.10
`1.97
`
`1.86
`1.82
`1.78
`1.70
`1.62
`
`1.49
`1.39
`1.33
`1.28
`1.24
`
`1.21
`1.18
`1.15
`1.13
`1.11
`
`1.09
`1.07
`1.05
`1.03
`1.02
`
`1.00
`0.98
`0.96
`0.94
`0.925
`0.915
`0.905
`0.900
`(0.895)
`
`‘ In the table the third significant figure is given only for the purpose of comparison and for smoothness and is not indicative of
`the degree of accuracy.
`‘" Values in square brackets are for liquid state.
`1 Values in parentheses are extrapolated.
`I Estimated.
`
`M108
`
`Intel Corp. et al. Exhibit 1021
`
`EXHIBIT A
`
`Intel Corp. et al. Exhibit 1021