Chemistry:List of thermal conductivities
In heat transfer, the thermal conductivity of a substance, k, is an intensive property that indicates its ability to conduct heat. For most materials, the amount of heat conducted varies (usually non-linearly) with temperature.[1]
Thermal conductivity is often measured with laser flash analysis. Alternative measurements are also established.
Mixtures may have variable thermal conductivities due to composition. Note that for gases in usual conditions, heat transfer by advection (caused by convection or turbulence for instance) is the dominant mechanism compared to conduction.
This table shows thermal conductivity in SI units of watts per metre-kelvin (W·m−1·K−1). Some measurements use the imperial unit BTUs per foot per hour per degree Fahrenheit (1 BTU h−1 ft−1 F−1 = 1.728 W·m−1·K−1).[2]
Sortable list
This concerns materials at atmospheric pressure and around 293 K (20 °C).
Material | Thermal conductivity [W·m−1·K−1] | Notes |
---|---|---|
Acrylic glass (Plexiglas V045i) | 0.170[3]–0.200[4] | |
Alcohols, oils | 0.100[5][6] | |
Alumina | 30[7] | For main article, see Aluminium oxide. |
Aluminium | 237[8] | |
Aluminium nitride | 321[9] | For high-quality single crystal. |
Beryllia | 209–330[10][11][12] | For main article, see Beryllium oxide. |
Bismuth | 7.97 | |
Boron arsenide | 1300[13] | |
Cubic boron nitride | 740[14] | |
Copper (pure) | 401[5][15][16] | For main article, see Copper in heat exchangers. |
Diamond | 1000[5] | |
Fiberglass or foam-glass | 0.045[6] | |
Germanium | 60.2 | |
Polyurethane foam | 0.03[5] | |
Expanded polystyrene | 0.033–0.046[17] | |
Manganese | 7.810[5] | Lowest thermal conductivity of any pure metal.[18] |
Water | 0.5918[19] | |
Marble | 2.070–2.940[5][20] | |
Silica aerogel | 0.02[5] | |
Silicon nitride | 90,[21] 177[22] | Ceramics material. |
Silver | 406[23] | Highest thermal conductivity of any pure metal. |
Snow (dry) | 0.050[5]–0.250[5] | |
Teflon | 0.250[5] | |
Kapton (tape) | 1.720[24] |
Analytical list
Thermal conductivities have been measured with longitudinal heat flow methods where the experimental arrangement is so designed to accommodate heat flow in only the axial direction, temperatures are constant, and radial heat loss is prevented or minimized. For the sake of simplicity the conductivities that are found by that method in all of its variations are noted as L conductivities, those that are found by radial measurements of the sort are noted as R conductivities, and those that are found from periodic or transient heat flow are distinguished as P conductivities. Numerous variations of all of the above and various other methods have been discussed by some G. K. White, M. J. Laubits, D. R. Flynn, B. O. Peirce and R. W. Wilson and various other theorists who are noted in an international Data Series from Purdue University, Volume I pages 14a–38a.[8]
This concerns materials at various temperatures and pressures.
Material | Thermal conductivity [W·m−1·K−1] | Temperature [K] | Electrical conductivity @ 293 K [Ω−1·m−1] |
Notes |
---|---|---|---|---|
Acrylic glass (Plexiglas V045i) | 0.17[3]-0.19[3]-0.2[4] | 296[3] | 7.143E-15[3] - 5.0E-14[3] | Note: There are no negative conductivities and the symbols that could be read that way are hyphens to separate various estimates and measurements. |
Air and thin air and high tech vacuums, macrostructure | 0.024[5][23][25]-0.025[6] 0.0262 (1 bar)[26] 0.0457 (1 bar)[26] Formula values d=1 centimeter Standard Atmospheric Pressure 0.0209 0.0235 0.0260 List[27] 0.1 atmosphere 0.0209 0.0235 0.0260 0.01 atmospheres 0.0209 0.0235 0.0259 0.001 atmospheres 0.0205 0.0230 0.0254 0.0001 atmospheres 0.0178 0.0196 0.0212 10−5atmospheres 0.00760 0.00783 0.00800 10−6atmospheres 0.00113 0.00112 0.00111 10−7atmospheres 0.000119 0.000117 0.000115 List [28] |
273[23][25]-293[6]-298[5] 300[26] 600[26] 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 |
hiAerosols2.95[29]-loAerosols7.83[29]×10−15 | (78.03%N2,21%O2,+0.93%Ar,+0.04%CO2) (1 atm) The plate distance is one centimeter, the special conductivity values were calculated from the Lasance approximation formula in The Thermal conductivity of Air at Reduced Pressures and Length Scales[28] and the primary values were taken from Weast at the normal pressure tables in the CRC handbook on page E2.[27] Let K0 is the normal conductivity at one bar (105 N/m2) pressure, Ke is its conductivity at special pressure and/or length scale. Let d is a plate distance in meters, P is an air pressure in Pascals (N/m2), T is temperature Kelvin, C is this Lasance constant 7.6 ⋅ 10−5 m ⋅ K/N and PP is the product P ⋅ d/T. The Lasance approximation formula is Ke/K0 = 1/(1+C/PP). Some readers might find the notation confusing since the original mK might be interpreted as milliKelvins when it is really meter-Kelvins. He(Lasance?) puts a one (1) at the end of his equation so that it appears like this: Ke/K0 = 1/(1+C/PP)(1). Eventually you can find out from his graph that the (1) at the end is not part of his formula and instead he is citing his graph. |
Air and thin air and high tech vacuums, microstructure | Formula Values d=1 millimeter Standard Atmospheric Pressure 0.0209 0.0235 0.0260 0.1 atmosphere 0.0209 0.0235 0.0259 0.01 atmospheres 0.0205 0.0230 0.0254 0.001 atmospheres 0.0178 0.0196 0.0212 0.0001 atmospheres 0.00760 0.00783 0.00800 10−5 atmospheres 0.00113 0.00112 0.00111 10−6 atmospheres 0.000119 0.000117 0.000115 10−7 atmospheres 0.0000119 0.0000117 0.0000116 List[28] |
233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 233.2 266.5 299.9 |
All values calculated from the Lasance formula: Lasance, Clemens J., "The Thermal Conductivity of Air at Reduced Pressures and Length Scales," Electronics Cooling, November 2002.[28] Plate separation = one millimeter. | |
Air, standard air | 0.00922 0.01375 0.01810 0.02226 0.02614 0.02970 0.03305 0.03633 0.03951 0.0456 0.0513 0.0569 0.0625 0.0672 0.0717 0.0759 0.0797 0.0835 0.0870 List, TPRC 3, pp 511–12[19] |
100 150 200 250 300 350 400 450 500 600 700 800 900 1000 1100 1200 1300 1400 1500 |
If maybe there is any big difference between wet air and dry air then it was not known to the Thermophysical Properties Research Center in Indiana where they never talked about the thermal conductivity of the air in Galveston Oh Galveston. This is their standard air. Volume 3, pp 511–12.[19] | |
Air, typical air | 30°N January Sea Level: 0.02535 1000 meters: 0.02509 2000 meters: 0.02483 3000 meters: 0.02429 30°N July Sea Level: 0.02660 1000 meters: 0.02590 2000 meters: 0.02543 3000 meters: 0.02497 60°N January Sea Level: 0.02286 1000 meters: 0.02302 2000 meters: 0.02276 3000 meters: 0.02250 List USSAS pp 103, 107 &123[30] |
288.52 285.25 281.87 275.14 304.58 295.59 289.56 283.75 257.28 259.31 256.08 252.85 |
TPRC standard air is very nearly equivalent to typical air worldwide. | |
Air, wet air | ≈Typical Air | Unlike a school bus driver in New England who is quite sure that cold wet air is colder than cold dry air the USGS has a thermal conductivity where it goes W/(m⋅K) and also an interface heat transfer coefficient which has W/(m2⋅K) and all of this sort of business would lead you to think that by the time they get all done the creditable conductivities are probably those that had been measured through interfaces of negligible consequence. Robertson Page 92[31] | ||
Air in motor windings at normal pressure, Lasance approximations | 360 Kelvins 10−2 meters: 0.03039 10−3 meters: 0.03038 10−4 meters: 0.03031 10−5 meters: 0.02959 List, TPRC Vol 3 page 512.[19][28] |
360 |
Lasance approximations are hardly significant in heat transfer through motor windings. Another investigator has reported some high values for the thermal conductivity of some metal air laminates both varnished and otherwise. See Taylor, T.S., Elec. World Vol 76 (24), 1159–62, 1920 in TPRC Data Series Vol 2, pp 1037–9.[32] | |
Alcohols or oils | 0.1[5][6]-0.110[33]-0.21[5][6]-0.212[33] | 293[6]-298[5]-300[33] | ||
Aluminium,[34] alloy | Mannchen 1931: 92% Aluminum, 8% Magnesium Cast L 72.8 100.0 126.4 139.8 Annealed L 76.6 104.6 120.1 135.6 88%Aluminium, 12% Magnesium Cast 56.1 77.4 101.3 118.4 Mever-Rassler 1940: 93.0% Aluminium, 7.0% Magnesium 108.7 List[8] |
87 273 373 476 87 273 373 476 87 273 373 476 348.2 |
Mannchen, W., Z Metalik..23, 193–6, 1931 in TPRC Volume 1 pages 478, 479 and 1447.
Mever-Rassler. The Mever-Rassler alloy has a density of 2.63 g cm−1. Mever-Rassler, F., Metallwirtschaft. 19, 713–21, 1940 in Volume 1 pages 478, 479 and 1464.[8] | |
Aluminium,[34] pure | 204.3[35]-205[23]-220[36]-237[6][15][37][38]-250[5] 214.6[35] 249.3[35] CRC Aluminum 99.996+% Pure Aluminum 780 1550 2320 3080 3810 4510 5150 5730 6220 6610 6900 7080 7150 7130 7020 6840 6350 5650 4000 2850 2100 1600 1250 1000 670 500 400 340 300 247 237 235 236 237 240 240 237 232 226 220 213 List[27] |
293[6][35]-298[5][15][38] 366[35] 478[35] 1 2 3 4 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 |
37,450,000[38] - 37,740,000[39]
Cryogenic: up to 1.858 ⋅ 1011 at 4.2 K.[40][8] Formula Values |
This material is superconductive (electrical) at temperatures below 1.183 Kelvins. Weast page E-78[27] |
Aluminum,[34] ultrapure | TPRC Aluminum 99.9999% Pure Aluminum 4102 8200 12100 15700 18800 21300 22900 23800 24000 23500 22700 20200 17600 11700 7730 3180[?] 2380 1230 754 532 414 344 302 248 237 236 237 240 237 232 226 220 213 List[8] |
1 2 3 4 5 6 7 8 9 10 11 13 15 20 25 30 40 50 60 70 80 90 100 150 200 273.2 300 400 500 600 700 800 900 |
These are not measured values.
Very high thermal conductivity measurements up to 22,600 w m−1 K−1 were reported by Fenton, E.W., Rogers, J.S. and Woods, S.D. in some journal of Physics which has its name blurred up in reference 570 on page 1458, 41, 2026–33, 1963. The data is listed on pages 6 through 8 and graphed on page 1 where Fenton and company are on curves 63 and 64. Next the government smoothed out the curve and their recommended values are listed and graphed on page 9. Thermophysical Properties Research Center. Performing Organization: Purdue University. Controlling Organization: Defense Logistics Agency. Documented summaries from numerous scientific journals, etc. and critical estimates. 17000 pages in 13 volumes. | |
Aluminium nitride | 170[37]-175[42]-190[42] | 293[42] | 1×10 −11[42] | |
Aluminium oxide | Pure 26[43]-30[6]-35[43]-39[37]-40[44] NBS, Ordinary 27 16 10.5 8.0 6.6 5.9 5.6 5.6 6.0 7.2 List[45] Slip Cast R 11.1 10.0 8.37 7.95 6.90 5.86 5.65 5.65 5.65 List: Kingery, TPRC II page 99 curve 7 ref.5[32] Sapphire R 15.5 13.9 12.4 10.6 8.71 8.04 7.68 7.59 7.61 7.86 8.13 8.49 List: Kingery, TPRC II page 96 curve 19 ref.72[32] |
293[6][43][44] 400 600 800 1000 1200 1400 1600 1800 2000 2200 613.2 688.2 703.2 873.2 943.2 1033.2 1093 1203.2 1258.2 591.5 651.2 690.2 775.2 957.2 1073.2 1173.2 1257.2 1313.2 1384.2 14X9.2 1508.2 |
1×10 −12-[43][44] | The NBS recommended ordinary values are for 99.5% pure polycrystalline alumina at 98% density.[45] Slip Cast Values are taken from Kingery, W.D., J. Am Ceram. Soc., 37, 88–90, 1954, TPRC II page 99 curve 7 ref. 5 page 1159.[32] Sapphire values are taken from Kingery, W.D. and Norton, F.H., USAEC Rept. NYO-6447, 1–14, 1955, TPRC II pages 94, 96, curve 19 ref. 72 page 1160.[32] Errata: The numbered references in the NSRDS-NBS-8 pdf are found near the end of the TPRC Data Book Volume 2 and not somewhere in Volume 3 like it says.[32] |
Aluminium oxide, porous | 22% Porosity 2.3[45] | Constant 1000-1773[45] | This is number 54 on pages 73 and 76. Shakhtin, D.M. and Vishnevskii, I.I., 1957, interval 893-1773 Kelvins.[45] | |
Ammonia, saturated | 0.507[33] | 300[33] | ||
Argon | 0.016[5]-0.01772[15]-0.0179[15][46] | 298[5][15]-300[15][46] | ||
Basalt | Stephens Basalt Sample NTS No. 1 R 1.76 1.62 1.80 1.84 1.63 1.84 1.58 1.92 1.84 Sample NTS No. 2 R 1.36 1.45 1.53 1.67 1.72 1.57 1.60 1.63 List[32] Robertson Basalt 5% olivine, 100% solidity* & 5MPa pressure Intrinsic: K = 2.55 W ⋅ m−1 ⋅ K−1 Air in Pores: K =1.58 Water in Pores: K = 1.97 List: Robertson pages 7, 11 & 13.[31] |
576 596 658 704 748 822 895 964 1048 442 483 529 584 623 711 762 858 300 |
These measurements of two samples of NTS Basalt were credited to some D.R. Stephens, USAEC UCRL — 7605, 1–19, 1963. They are reported in the TPRC Data Series in Volume 2 on pages 798 and 799.
Stephens Basalt is two rocks and Robertson Basalt is one kind of rock. If you combined Robertson with his recommended lists of mineral conductivities then you would get formulas to calculate the thermal conductivities of most all the rocks in the world at every porosity over wide intervals of temperature and pressure. Unfortunately his lists are not available for free and for example his Horai list cost $42.00 on the internet: Ki-iti Horai, Thermal conductivity of Rock Forming minerals, Journal of Geophysical Research, Volume 76, Issue 5, pages 1278 — 1308, February 10, 1971.
| |
Beryllium oxide | 218[37]-260[47]-300[47] TPRC Recommended 424 302 272 196 146 111 87 70 57 47 39 33 28.3 24.5 21.5 19.5 18.0 16.7 15.6 15.0 List[32] |
293[47] 200 273.2 300 400 500 600 700 800 900 1000 1100 1200 1300 1400 1500 1600 1700 1800 1900 2000 |
1×10 −12[47] | Recommended values are found on page 137 of volume 2, TPRC Data Series, 1971[32] |
Bismuth | 7.97[15] | 300[15] | ||
Brass Cu63% | 125[48] | 296[48] | 15,150,000[48] - 16,130,000[48] | (Cu63%, Zn37%) |
Brass Cu70% | 109[23][49] - 121[49] | 293[23]-296[49] | 12,820,000[49] - 16,130,000[49] | (Cu70%, Zn30%) |
Brick | 0.15[23]-0.6[23]-0.69[5]-1.31[5] British 2016: Inner leaf (1700 kg/m3): 0.62[50] Outer leaf (1700 kg/m3): 0.84[50] 1920s Values: Brick #1: 0.674[32] Brick #2: 0.732[32] |
293[23]-298[5] 373.2[32] 373.2[32] |
Brick #1: 76.32% SiO2, 21.96%Al2O3, 1.88%Fe2O3 traces of CaO and MgO, commercial brick, density 1.795 g ⋅ cm−3. Brick #2: 76.52%SiO2, 13.67%Al2O3, 6.77%Fe2O3, 1.77%CaO, 0.42%MgO, 0.27%MnO, no specified density. Judging from the descriptions the TPRC has put the wrong labels on their bricks, and if that is the case then Brick #1 is "Common Brick" and Brick #2 is "Red Brick." Tadokoro, Y., Science Repts. Tohoku Imp. Univ., 10, 339–410, 1921, TPRC pages 493 & 1169.[32] | |
Bronze | 26[36] 42[51]-50[35][51] |
293[35]-296[51] | 5,882,000[51] - 7,143,000[51] |
Sn25%[36] (Cu89%, Sn11%)[51] |
Calcium silicate | 0.063[52] | 373[52] | ||
Carbon dioxide | 0.0146[5]-0.01465[53]-0.0168[46] (sat. liquid 0.087[54]) | 298[5]-273[53]-300[46] (293[54]) | ||
Carbon nanotubes, bulk | 2.5 (multiwall)[55] - 35 (single wall, disordered mats)[55] - 200(single wall, aligned mats)[55] | 300[55] | "bulk" refers to a group of nanotubes either arranged or disordered, for a single nanotube, see "carbon nanotube, single".[55] | |
Carbon nanotube, single | 3180 (multiwall)[56][57]-3500 (single wall)[58] (SWcalc.6,600[56][59]-37,000[56][59]) |
320[56][57]-300[58] (300[56][59]-100[56][59]) |
(Lateral)10−16[60] - (Ballistic)108[60]) | values only for one single SWNT(length:2.6 μm, diameter:1.7 nm) and CNT. "Single", as opposed to "bulk" quantity (see "carbon nanotubes, bulk" ) of many nanotubes, which should not be confused with the denomination of nanotubes themselves which can be singlewall(SWNT) or multiwall(CNT)[55] |
Cerium dioxide | 1.70 1.54 1.00 0.938 0.851 0.765 List: TPRC II pp. 145–6[32] |
1292.1 1322.1 1555.9 1628.2 1969.2 2005.9 |
Pears, C.D., Project director, Southern Res. Inst. Tech. Documentary Rept. ASD TDR-62-765, 20-402, 1963. TPRC Vol 2, pages 145, 146 and 1162[32] | |
Concrete | 0.8[23] - 1.28[6] - 1.65[61] - 2.5[61] | 293[6] | ~61-67%CaO | |
Copper, commercial | Wright, W. H., M. S. Thesis: Sample 1 L 423 385 358 311 346 347 350 360 Sample 2 L 353 360 366 363 365 Lists: TPRC I page 75 curve 129[8] Taga, M., periodical First run: 378 Second run: 374 Third run: 378 Fourth run: 382 List: TPRC I page 75 curve 129[8] |
80.06 95.34 115.62 135.53 159.46 181.56 198.35 217.30 198.53 220.90 240.88 257.38 275.40 363.2 363.2 363.2 363.2 |
Wright, W. H., M. S. Thesis, Georgia Institute of Technology, 1–225, 1960. TPRC Data Series Volume 1, pages 75 and 80 curve 129, ref. page 1465.[8] Taga, commercial grade, 99.82% purity, density 8.3 g⋅cm−3. Taga, M., [Bull?], Japan Soc. Mech. Engrs., 3 (11) 346–52, 1960. TPRC Data Series Vol 1, pages 74, 79 and 1459.[8] | |
Copper, pure | 385[23]-386[35][36]-390[6]-401[5][15][16] 368.7[35] 353.1[35] 1970s values: TPRC (American) 2870 13800 19600 10500 4300 2050 1220 850 670 570 514 483 413 401 398 392 388 383 377 371 364 357 350 342 334 List[8] The Soviet Union 403[62] 1960s Values Thin Copper Foil*: 126.8 202.3 295.9 400.2 List[63][8] |
293[5][6][15][16][23][35] 573[35] 873[35] 1 5 10 20 30 40 50 60 70 80 90 100 200 273 300 400 500 600 700 800 900 1000 1100 1200 1300 273.15 0.427 0.671 0.981 1.322 |
59,170,000[16] - 59,590,000[39] Formula Values: 6.37 ⋅ 107 at 273.15 K; 5.71 ⋅ 107 at 300K; 4.15 ⋅ 107 at 400K.[41] |
International Annealed Copper Standard (IACS) pure =1.7×10−8Ω•m =58.82×106Ω−1•m−1 For main article, see: Copper in heat exchangers. The TPRC recommended values are for well annealed 99.999% pure copper with residual electrical resistivity of ρ0=0.000851 μΩ⋅cm. TPRC Data Series volume 1 page 81.[8]
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Cork | 0.04[23] - 0.07[6] 1940s values: Density=0.195 g cm−3 L 0.0381 0.0446 Density=0.104 g cm−3 L 0.0320 0.0400 List: Rowley, F.B. and others in TPRC II page 1064 & 1067 curves 1 & 3 ref 109.[32] |
293[6] --- 222.0 305.5 222.0 305.5 |
1940s values are for oven dried cork at specified densities: Rowley, F.B., Jordan, R.C. and Lander, R.M., Refrigeration Engineering, 53, 35–9. 1947, TPRC pages 1064, 1067 & 1161.[32] | |
Cotton or Plastic Insulation-foamed | 0.03[5][6] | 293[6] | ||
Diamond, impure | 1,000[23][64] | 273[64] - 293[23] | 1×10 −16~[65] | Type I (98.1% of Gem Diamonds) (C+0.1%N) |
Diamond, natural | 2,200[66] | 293[66] | 1×10 −16~[65] | Type IIa (99%12C and 1%13C) |
Diamond, isotopically enriched | 3,320[66]-41,000[56][67] (99.999% 12C calc.200,000[67]) | 293[66]-104[56][67] (~80[67]) | (Lateral)10−16[65] - (Ballistic)108[65] | Type IIa isotopically enriched (>99.9%12C) |
Dolomite, NTS dolomite | Specimen No. 1 R 1.08 1.14 Specimen No. 2 R 1.27 1.26 List TPRC 2 pp 811–12.[32] |
521 835 523 833 |
Specimen No. 1 had a fine-grained appearance; 2.25 inches O.D.. 0.375 in. I.D., 12 in. long; obtained from exploratory dolomite hole No. 1, dolomite hill at level of 200 feet; density 2.80 g cm−3. Method: Radial heat flow [TPRC Volume 1 page 23a].
Stephens, D. R., USAEC UCRL — 7605. 1–19, 1963 in TPRC Data Series Volume 2, pp. 811–12.[32] | |
Epoxy, thermally conductive | 0.682[68] - 1.038 - 1.384[69] - 4.8[70] | |||
Eclogite | Roberston Eclogite, 5MPa 0.6437 0.2574 List from graph: Roberston page 39[31] |
373 573 |
Some more recent measurements about ecolgite at high pressures and elevated temperatures (up to 14GPa and 1000K) have been reported by Chao Wang and others in a 2014 article about omphacite, jadeite and diopside which is free on the internet[71] | |
Ethylene glycol | TPRC 0.2549 0.2563 0.2576 0.2590 0.2603 0.2616 0.2630 0.2643 List[32] CRC 0.2645 0.2609 0.2695 List[27] |
280 290 300 310 320 330 340 350 288.15 293.15 353.15 |
The TPRC values are posted in Volume 3 on page 177 and the CRC estimates are found in the handbook on page E-4. | |
Expanded polystyrene – EPS | 0.03[5]-0.033[5][23][64] ((PS Only)0.1[72]-0.13[72]) | 98[64]-298[5][64] (296[72]) | 1×10 −14[72] | (PS+Air+CO2+CnH2n+x) |
Extruded polystyrene – XPS | 0.029 - 0.39 | 98-298 | ||
Fat | Beef fat 0.354 0.175 Bone fat 0.186 Pig fat 0.238 List[32] |
293.2 333.2 293.2 293.2 |
The fats were found out by Lapshin A. and Myasnaya Ind., SSSR. Volume 25 (2) pp. 55–6, 1954. and reported in volume two of the TPRC Data Series on page 1072.[32] | |
Fiberglass or foam-glass | 0.045[6] | 293[6] | ||
Gabbro | Sligachan Gabbro 2.55 2.47 List[32] Generic Gabbro* 2.06 ± 0.2 List: Birch and Clark in Robertson page 31[31] |
309.4 323.1 300 |
Specimen 5 cm in diameter and 2 cm long from Sligachan Skye, density 3.1 g ⋅ cm−1. Nancarrow, H.A., Proc. Phys. Soc. (London) 45, page 447–61, 1933 in TPRC Data Series Volume 2 page 816.[32]
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Gallium arsenide | 56[64] | 300[64] | ||
Gasket | Cardboard 0.210[73] Transite P 0.770 0.757 0.749 0.742 0.739 0.736 0.736 0.736 0.733 0.731 List: Smith, W.K. in TPRC II page 1107 curve 1 ref 390.[32] |
291.15 338.7 366.5 394.3 422.1 449.8 477.6 505.4 533.2 560.9 588.7 |
The cardboard is in Yarwood and Castle on page 36 and the Transite is credited to some W.K. Smith who sounds like a secret agent since the rest of his credit is NOTS TP2624, 1 — 10, 1961. [AD 263771]. In any case Transite was found out in 1961 and it is some sort of asbestos — cement board with a density of 0.193 — 0.1918 grams⋅cm−1. TPRC Data Series, Volume 2, page 1107[32]
For rubber gasket see Rubber. | |
Glass | 0.8[23]-0.93[6] (SiO2pure1[37]-SiO296%1.2[74]-1.4[74]) Pyrex 7740, Air Force, 1961 P 1.35 1.34 1.39 1.42 1.59 1.45 1.43 1.56 1.66 1.68 1.91 1.90 List: TPRC II pages 926-9 curve 81[32] Pyrex 7740, NBS, 1963 L 1.11 1.16 1.22 1.27 1.33 1.38 1.43 List: TPRC II pages 926-9 curve 76[32] Pyrex 7740, NBS, 1966 0.58 0.90 1.11 1.25 1.36 1.50 1.62 1.89 List[75] |
293[6][23][74] 297 300 306 319 322 322 329 330 332 336 345 356 273.2 323.2 373.2 423.2 473.2 523.2 573.2 100 200 300 400 500 600 700 800 |
<1% Iron oxides In 1966 Pyrex 7740 had a composition of about 80.6% SiO2, 13% B2O3, 4.3% Na2O and 2.1% Al2O3.[75] Similar glasses have a coefficient of linear expansion of about 3 parts per million per Kelvin at 20°Celsius.[76] Density [Pyrex 774] ≈ 2.210 g ⋅ cm−3 at 32 °F. Specific heats: 0.128, 0.172, 0.202, 0.238, 0.266, 0.275 Cal. g−1 K−1 at 199.817, 293.16, 366.49, 477.60, 588.72 & 699.83 Kelvins respectively. Lucks, C.F., Deem, H.W. and Wood, W.D. in TPRC V pages 1232-3[77] Errata: The numbered references in the NSRDS-NBS-8 pdf are found near the end of the TPRC Data Book Volume 2 and not somewhere in Volume 3 like it says.[32] | |
Glycerol | 0.285[33]-0.29[6] | 300[33]-293[6] | ||
Gold, pure | 314[23]-315[35]-318[15][36][78] 1970s values: 444 885 2820 1500 345 327 318 315 312 309 304 298 292 285 List[8] |
293[35]-298[15][78] 1 2 10 20 100 200 273.2 300 400 500 600 700 800 900 |
45,170,000[39] - 45,450,000[78] | 1970s values are found on page 137, TPRC Data Series volume 1 (1970).[8] |
Granite | 1.73[20] - 3.98[20] Nevada Granite R 1.78 1.95 1.86 1.74 1.80 Scottish Granite L 3.39 3.39 List[32] Westerly Granite 2.4(63) 2.2(83) 2.1(44) Barre Granite 2.8(23) 2.5(18) 2.3(10) Rockport-1* 3.5(57) 3.0(31) 2.7(12) Rockport-2* 3.8(07) 3.2(11) 2.8(37) List: Birch and Clark in Robertson page 35.[31] |
368 523 600 643 733 306.9 320.2 273.15 373.15 473.15 273.15 373.15 473.15 273.15 373.15 473.15 273.15 373.15 473.15 |
(72%SiO2+14%Al2O3+4%K2O etc.) Scottish Granite: This is granite from May Quarry in Aberdeenshire. Nancarrow, H. A., Proc. Phys. Soc. (London). 45, 447–61, 1933, TPRC II pages 818 and 1172.[32] Nevada Granite: This granite is 34%v plagioclase, 28%v ortheoclase, 27%v quartz and 9%v biotite. Stephens, D. R., USAEC UCRL-7605, 1–19, 1963, TPRC II pages 818 and 1172.[32] A 1960 report on the Nevada granite (Izett, USGS) is posted on the internet but the very small numbers there are hard to understand.[79]
| |
Granite, ΔP | Barre Granite* Wet 50 bar* 2.8 2.5 2.3 2.1 1000 bar 3.2 2.8 2.6 2.4 5000 bar 4.5 4.0 3.7 3.4 Dry 50 bar 2.8(23) 2.5(18) 2.3(10) 2.1(44) 1000 bar 2.8(76) 2.5(65) 2.3(53) 2.1(84) 5000 bar 3.0(91) 2.7(57) 2.5(29) 2.3(47) List: Robertson pages 35, 59-61[31] |
273.15 373.15 473.15 573.15 273.15 373.15 473.15 573.15 273.15 373.15 473.15 573.15 273.15 373.15 473.15 573.15 273.15 373.15 473.15 573.15 273.15 373.15 473.15 573.15 |
Granite pillars small enough to put in your coat pocket have failed under loads that averaged out to about 1.43 ⋅ 108 Newtons/meter2 and this kind of rock has a sonic speed of about 5.6 ± 0.3 ⋅ 103 m/sec (stp), a density of about 2.7 g/cm3 and specific heat ranging from about 0.2 to 0.3 cal/g °C through the temperature interval 100-1000 °C [Stowe pages 41 & 59 and Robertson pages 70 & 86].[80][31]
| |
Graphene | (4840±440)[81] - (5300±480)[81] | 293[81] | 100,000,000[82] | |
Graphite, natural | 25-470[83] 146-246 (longitudinal), 92-175 (radial)[84] |
293[83] | 5,000,000-30,000,000[83] | |
Grease, thermally conductive greases | 860 Silicone Heat Transfer Compound: 0.66 8616 Super Thermal Grease II: 1.78 8617 Super thermal Grease III: 1.0 List, MG Chemicals[85] |
233.15—473.15 205.15—438.15 205.15—438.15 |
These thermal greases have low electrical conductivity and their volume resistivities are 1.5⋅1015, 1.8⋅1011, and 9.9⋅109 Ω⋅cm for 860, 8616 and 8617 respectively. | The thermal grease 860 is a silicone oil with a Zinc Oxide filler and 8616 and 8617 are synthetic oils with various fillers including Aluminum Oxide and Boron Nitride. At 25 °C the densities are 2.40, 2.69 and 1.96 g/mL for the greases 860, 8616 and 8617 respectively. |
Helium II | ≳100000[86] in practice, phonon scattering at solid-liquid interface is main barrier to heat transfer. | 2.2 | liquid Helium in its superfluid state below 2.2 K | |
House | American 2016 Wood Product Blow-in, Attic Insulation 0.0440 − 0.0448[87] FIBERGLAS Blow-in, Attic Insulation 0.0474 − 0.0531[88] PINK FIBERGLAS Flexible Insulation 0.0336 − 0.0459[89] British CONCRETE: General 1.28 (2300 kg/m3) 1.63 (2100 kg/m3 typical floor) 1.40 (2000 kg/m3 typical floor) 1.13 (medium 1400 kg/m3)0.51 (lightweight 1200 kg/m3) 0.38 (lightweight 600 kg/m3) 0.19 (aerated 500 kg/m3) 0.16 PLASTER: (1300 kg/m3) 0.50 (600 kg/m3) 0.16 TIMBER: Timber (650 kg/m3) 0.14 Timber flooring (650 kg/m3) 0.14 Timber rafters 0.13 Timber floor joists 0.13 MISC.: Calcium silicate board (600 kg/m3) 0.17 Expanded polystyrene 0.030 −0.038 Plywood (950 kg/m3) 0.16 Rock mineral wool 0.034 −0.042 List[50] Wallboard, see Wallboard. 1960s Values Dry Zero − Kapok between burlap or paper density 0.016 g cm−3, TC=0.035 W⋅m−1K−1 Hair Felt − Felted cattle hair density 0.176 g cm−3, TC=0.037 W⋅m−1K−1 density 0.208 g cm−3, TC=0.037 W⋅m−1K−1 Balsam Wool − Chemically treated wood fibre density 0.035 g cm−3, TC=0.039 W⋅m−1K−1 Hairinsul − 50% hair 50% jute density 0.098 g cm−3, TC=0.037 W⋅m−1K−1 Rock Wool − Fibrous material made from rock density 0.096 g cm−3, TC=0.037 W⋅m−1K−1 density 0.160 g cm−3, TC=0.039 W⋅m−1K−1 density 0.224 g cm−3, TC=0.040 W⋅m−1K−1 Glass Wool − Pyrex glass curled density 0.064 g cm−3, TC=0.042 W⋅m−1K−1 density 0.160 g cm−3, TC=0.042 W⋅m−1K−1 Corkboard − No added binder density 0.086 g cm−3, TC=0.036 W⋅m−1K−1 density 0.112 g cm−3, TC=0.039 W⋅m−1K−1 density 0.170 g cm−3, TC=0.043 W⋅m−1K−1 density 0.224 g cm−3, TC=0.049 W⋅m−1K−1 Corkboard − with asphaltic binder density 0.232 g cm−3, TC=0.046 W⋅m−1K−1 Cornstalk Pith Board: 0.035 − 0.043 Cypress density 0.465 g cm−3, TC=0.097 W⋅m−1K−1 White pine density 0.513 g cm−3, TC=0.112 W⋅m−1K−1 Mahogany density 0.545 g cm−3, TC=0.123 W⋅m−1K−1 Virginia pine density 0.545 g cm−3, TC=0.141 W⋅m−1K−1 Oak density 0.609 g cm−3, TC=0.147 W⋅m−1K−1 Maple density 0.705 g cm−3, TC=0.159 W⋅m−1K−1 List[90] |
American 2016: Flexible insulation from Owens Corning includes faced and unfaced rolls of glass wool and with foil.[89] 1960s values: All thermal conductivities from Cypress to Maple are given across the grain.[90] | ||
Hydrogen | 0.1819[91] | 290 | Hydrogen gas at room temperature. | |
Ice | 1.6[23]-2.1[6]-2.2[64]-2.22[92] The Historic Ice Authorities van Duser 1929 2.09 2.161 2.232 2.303 2.374 2.445 Choi & Okos/Bonales 1956 — 2017 2.2199 2.3854 2.6322 2.9603 3.3695 3.8601 Ratcliffe/Bonales 1962 — 2017 2.0914 2.2973 2.5431 2.8410 3.2086 3.6723 List[93] Clark, S.P. Jr., 1966* 2.092 2.552 List: Clark, S.P. Jr. in Robertson p. 58[31] |
293[6][23] - 273[64][92] 273.15 253.15 233.15 213.15 193.15 173.15 273.15 253.15 233.15 213.15 193.15 173.15 273.15 253.15 233.15 213.15 193.15 173.15 273.15 143.15 |
Bonales says that his posted formulas are lined up with his old authorities though more recent ones (and Bonales among them) have come to believe that ices that come to low temperatures remember a cooling rate.[94][93]
The formulas are: 1)van Duser: k=2.09(1-0.0017 T(°C)); 2)Choi & Okos: k=2.2199-6.248 ⋅ 10−3 T(°C) + 1.0154 ⋅ 10−4 T(°C)2; 3)Ratcliffe: k=2135 T(K)-1.235. k is given in w ⋅ m−1 ⋅ K−1. Errata: Contrary to what they say the formula of Bonales and Sanz cannot be fitted to their data and also it is not consistent with the results of Choi and Okos since their formula is a typo and also Choi and Okos did not cook up a linear function to start with. Instead the formula that would fit some of the Bonales data is k ≈ 2.0526 - 0.0176TC and not k = -0.0176 + 2.0526T as they say on page S615 and also the values they posted for Alexiades and Solomon do not fit the other formula that they posted on table 1 on page S611 and the formula that would fit over there is k = 2.18 - 0.01365TC and not k = 2.18 - 0.01365TK.
| |
Indium phosphide | 80[64] | 300[64] | ||
Insulating firebrick | Sheffield Pottery, 2016: NC-23 0.19 0.20 0.23 0.26 NC-26 0.25 0.26 0.27 0.30 NC-28 0.29 0.32 0.33 0.36 List[95] 1940s Blast Furnace: 1.58 1.55 1.53 List[32] |
533 811 1089 1366 533 811 1089 1366 533 811 1089 1366 636.2 843.2 1036.2 |
Sheffield pottery: Standard ASTM 155 Grades, 05/10/2006: NC-23, Cold Crushing Strength=145 lbs/inch2, density=36 lbs/ft3 NC-26, Cold Crushing Strength=220 lbs/inch2, density=46 lbs/ft3 NC-28, Cold Crushing Strength=250 lbs/inch2, density=55 lbs/ft3 [95] --- 1940s Blast Furnace: Kolechkova, A. F. and Goncharov, V. V., Ogneupory, 14, 445–53, 1949, TPRC pages 488, 493 & 1161.[32] | |
Iron, pure | 71.8[36]-72.7[35]-79.5[23]-80[5]-80.2[64]-80.4[15][96] 55.4[35] 34.6[35] TPRC 149 224 297 371 442 513 580 645 705 997 814 555 372 265 204 168 146 132 94 83.5 80.3 69.4 61.3 54.7 48.7 43.3 38.0 32.6 29.7 29.9 27.9 28.2 29.9 30.9 31.8 List[8] The Soviet Union 86.5[62] |
293[23][35]-298[5]-300[15][64][96] 573[35] 1273[35] 2 3 4 5 6 7 8 9 10 20 30 40 50 60 70 80 90 100 200 273.2 300 400 500 600 700 800 900 1000 1100 1183 1183 1200 1300 1400 1500 273.15 |
9,901,000[96] - 10,410,000[39] | The TPRC recommended values are for well annealed 99.998% pure iron with residual electrical resistivity of ρ0=0.0327 μΩ⋅cm. TPRC Data Series volume 1 page 169.[8] |
Iron, cast | 55[5][36] Tadokoro Cast Iron* White 12.8 13.3 14.3 14.5 17.3 Grey 29.5 29.7 30.0 30.1 31.1 List: Tadokoro, curves 39 & 40 in TPRC Vol. I, pp 1130–31[8] Donaldson Cast Iron* 48.5 48.1 46.9 47.3 46.9 46.0 List: Donaldson, curve 1 in TPRC Vol. I, pp 1129 & 1131[8] |
298[5] 303.2 323.2 362.2 373.2 425.2 303.2 323.2 361.2 373.2 427.2 353.70 376.70 418.20 429.70 431.70 447.20 |
(Fe+(2-4)%C+(1-3)%Si)
Apart from a thermal conductivity a boiler company also has an interface heat transfer coefficient Q and also some Kurganov has posted this simplification that water flowing in tubes has Q ≈ 500 - 1200 W/(m2K).[97]
By comparison the Donaldson Iron is 2.80% C, 0.10% Mn, 0.061% P, 0.093% S and 0.39% Si. It has 0.76% graphitic carbon and 2.04% combined carbon and the thermal conductivity measurements come with a 2% error estimate. Tadokoro, Y., J., Iron Steel Inst. (Japan), 22, 399 — 424, 1936 and Donaldson, J.W., J. Iron Steel Inst. (London), 128, p. 255-76, 1933. | |
Laminates, metal non-metal | Taylor I 30 varnished silicon steel foils each of thickness 0.014 inches (0.356 mm): density 7.36 g cm−3; measured near a temperature of 358.2 K under pressure in the range 0 — 132 psi: 0 psi 0.512 w m−1 K−1 20 psi 0.748 40 psi 0.846 60 psi 0.906 80 psi 0.925 100 psi 0.965 120 psi 0.992 132 psi 1.02 120 psi 1.00 100 psi NA* 80 psi 0.984 60 psi 0.945 40 psi 0.906 20 psi 0.846 0 psi 0.591 Taylor II 30 varnished silicon steel foils each of thickness 0.0172 inches (0.4368 mm); density 7.51 g cm−3; measured near a temperature of 358.2 K under pressure in the range 0 — 128 psi: 0 psi 0.433 w m−1 K−1 20 psi 0.807 40 psi 0.965 60 psi 1.04 80 psi 1.10 100 psi 1.18 120 psi 1.24 128 psi 1.26 120 psi 1.26 100 psi 1.22 80 psi 1.18 60 psi 1.14 40 psi 1.10 20 psi 0.984 0 psi 0.630 Taylor III 30 silicon steel foils each of thickness 0.0172 inches (0.4368 mm); density 7.79 g cm−3; measured near a temperature of 358.2 K under pressure in the range 0 — 125 psi: 0 psi 0.496 w m−1 K−1 10 psi 0.748 22.5 psi 0.945 125 psi 1.65 100 psi 1.59 80 psi 1.54 47 psi 1.38 20 psi 1.14 0 psi 0.709 List: Taylor, T.S., Elec. World, 76 (24), 1159 — 62, 1920.[32] |
*The report in the Data Series says that the Taylor I laminate had a thermal conductivity of 0.0996 w cm−1 K−1 at 100 psi in descent and that is an obvious typo [NA]. What would fit is 0.00996 w cm−1 K−1 = 0.996 w m−1 K−1. TPRC Volume 2, pp 1037–9. | ||
Lead, pure | 34.7[23][35]-35.0[5][36]-35.3[15][98] 29.8[35] TPRC 2770 4240 3400 2240 1380 820 490 320 230 178 146 123 107 94 84 77 66 59 50.7 47.7 45.1 43.5 39.6 36.6 35.5 35.2 33.8 32.5 31.2 List[8] The Soviet Union 35.6[62] |
293[23][35]-298[5]-300[15][98] 573[35] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 18 20 25 30 40 50 100 200 273.2 300 400 500 600 273.15 |
4,808,000[39] - 4,854,000[98] | The TPRC List is the TPRC estimate for well annealed Lead of 99.99+% purity and residual electrical resistivity ρ0=0.000880 μΩ cm. TPRC Data Series Volume 1, page 191.[8] This material is superconductive (electrical) at temperatures below 7.193 Kelvins. Weast page E-87.[27] |
Limestone | 1.26[20] - 1.33[20] Indiana Limestone R 1.19 1.21 1.19 1.11 1.12 1.07 1.03 0.62 0.57 0.54 List[99] Queenstone Grey L 1.43 1.41 1.40 1.33 List1.43[32] Generic Limestone R* Air in Pores Solidity = 1.0: K = 2.67* Solidity = 0.9: K = 2.17 Solidity = 0.8: K = 1.72 Solidity = 0.7: K = 1.32 Water in Pores Solidity = 1.0: K = 2.97 Solidity = 0.9: K = 2.52 Solidity = 0.8: K = 2.12 Solidity = 0.7: K = 1.77 List: Robertson formula 6 and page 10&16.[31] |
---- 472 553 683 813 952 1013 1075 1181 1253 1324 395.9 450.4 527.6 605.4 300 |
Mostly CaCO3 and the "Indiana Limestone" is 98.4% CaCO3, 1% quartz and 0.6% hematite.[99] By comparison Queenstone Grey is a mixture of dolomite and calcite containing 22% MgCO2. Density=2.675 g cm−3. Niven, C.D., Can J. Research, A18, 132–7, 1940, TPRC pages 821 and 1170.[32]
| |
Manganese | 7.81[5] | lowest thermal conductivity of any pure metal | ||
Marble | 2.07[20]-2.08[5]-2.94[5][20] | 298[5] | ||
Methane | 0.030[5]-0.03281[100] | 298[5]-273[100] | ||
Mineral wool insulation | 0.04[5][6][23] | 293[6]-298[5] | ||
Nickel | 90.9[15]-91[5] | 298[5][15] | ||
Nitrogen, pure | 0.0234[23]-0.024[5]-0.02583[15]-0.026[46][64] | 293[23]-298[5]-300[15][46][64] | (N2) (1 atm) | |
Norite | 2.7 ± 0.4 List: Misener and others in Robertson page 31.[31] |
300 | This summary came from five samples in 1951. | |
Oxygen, pure (gas) | 0.0238[23]-0.024[5]-0.0263[46]-0.02658[15] | 293[23]-298[5]-300[15][46] | (O2) (1 atm) | |
Oil | Transformer Oil CRC Oil Regular 0.177 Light Heat 0.132 List[101] Yarwood and Castle 0.135[73] |
343.15 — 373.15 303.15 — 373.15 273.15 |
Yarwood and Castle have their transformer oil on page 37. | |
Paper | Ordinary Paper Engineeringtoolbox 0.05[5] Yarwood and Castle 0.125[73] Oil Impregnated Paper 0.180 — 0.186[32] |
298[5] 291.15 294.7 — 385.2 |
The oil-impregnated paper was about 0.05 inches thick and it was loaded under about 2 PSI. TPRC Volume 2, page 1127. Yarwood and Castle has the thermal conductivity of their paper on page 36 | |
Perlite, (1 atm) | 0.031[5] | 298[5] | ||
Perlite in partial vacuum | 0.00137[5] | 298[5] | ||
Pine | 0.0886 0.0913 0.0939 0.0966 0.0994 0.102 List[32] |
222.0 238.7 255.4 272.2 288.9 305.5 |
Density=0.386 g cm−3. Rowley, F. B., Jordan, R. C. and Lander, R. M., Refrigeration Engineering, 53, 35–9, 1947, TPRC pages 1083 and 1161.[32] | |
Plastic, fiber-reinforced | 0.23[102] - 0.7[102] - 1.06[6] | 293[6] - 296[102] | 10−15[102] - 100[102] | 10-40%GF or CF |
Polyethylene, high-density | 0.42[5] - 0.51[5] | 298[5] | ||
Polymer, high-density | 0.33[102] - 0.52[102] | 296[102] | 10−16[102] - 102[102] | |
Polymer, low-density | 0.04[102] - 0.16[6] - 0.25[6] - 0.33[102] | 293[6] - 296[102] | 10−17[102] - 100[102] | |
Polyurethane foam | 0.03[5] | 298[5] | ||
Porcelain, electrical porcelain | 1940s Values Sample 1 1.90 — 2.27 Sample 2 1.40 — 2.15 Sample 3 1.84 — 2.24 |
388.2 — 1418.2 395.2 — 1456.2 385.2 — 1396.2 |
Starting material was 19.0 flint, 37.0 feldspar, 7.0 Edgar plastic kaolin, 22.0 Edgar Nocarb clay, and 15.0 Kentucky old mine No. 4 ball clay, ball milled for 15 hours, slip cast and fired to 1250 °C; 25% open pores; bulk density 2.5 g ⋅ cm−3. Norton, F.H. and Kingery, W.D., USAEC Rept. NYO — 601, 1 — 52, 1943 in TPRC Vol. 2 page 937[32] | |
Propylene glycol | 0.2007[27] | 293.15 — 353.15 | This hearsay value is posted in the 48th Edition of the Handbook of Chemistry and Physics on page E-4.[27] | |
Pyroxenite | 4.3 ± 0.1 List: Birch and Clark in Robertson, page 31.[31] |
300 | This summary came from 2 samples in 1940. | |
Quartz, single crystal | 12[64] [math]\displaystyle{ \parallel }[/math] to c axis, 06.8[64] [math]\displaystyle{ \perp }[/math] to c axis Rutgers University 11.1 [math]\displaystyle{ \parallel }[/math] to c axis, 5.88 [math]\displaystyle{ \perp }[/math] to c axis 9.34 [math]\displaystyle{ \parallel }[/math] to c axis, 5.19 [math]\displaystyle{ \perp }[/math] to c axis 8.68 [math]\displaystyle{ \parallel }[/math] to c axis, 4.50 [math]\displaystyle{ \perp }[/math] to c axis List[103] NBS 6.00 [math]\displaystyle{ \parallel }[/math] to c axis, 3.90 [math]\displaystyle{ \perp }[/math] to c axis 5.00 [math]\displaystyle{ \parallel }[/math] to c axis, 3.41 [math]\displaystyle{ \perp }[/math] to c axis 4.47 [math]\displaystyle{ \parallel }[/math] to c axis, 3.12 [math]\displaystyle{ \perp }[/math] to c axis 4.19 [math]\displaystyle{ \parallel }[/math] to c axis, 3.04 [math]\displaystyle{ \perp }[/math] to c axis List[104] |
300 311 366 422 500 600 700 800 |
The noted authorities have reported some values in three digits as cited here in metric translation but they have not demonstrated three digit measurement.[105] Errata: The numbered references in the NSRDS-NBS-8 pdf are found near the end of the TPRC Data Book Volume 2 and not somewhere in Volume 3 like it says.[32] | |
Quartz, fused, or vitreous silica, or fused silica | 1.46[106]-3[6] 1.4[64] England 0.84 1.05 1.20 1.32 1.41 1.48 List[107] America 0.52 1.13 1.23 1.40 1.42 1.50 1.53 1.59 1.73 1.92 2.17 2.48 2.87 3.34 4.00 4.80 6.18 List[104] |
293[6][106] 323[64] 123 173 223 273 323 373 100 200 223 293 323 373 400 500 600 700 800 900 1000 1100 1200 1300 1400 |
1.333E-18[108] - 10−16[106] | |
Quartz, powdered | Kozak 1952 0.184 0.209 0.230 0.259 Sinel'nikov 1958 0.0289 0.0335 0.0356 0.041 0.0448 0.0515 0.0669 0.0753 0.0812 0.0837 List: TPRC II pages 177-180[32] |
373.2 483.2 588.2 673.2 313.2 373.2 473.2 571.2 617.2 667.2 713.2 811.2 863.2 868.2 |
Kozak grain sizes ranged from 0.3 to 1 mm diameter and the density was 0.54 grams ⋅ cm−3. Kozak, M.I. Zhur. Tekh. Fiz., 22 (1), 73–6, 1952. By comparison Sinel'nikov powder is a powder in a vacuum, gran sizes range from 100-200 micrometers, the powder density is 1.35 g per cm−3. Sinel'nikov, N.N. and Filipovich, V.N., Soviet Phys. Tech., 3, 193-6, 1958. The TPRC record is blurred up some on the Sinel'nikov vacuum which looks like it is probably 5 ⋅ 10−5 mmHg.
TPRC pages 177-180, Volume 2, curves 62 and 65, Reference numbers 326 and 327 respectively.[32] | |
Quartz, slip-cast | First Run 0.34 0.39 0.45 0.51 0.62 Second Run 0.63 0.66 0.69 List[109] |
500 700 900 1100 1300 900 1000 1100 |
This material which must have started out like unfired pottery was slip cast from fused silica. Then it was dried four days at 333 K before being tested. It was 9 inches in diameter and 1 inch thick, density 1.78 ⋅ cm−3. The first run went to 1317K and then on the second run the same insulator proved to be more conductive. 1959.[109] | |
Redwood bark | Whole: Density=0.0641 g cm−3 L 0.0286 0.0307 0.0330 0.0356 0.0379 0.0407 Shredded: Density=0.0625 g cm−3 L 0.0107 List[32] |
222.2 239.2 255.5 272.1 288.8 305.3 318.7 |
Whole: Rowley, F. B., Jordan, R. C. and Lander, R. M., Refrig. Eng., 50, 541–4, 1945, TPRC pages 1084 & 1172.[32] Shredded: Wilkes, G. B., Refrig. Eng., 52, 37–42, 1946, TPRC pages 1084 & 1162.[32] | |
Rice hulls (ash) | 0.062[110] | |||
Rice hulls (whole) | 0.0359[110] | |||
Rock, felsic igneous | Air in Pores, 5 MPa* Solidity* = 1 20%v Quartz: 2.21 40%v Quartz: 2.97 60%v Quartz: 3.72 Solidity = 0.9 20%v Quartz: 1.80 40%v Quartz: 2.41 60%v Quartz: 3.02 Water in Pores, 5 MPa Solidity = 1 20%v Quartz: 2.83 40%v Quartz: 4.14 60%v Quartz: 5.46 Solidity = 0.9 20%v Quartz: 2.41 40%v Quartz: 3.47 60%v Quartz: 4.54 List: Formula values (6), page 10, Robertson.[31] |
300 | *5 MPa is 5 ⋅ 106 Pascals or 5 ⋅ 106 Newtons per meter2 or about fifty atmospheres pressure. *Solidity ≡ the ratio of the volume of solid to the bulk volume, or the ratio of bulk density to solid grain density dB/dG. Symbols: %v is percent by volume. | |
Rock, mafic igneous | Air in Pores, 5 MPa Solidity = 1 0 %v OPA*: 1.50 5 %v OPA : 1.58 10%v OPA: 1.65 20%v OPA: 1.80 30%v OPA: 1.95 Solidity = 0.9 0 %v OPA : 1.25 5 %v OPA : 1.31 10%v OPA: 1.37 20%v OPA: 1.49 30%v OPA: 1.62 Water in Pores, 5 MPa Solidity = 1 0 %v OPA : 1.84 5 %v OPA : 1.96 10%v OPA: 2.09 20%v OPA: 2.34 30%v OPA: 2.59 Solidity = 0.9 0 %v OPA : 1.63 5 %v OPA : 1.73 10%v OPA: 1.83 20%v OPA: 2.04 30%v OPA: 2.24 List: Formula values (6), page 10, Robertson.[31] |
300 | *OPA is olivine, pyroxene and/or amphibole in any proportions. | |
Rubber | CRC Rubber, 92%, nd 0.16[64] Griffiths Natural Rubber 1923 0.134 Hayes Synthetic Rubbers 1960 Thiokel ST 0.268 Kel-F 3700 0.117 0.113 0.113 0.113 Carboxy Rubber, Firestone butaprene T 0.255 0.238 0.197 List Griffiths and Hayes curves 11, 41, 43 & 56 in TPRC II pp 981–984[32] |
303[64] 298.2 310.9 310.9 422.1 477.6 533.2 310.9 422.1 477.6 |
1×10 −13~[108] | The Listed Synthetic Rubbers and more of them in the data collection are credited to Hayes, R.A., Smith, F.M., Kidder, G.A., Henning, J.C., Rigby, J.D. and Hall, G.L., WADC TR 56-331 (Pt.4), 1–157, 1960 [AD 240 212].[32] |
Sand, Hudson River | 0.27 List: Robertson page 58[31] |
303.15 | This sample has a density of 1.36 g/cm3. | |
Sandstone | 1.83[20] - 2.90[20] 2.1[111] - 3.9[111] |
~95-71%SiO2 ~98-48%SiO2, ~16-30% Porosity | ||
Silica aerogel | 0.003[64] (carbon black9%~0.0042[112])-0.008[112]-0.017[112]-0.02[5]-0.03[64] | 98[64] - 298[5][64] | Foamed glass | |
Silver, pure | 406[23]-407[35]-418[36] 427[37]-429[5][15][64][113]-430[15] 1970s values: TPRC 3940 7830 17200 16800 5100 1930 1050 700 550 497 471 460 450 432 430 428 427 420 413 405 397 389 382 List[8] The Soviet Union 429[62] |
293[23][35] 298[5][15][113]-300[15][64] 1 2 5 10 20 30 40 50 60 70 80 90 100 150 200 273.2 300 400 500 600 700 800 900 273.15 |
61,350,000[113] - 63,010,000[39] | Highest electrical conductivity of any metal TPRC recommended values are for well annealed 99.999% pure silver with residual electrical resistivity of ρ0=0.000620 μΩ⋅cm. TPRC Data Series volume 1 page 348 (1970).[8] |
Silver, sterling | 361[114] | |||
Snow, dry | 0.05[5]-0.11[23]-0.25[5] | 273[5] | ||
Sodium chloride | 35.1 - 6.5 - 4.85[115] | 80 - 289 - 400[115] | ||
Soil, dry with organic matter | 0.15[6][116]-1.15[116]-2[6] | 293[6] | composition may vary | |
Soil, saturated | 0.6[6]-4[6] | 293[6] | composition may vary | |
Soils, temperate | Andersland Soils Sandy Soils Dry Density= 1200 kg ⋅ meter−3 20% Saturation: K= 0.90 W ⋅ m−1 ⋅ K−1 40% Saturation: K= 1.05 60% Saturation: K= 1.15 80% Saturation: K= 1.20 Dry Density= 1400 kg ⋅ meter−3 20% Saturation: K= 1.09 40% Saturation: K= 1.30 60% Saturation: K= 1.44 80% Saturation: K= 1.54 Dry Density= 1600 kg ⋅ meter−3 20% Saturation: K= 1.29 40% Saturation: K= 1.58 60% Saturation: K= 1.76 80% Saturation: K= 1.88 Dry Density= 1800 kg ⋅ meter−3 20% Saturation: K= 1.50 40% Saturation: K= 1.90 60% Saturation: K= 2.15 80% Saturation: K= 2.31 Silt and Clay Soils Dry Density= 1200 kg ⋅ meter−3 20% Saturation: K= 0.54 W ⋅ m−1 ⋅ K−1 40% Saturation: K= 0.76 60% Saturation: K= 0.90 80% Saturation: K= 1.00 Dry Density= 1400 kg ⋅ meter−3 20% Saturation: K= 0.59 40% Saturation: K= 0.86 60% Saturation: K= 1.04 80% Saturation: K= 1.15 Dry Density= 1600 kg ⋅ meter−3 20% Saturation: K= 0.61 40% Saturation: K= 1.00 60% Saturation: K= 1.23 80% Saturation: K= 1.39 Dry Density= 1800 kg ⋅ meter−3 20% Saturation: K= 0.65 40% Saturation: K= 1.08 60% Saturation: K= 1.39 80% Saturation: K= 1.62 Charts: Andersland and Anderson in Farouki, figures 152 page 106 and 148 on page 104[117] de Vries Soils Mineral; density 2.65 g cm−3: K = 2.93 Organic; density 1.3 g cm−3: K = 0.251 Soil, mineral, dry; density 1.50 g cm−3: K = 0.209 Soil, mineral, saturated; density 1.93 g cm−3: K = 2.09 Soil, organic, dry; density 0.13 g cm−3: K = 0.033 Soil, organic, sat.; density 1.03 g cm−3: K = 0.502 List[118] Higashi Soil With Water r* Loose Packed r = 0.0: K= 0.255 W ⋅ m−1 ⋅ K−1 r = 0.2: K= 0.534 r = 0.4: K= 0.883 r = 0.6: K= 1.162 Close Packed r = 0.0: K= 0.372 r = 0.2: K= 0.697 r = 0.4: K= 1.127 r = 0.6: K= 1.627 List: Higashi, Akira; Hokkaido University Library[119] Kersten Soils Silt-Clay Soils 1.28 grams ⋅ cm−3 dry 50% Saturation: K = 0.89 W ⋅ m−1 ⋅ K−1 100% Saturation: K = 1.1 1.44 grams ⋅ cm−3 dry 50% Saturation: K = 1.0 100% Saturation: K = 1.3 1.60 grams ⋅ cm−3dry 50% Saturation: K = 1.2 100% Saturation: K = 1.5 Sandy Soil 1.60 grams ⋅ cm−3 dry 50% Saturation: K = 1.7 W ⋅ m−1 ⋅ K−1 100% Saturation: K = 2.0 List: Kersten in Farouki, figures 146 & 150, pp. 103 & 105[120] |
293.2 277.59 |
The cited Andersland Charts include corresponding water content percentages for easy measurements. The TPRC Data Book has been quoting de Vries with values of 0.0251 and 0.0109 W⋅cm−3⋅Kelvin−1 for the thermal conductivities of organic and dry mineral soils respectively but the original article is free at the website of their cited journal. Errors: TPRC Volume 2 pages 847 and 1159.[32] Journal archives.[118] Also some de Vries authorities include John Webb, "Thermal Conductivity of Soil" November 1956, Nature Volume 178, pages 1074–1075, and M.W. Makowski, "Thermal Conductivity of Soil" April 1957, Nature Volume 179, pages 778-779 and more recent notables include Nan Zhang Phd and Zhaoyu Wang PhD "Review of soil thermal conductivity and predictive models" July 2017, International Journal of Thermal Sciences Volume 117 pages 172–183.
| |
Soils, frozen, below saturation | Higashi Soils Soil A, Black cultivated, 0 — 10 cm deep Dry: K = 0.488 W ⋅ m−1 ⋅ K−1 Saturated: K = 3.151 Soil B, Brown subsoil, 25 — 30 cm deep Dry: K = 0.232 Saturated: K = 2.604 Soil C, Yellow brown subsoil, 50 — 60 cm deep Dry: K = 0.290 Saturated: K = 2.279 List: Higashi, Hokkaido University Library[121] Kersten Soils Sandy Soil 1.60 grams ⋅ cm−3 dry 50% Saturation: K = 1.7 W ⋅ m−1 ⋅ K−1 100% Saturation: K > 3.17 List: Kersten in Farouki, figure 151 page 105.[120] |
268.15 ± 2K 269.26 |
Higashi anomalies: The very high c values that are labeled as thermal conductivities in table III on page 100 would roughly fit the thesis of the paper if they came with lower orders of magnitude. The way that the dry soils get a lot lighter between Table I on page 99 and table IV on pages 102-3 is eventually explained by the fact that Table I has pycnometer densities.
For those who may already see reasons to learn more about the thermal conductivities of the soils it is free from the Army Cold Regions Research and Engineering Laboratory. The whole thing is on the Farouki reference footnote[120] and it comes with graphs and with formulas. To make it easier a lb/ft3 is about 0.01601846 grams/cm3 and a Btu in./ft2 hr °F is about 0.14413139 W ⋅ m−1 ⋅ K−1. | |
Soils, frozen, above saturation | Higashi Soils Soil A r* = 0.7: K = 3.953 W ⋅ m−1 ⋅ K−1 Soil B r = 0.8: K = 3.348 List[121] |
268.15 ± 2K | In this sample of two there is one very dirty kind of ice that conducts heat at nearly twice the rate of plain ice. *r ≡ The ratio of the water mass to the dried mass. | |
Solder, Sn/63% Pb/37% | 50[122] | |||
Lead-free solder, Sn/95.6% Ag/3.5% Cu/0.9%, Sn/95.5% Ag/3.8% Cu/0.7% (SAC) | ~60[122] | |||
Steel, carbon | 36[35][36]-43[5] 50.2[23]-54[5][35][36] Intermediate British Steels, 1933 CS 81: 0.1% C, 0.34% Mn 67.4 66.1 64.9 CS 91: 0.26% C, 0.61% Mn 56.1 55.2 54.4 CS 92: 0.44% C, 0.67% Mn 54.0 52.7 51.9 List: Naeser, G. in TPRC I pp 1186–90, curves 81, 91 and 92[8] Tool Steel, 1.41% C, 0.23% Mn, 0.158% Si L Water Quenched 30.5 31.0 31.8 Tempered at 150°C and air cooled 32.2 32.2 32.8 Tempered at 200°C and air cooled 33.1 33.9 33.5 Tempered at 250°C and air cooled 36.8 36.4 37.2 Tempered at 300°C and air cooled 37.7 38.5 38.1 Tempered at 350°C and air cooled 38.1 38.5 38.9 List: Hattori, D., J. Iron Steel Inst. (London) 129 (1), 189–306, 1934 in TPRC I pp 1115–1120 curves 61-66[8] |
293[23][35]-298[5] 373.2 473.2 573.2 373.2 473.2 573.2 373.2 473.2 573.2 355.70 374.20 390.20 360.70 376.70 389.70 366.20 401.70 427.20 364.20 395.70 424.70 365.70 393.20 427.20 369.20 390.70 432.20 |
(Fe+(1.5-0.5)%C) | |
Steel, stainless | 16.3[36][123]-16.7[124]-18[125]-24[125] | 296[123][124][125] | 1,176,000[124] - 1,786,000[125] | (Fe, Cr12.5-25%, Ni0-20%, Mo0-3%, Ti0-trace) |
Styrofoam-expanded polystyrene | Dow Chemical 0.033-0.036[126] K. T. Yucel et al. 0.036-0.046[17] |
|||
Syenite | 2.18 List: Birch and Clark in Robertson page 58[31] |
300 | This summary came from one sample in 1940. | |
Thermal grease | ||||
Thermal tape | 0.60[127] | |||
Thorium dioxide | 3.68 3.12 2.84 2.66 2.54 List[32] |
1000 1200 1400 1600 1800 |
Recommended values, TPRC, Polycrystaline, 99.5% pure, 98% dense, page 198[32] | |
Tin | TPRC 20400[math]\displaystyle{ \perp }[/math]to the c axis, 14200 [math]\displaystyle{ \parallel }[/math] to the c axis, 18300 P* 36000[math]\displaystyle{ \perp }[/math]to the c axis, 25000 [math]\displaystyle{ \parallel }[/math] to the c axis, 32300 P 33100[math]\displaystyle{ \perp }[/math]to the c axis, 23000 [math]\displaystyle{ \parallel }[/math] to the c axis, 29700 P 20200[math]\displaystyle{ \perp }[/math]to the c axis, 14000 [math]\displaystyle{ \parallel }[/math] to the c axis, 18100 P 13000[math]\displaystyle{ \perp }[/math]to the c axis, 9000 [math]\displaystyle{ \parallel }[/math] to the c axis, (11700) P 8500[math]\displaystyle{ \perp }[/math]to the c axis, 5900 [math]\displaystyle{ \parallel }[/math] to the c axis, (7600) P 5800[math]\displaystyle{ \perp }[/math]to the c axis, 4000 [math]\displaystyle{ \parallel }[/math] to the c axis, (5200) P 4000[math]\displaystyle{ \perp }[/math]to the c axis, 2800 [math]\displaystyle{ \parallel }[/math] to the c axis, (3600) P 2900[math]\displaystyle{ \perp }[/math]to the c axis, 2010 [math]\displaystyle{ \parallel }[/math] to the c axis, (2600) P 2150 [math]\displaystyle{ \perp }[/math]to the c axis, 1490 [math]\displaystyle{ \parallel }[/math] to the c axis, (1930) P 1650[math]\displaystyle{ \perp }[/math]to the c axis, 1140[math]\displaystyle{ \parallel }[/math] to the c axis, (1480) P 1290[math]\displaystyle{ \perp }[/math]to the c axis, 900 [math]\displaystyle{ \parallel }[/math] to the c axis, (1160) P 1040[math]\displaystyle{ \perp }[/math]to the c axis, 20 [math]\displaystyle{ \parallel }[/math] to the c axis, (930) P 850 [math]\displaystyle{ \perp }[/math]to the c axis, 590 [math]\displaystyle{ \parallel }[/math] to the c axis, (760) P 700 [math]\displaystyle{ \perp }[/math]to the c axis, 490 [math]\displaystyle{ \parallel }[/math] to the c axis, (630) P 590 [math]\displaystyle{ \perp }[/math]to the c axis, 410 [math]\displaystyle{ \parallel }[/math] to the c axis, (530) P 450 [math]\displaystyle{ \perp }[/math]to the c axis, 310 [math]\displaystyle{ \parallel }[/math] to the c axis, (400) P 360 [math]\displaystyle{ \perp }[/math]to the c axis, 250 [math]\displaystyle{ \parallel }[/math] to the c axis, (320) P 250 [math]\displaystyle{ \perp }[/math]to the c axis, 172 [math]\displaystyle{ \parallel }[/math] to the c axis, (222) P 200 [math]\displaystyle{ \perp }[/math]to the c axis, 136* [math]\displaystyle{ \parallel }[/math] to the c axis, (176) P 167 [math]\displaystyle{ \perp }[/math]to the c axis, 116 [math]\displaystyle{ \parallel }[/math] to the c axis, (150) P (150)[math]\displaystyle{ \perp }[/math]to the c axis, (104) [math]\displaystyle{ \parallel }[/math] to the c axis, (133) P (137)[math]\displaystyle{ \perp }[/math]to the c axis, (95) [math]\displaystyle{ \parallel }[/math] to the c axis, (123) P (128)[math]\displaystyle{ \perp }[/math]to the c axis, (89) [math]\displaystyle{ \parallel }[/math] to the c axis, (115) P (107)[math]\displaystyle{ \perp }[/math]to the c axis, (74) [math]\displaystyle{ \parallel }[/math] to the c axis, (96) P (98.0)[math]\displaystyle{ \perp }[/math]to the c axis, (68.0) [math]\displaystyle{ \parallel }[/math] to the c axis, (88.0) P (95.0)[math]\displaystyle{ \perp }[/math]to the c axis, (66.0) [math]\displaystyle{ \parallel }[/math] to the c axis, (85.0) P (86.7)[math]\displaystyle{ \perp }[/math]to the c axis, (60.2) [math]\displaystyle{ \parallel }[/math] to the c axis, (77.9) P (81.6)[math]\displaystyle{ \perp }[/math]to the c axis, (56.7) [math]\displaystyle{ \parallel }[/math] to the c axis, (73.3) P (75.9)[math]\displaystyle{ \perp }[/math]to the c axis, (52.7) [math]\displaystyle{ \parallel }[/math] to the c axis, 68.2 P (74.2)[math]\displaystyle{ \perp }[/math]to the c axis, (51.5) [math]\displaystyle{ \parallel }[/math] to the c axis, 66.6 P 69.3[math]\displaystyle{ \perp }[/math]to the c axis, 48.1 [math]\displaystyle{ \parallel }[/math] to the c axis, 62.2 P 66.4[math]\displaystyle{ \perp }[/math]to the c axis, 46.1 [math]\displaystyle{ \parallel }[/math] to the c axis, 59.6 P List[8] The Soviet Union 68.2[62] |
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 18 20 25 30 35 40 45 50 70 90 100 150 200 273.2 300 400 500 273.15 |
*The P Conductivity is the conductivity of polycrystalline Tin. TPRC Tin is well annealed 99.999+% pure white tin with residual electrical resistivity ρ0=0.000120, 0.0001272 & 0.000133 μΩ cm respectively for the single crystal along directions perpendicular [math]\displaystyle{ \perp }[/math] and parallel [math]\displaystyle{ \parallel }[/math] to the c axis and for polycrystalline tin P. The recommended values are thought to be accurate to within 3% near room temperature and 3 to [unintelligible] at other temperatures. Values in parentheses are extrapolated, interpolated, or estimated. *It happens that the online record has the thermal conductivity at 30 Kelvins and [math]\displaystyle{ \parallel }[/math] to the c axis posted at 1.36 W⋅cm−1 K−1 and 78.0 Btu hr−1 ft−1 F−1 which is incorrect. Also the copy is blurred up enough to give you the impression that maybe what it really means is 1.36 W−1 cm−1 K−1 and 78.6 Btu hr−1 ft−1 F−1 and a type-head that got overdue for its cleaning since the secretary had a tall heap of papers on her desk and if that is the case then the multilingual expression is perfectly consistent. TPRC Data Series Volume 1, page 408.[8] This material is superconductive (electrical) at temperatures below 3.722 Kelvins. Weast page E-75.[27] | |
Titanium, pure | 15.6[36]-19.0[35]-21.9[15][128]-22.5[35] | 293[35]-300[15][128] | 1,852,000[128] - 2,381,000[39] | |
Titanium alloy | 5.8[129] | 296[129] | 595,200[129] | (Ti+6%Al+4%V) |
Tungsten, pure | 173 1440 9710 208 173[130] 118 98[131] |
1 10 100 293[130] 1000 2000 |
18,940,000[130] | |
Wallboard (1929) | 0.0640 0.0581 0.0633 List[32] |
322.8 | Stiles, H., Chem. Met. Eng.,36, 625–6, 1929, TPRC Volume 2 pages 1131 and 1172. This is commercial wallboard in three samples of it at the same mean temperature.[32] | |
Water | 0.563[132]-0.596[132]-0.6[6][23]-0.609[33] Deionized ultra-filtered water 0.598[133] TPRC 0.5225* 0.5551* 0.5818 0.5918 0.6084 0.6233 0.6367 0.6485 0.6587 0.6673 0.6797 0.6864 0.6727 0.6348 0.5708 List[19] The Soviet Union 0.599[62] |
273[132]-293[6][23][132]-300[33] 293.15 250 270 280 290 300 310 320 330 340 350 370 400 450 500 550 293.15 |
5×Pure10−6[65]-Sweet10−3±1[65]-Sea1[132] | <4[132]%(NaCl+MgCl2+CaCl2) *The TPRC Estimates for water at 250K and 270K are for supercooled liquid. Of course the values for 400K and above are for water under steam pressure.[19] |
Water vapor | 0.016[5]-0.02479 (101.3 kPa)[134] 0.0471 (1 bar)[26] |
293[134]-398[5] 600[26] |
||
Wood, moist | +>=12% water: 0.09091[135]-0.16[64]-0.21[135]-0.4[6] The Royal Society: Fir L Specific gravity=0.6 15% moisture ⊥ to the grain U*: 0.117 Mahogany L Specific gravity=0.70 15% m & ⊥ to the grain R*: 0.167 15% m & ⊥ to the grain T*: 0.155 15% m & [math]\displaystyle{ \parallel }[/math] to the grain: 0.310 Oak L Specific gravity=0.60 14% m & ⊥ to the grain T: 0.117 Spruce: L Electric Oven 3.40% m & ⊥ to the grain R: 0.122 5.80% m & ⊥ to the grain R: 0.126 7.70% m & ⊥ to the grain R: 0.129 9.95% m & ⊥ to the grain R: 0.133 17.0% m & ⊥ to the grain R: 0.142 Specific gravity=0.041 16% m & ⊥ to the grain R: 0.121 16% m & ⊥ to the grain T: 0.105 16% m & [math]\displaystyle{ \parallel }[/math] to the grain: 0.222 Teak L Specific gravity=0.72 10% m & ⊥ to the grain T: 0.138 Walnut L Specific gravity=0.65 12.1% m & ⊥ to the grain R: 0.145 11.3% m & ⊥ to the grain T: 0.136 11.8% m & [math]\displaystyle{ \parallel }[/math] to the grain: 0.332 List[32] |
298[64]-293[6] 293.2 293.2 293.2 293.2 293.2 373.2 373.2 373.2 373.2 373.2 293.2 293.2 293.2 293.2 293.2 293.2 293.2 |
Species-Variable[135] The Royal Society: Griffiths, E. and Kaye, G. W. C., Proc. Roy. Soc. (London), A104, 71–98, 1923, TPRC Volume 2, pages 1073, 1080, 1082, 1086 and 1162.[32] *The R conductivity is the thermal conductivity radial to the annual rings, T is tangential to those rings and U is unspecified. Mahogany: page 1080, Oak: page 1082, Spruce: page 1086, Teak: page 1087, Walnut: page 1089. Method: Longitudinal Heat Flow, TPRC 1, page 24a.[8] Note: all the percentages refer to moisture. The Fir was measured at 15%, Mahogany, 15%, Oak, 14%, Spruce, 3.40%, 5.80%, 7.70%, 9.95%, 17.0% and 16%. Teak was measured at 10% and Walnut was measured at 12.1%, 11.3% and 11.8% moisture. | |
Wood, unspecified | 0.04[23]-0.055[5]-0.07692[135]-0.12[23]-0.17[5][135] The Royal Society Walnut L ⊥ to the grain & tangent to the annual rings, various pressures and thicknesses all 0.137 ± 0.001 twelve times over. Griffiths, E. and Kaye, G. W. C., Proc. Roy. Soc. (London), A104, 71–98, 1923 in TPRC 2 page 1089.[32] Various Pine, see Pine. Redwood Bark, see Redwood Bark. |
293[23]-298[5] 293.2 |
Balsa[5]-Cedar[135]-Hickory[135]/Oak[5] | |
Wool, Angora wool | 0.0464[32] | 293.2[32] | Bettini, T. M., Ric. Sci. 20 (4), 464–6, 1950, TPRC pages 1092 and 1172[32] | |
Wool felt | 0.0623[32] 0.0732[32] |
313.2[32] 343.2[32] |
Taylor, T. S., Mech. Eng., 42, 8–10, 1920, TPRC pages 1133 and 1161.[32] | |
Zinc, pure | 116[65] | 293[65] | 16,950,000[65] | |
Zinc oxide | 21[37] | |||
Zirconium dioxide | Slip Cast, first run (1950) 2.03 1.98 1.96 1.91 1.91 1.90 Second Run (1950) 1.81 1.80 1.92 1.90 1.95 1.92 1.97 1.98 2.04 2.29 CaO stabilized (1964) 1.54 1.64 1.64 1.76 1.62 1.79 1.80 2.46 2.33 2.80 2.56 2.70 List[32] |
766.2 899.2 1006.2 1090.2 1171.2 1233.2 386.2 470.2 553.2 632.2 734.2 839.2 961.2 1076.2 1163.2 1203.2 1343.2 1513.2 1593.2 1663.2 1743.2 2003.2 2103.2 2323.2 2413.2 2413.2 2493.2 2523.2 |
First Run: Density=5.35 g cm−3. Norton, F. H., Kingery, W. D., Fellows, D. M., Adams, M., McQuarrie, M. C. and Coble, R. L. USAEC Rept. NYO-596, 1–9, 1950, TPRC pages 247 and 1160[32] Second Run: Same Specimen, same USAEC Report.[32] CaO stabilized: Density=4.046 g cm−3 (66.3% of theoretical). Feith, A. D., Gen. Elec. Co., Adv. Tech. Service, USAEC Rept. GEMP-296, 1-25, 1964, TPRC pages 247 and 1165.[32] Some recent developments include Zirconia fibrous thermal insulation for temperatures up to about 2000 Kelvins. Various conductivities less than 0.4 w m−1 K−1. Zircar Zirconia, Inc.[136] http://hyperphysics.phy-astr.gsu.edu/hbase/Tables/thrcn.html<ref> | |
Material | Thermal conductivity [W·m−1·K−1] | Temperature [K] | Electrical conductivity @ 293 K [Ω−1·m−1] | Notes |
See also
- Laser flash analysis
- List of insulation materials
- R-value (insulation)
- Thermal transmittance
- Specific heat capacity
- Thermal conductivity
- Thermal conductivities of the elements (data page)
- Thermal diffusivity
- Thermodynamics
References
- ↑ "Metals, Metallic Elements and Alloys - Thermal Conductivities". Engineeringtoolbox.com. https://www.engineeringtoolbox.com/thermal-conductivity-metals-d_858.html. Retrieved 2022-03-15.
- ↑ Roger N. Wright (3 December 2010). Wire Technology: Process Engineering and Metallurgy. Elsevier. p. 281. ISBN 978-0-12-382093-8. https://books.google.com/books?id=YXp6zao0HqgC&pg=PA281.
- ↑ 3.0 3.1 3.2 3.3 3.4 3.5 www.goodfellow.com. "Polymethylmethacrylate - online catalogue source - supplier of research materials in small quantities - Goodfellow". http://www.goodfellow.com/E/Polymethylmethacrylate.html.
- ↑ 4.0 4.1 "Archived copy". http://www.plexiglas.com/tds/4b.pdf.
- ↑ 5.00 5.01 5.02 5.03 5.04 5.05 5.06 5.07 5.08 5.09 5.10 5.11 5.12 5.13 5.14 5.15 5.16 5.17 5.18 5.19 5.20 5.21 5.22 5.23 5.24 5.25 5.26 5.27 5.28 5.29 5.30 5.31 5.32 5.33 5.34 5.35 5.36 5.37 5.38 5.39 5.40 5.41 5.42 5.43 5.44 5.45 5.46 5.47 5.48 5.49 5.50 5.51 5.52 5.53 5.54 5.55 5.56 5.57 5.58 5.59 5.60 5.61 5.62 5.63 5.64 5.65 5.66 5.67 5.68 5.69 5.70 5.71 5.72 5.73 5.74 5.75 5.76 5.77 "Thermal Conductivity of common Materials and Gases". http://www.engineeringtoolbox.com/thermal-conductivity-d_429.html.
- ↑ 6.00 6.01 6.02 6.03 6.04 6.05 6.06 6.07 6.08 6.09 6.10 6.11 6.12 6.13 6.14 6.15 6.16 6.17 6.18 6.19 6.20 6.21 6.22 6.23 6.24 6.25 6.26 6.27 6.28 6.29 6.30 6.31 6.32 6.33 6.34 6.35 6.36 6.37 6.38 6.39 6.40 6.41 6.42 6.43 6.44 6.45 "Products & Services - Hukseflux Thermal Sensors". http://www.hukseflux.com/thermalScience/thermalConductivity.html.
- ↑ Material Properties Data: Alumina (Aluminium Oxide) . Makeitfrom.com. Retrieved on 2013-04-17.
- ↑ 8.00 8.01 8.02 8.03 8.04 8.05 8.06 8.07 8.08 8.09 8.10 8.11 8.12 8.13 8.14 8.15 8.16 8.17 8.18 8.19 8.20 8.21 8.22 8.23 8.24 8.25 8.26 8.27 Touloukian, Powell, Ho and Klemens, Purdue Research Foundation, TPRC Data Series Volume 1 (1970): http://www.dtic.mil/dtic/tr/fulltext/u2/a951935.pdf Retrieved 14:46 AM 15 May 2018 (CET).
- ↑ Cheng, Zhe; Koh, Yee Rui; Mamun, Abdullah; Shi, Jingjing; Bai, Tingyu; Huynh, Kenny; Yates, Luke; Liu, Zeyu; Li, Ruiyang; Lee, Eungkyu; Liao, Michael E.; Wang, Yekan; Yu, Hsuan Ming; Kushimoto, Maki; Luo, Tengfei; Goorsky, Mark S.; Hopkins, Patrick E.; Amano, Hiroshi; Khan, Asif; Graham, Samuel (2020). "Experimental observation of high intrinsic thermal conductivity of AlN". Physical Review Materials. 4 (4): 044602. arXiv:1911.01595. Bibcode:2020PhRvM...4d4602C. doi:10.1103/PhysRevMaterials.4.044602. S2CID 207780348.
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- ↑ Kang, Joon Sang; Li, Man; Wu, Huan; Nguyen, Huuduy; Hu, Yongjie (2018). "Experimental observation of high thermal conductivity in boron arsenide". Science 361 (6402): 575–578. doi:10.1126/science.aat5522. PMID 29976798. Bibcode: 2018Sci...361..575K.
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- ↑ Apart from maybe Neptunium (6.3 W/(m⋅K)) and Plutonium (6.74 W/(m⋅K)).
- ↑ 19.0 19.1 19.2 19.3 19.4 19.5 Touloukian, Powell, Ho and Klemens, Purdue Research Foundation, TPRC Data Series Volume 3 (1970)https://apps.dtic.mil/dtic/tr/fulltext/u2/a951937.pdf retrieved on February 2, 2019 at 5:34 AM EST.
- ↑ 20.0 20.1 20.2 20.3 20.4 20.5 20.6 20.7 20.8 Marble Institute of America (2 values are usually given: the highest and lowest test scores)
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- ↑ Zhou, You; Hyuga, Hideki; Kusano, Dai; Yoshizawa, Yu-ichi; Ohji, Tatsuki; Hirao, Kiyoshi (2015). "Development of high-thermal-conductivity silicon nitride ceramics". Journal of Asian Ceramic Societies 3 (3): 221–229. doi:10.1016/j.jascer.2015.03.003.
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- ↑ Stowe, Richard L., “Strength and Deformation Properties of Granite, Basalt, Limestone and Tuff at Various Loading Rates,” 1969, Army Engineer Waterways Experiment Station Vicksburg MS, AD0684358 at https://apps.dtic.mil/docs/citations/AD0684358 with full text at https://apps.dtic.mil/dtic/tr/fulltext/u2/684358.pdf retrieved February 9, 2019 at 6:45 PM EST.
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- ↑ 108.0 108.1 Cite error: Invalid
<ref>
tag; no text was provided for refs namedserway
- ↑ 109.0 109.1 Mason, C.R., Walton, J.D., Bowen, M.D. and Teague, W.T. (1959) in R.W.Powell, C.Y.Ho and P.E.Liley, Thermal Conductivity of Selected Materials, NSRDS-NBS 8, Issued 25 November 1966, pages 99, 103>Link Text
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- ↑ 118.0 118.1 de Vries, D. A. and Peck, A. J., "On the Cylindrical Probe Method of Measuring Thermal Conductivity With Special Reference to Soils. I. Extension of Theory and Discussion of Probe Characteristics," Australian Journal of Physics, 11 (2), [pp 255-71] page 262, 1958> http://www.publish.csiro.au/?act=view_file&file_id=PH580255.pdf. Retrieved 29 March 2016 at 9:17 PM (UTC).
- ↑ Higashi, Akira, On the Thermal Conductivity of Soil, Journal of the Faculty of Science, Hokkaido University, Series 2, Physics, 4_P21-28, 1951-02 at https://eprints.lib.hokudai.ac.jp/dspace/bitstream/2115/34185/1/4_P21-28.pdf retrieved January 26, 2019 at 12:08 AM, EST.
- ↑ 120.0 120.1 120.2 Farouki, Omar T., Thermal Properties of Soils, CRREL Monograph 81-1, U.S. Army Cold Regions Research and Engineering Laboratory, Hanover New Hampshire, December 1981 at https://babel.hathitrust.org/cgi/pt?id=uc1.31210018605970;view=1up;seq=3 retrieved January 28, 2019 at 2:19 AM EST.
- ↑ 121.0 121.1 Higashi, Akira, Thermal Conductivity of Frozen Soil, Journal of the Faculty of Science, Hokkaido University, Series 2, Physics 4_P95-106, 1952-3 at https://eprints.lib.hokudai.ac.jp/dspace/bitstream/2115/34198/1/4_P95-106.pdf retrieved January 26, 2019 at 12:12 AM EST.
- ↑ 122.0 122.1 "Thermal Conductivity-of Solders". 9 August 2006. http://electronics-cooling.com/2006/08/thermal-conductivity-of-solders/.
- ↑ 123.0 123.1 http://www.goodfellow.com/E/Stainless-Steel-AISI-302.html
http://www.goodfellow.com/E/Stainless-Steel-AISI-304.html
http://www.goodfellow.com/E/Stainless-Steel-AISI-310.html
http://www.goodfellow.com/E/Stainless-Steel-AISI-316.html
http://www.goodfellow.com/E/Stainless-Steel-AISI-321.html - ↑ 124.0 124.1 124.2 www.goodfellow.com. "Stainless Steel - 17-7PH - online catalogue source - supplier of research materials in small quantities - Goodfellow". http://www.goodfellow.com/E/Stainless-Steel-17-7PH.html.
- ↑ 125.0 125.1 125.2 125.3 www.goodfellow.com. "Stainless Steel - AISI 410 - online catalogue source - supplier of research materials in small quantities - Goodfellow". http://www.goodfellow.com/E/Stainless-Steel-AISI-410.html.
- ↑ "STYROFOAM : Declared Thermal Resistance". Dow. http://building.dow.com/eu/gbr/en/products/styrofoam/thermalresistance.htm.
- ↑ "3M™ Thermally Conductive Adhesive Transfer Tape 8805". 3M. 2015. http://solutions.3m.com/wps/portal/3M/en_US/Electronics_NA/Electronics/Products/Electronics_Product_Catalog/~/3M-Thermally-Conductive-Adhesive-Transfer-Tape-8805?N=8704987+3294001801&rt=rud.
- ↑ 128.0 128.1 128.2 www.goodfellow.com. "Titanium - online catalogue source - supplier of research materials in small quantities - Goodfellow". http://www.goodfellow.com/E/Titanium.html.
- ↑ 129.0 129.1 129.2 www.goodfellow.com. "Titanium/Aluminium/Vanadium - online catalogue source - supplier of research materials in small quantities - Goodfellow". http://www.goodfellow.com/E/Titanium-Aluminium-Vanadium.html.
- ↑ 130.0 130.1 130.2 Tungsten
- ↑ Inc., eFunda. "Thermal Conductivity: Tungsten". http://www.efunda.com/materials/elements/TC_Table.cfm?Element_ID=W.
- ↑ 132.0 132.1 132.2 132.3 132.4 132.5 "2.7.9 Physical properties of sea water". www.kayelaby.npl.co.uk/ - www.npl.co.uk/. http://www.kayelaby.npl.co.uk/general_physics/2_7/2_7_9.html.
- ↑ Dr. Cederkrantz, Daniel (11 February 2021). "Thermal Conductivity of Water". https://thermtest.se/thermal-conductivity-of-water.
- ↑ 134.0 134.1 "Thermal conductivity of saturated H2O and D2O", CRC Handbook, p. 6–4.
- ↑ 135.0 135.1 135.2 135.3 135.4 135.5 135.6 "Physical Properties and Moisture Relations of Wood". http://www.fpl.fs.fed.us/documnts/fplgtr/fplgtr113/ch03.pdf.
- ↑ https://zircarzirconia.com/technical-documents/thermal-conductivity-zircar-zirconia-fibrous-insulation/ retrieved January 19, 2019 at 4:49 AM EST.
Bibliography
- David R. Lide, ed (2003). CRC Handbook of Chemistry and Physics (84th ed.). Boca Raton, FL: CRC Press. ISBN 978-0-8493-0484-2. https://books.google.com/books?id=q2qJId5TKOkC.
External links
- aluminium profile
- Heat Conduction Calculator
- Thermal Conductivity Online Converter - An online thermal conductivity calculator
- Thermal Conductivities of Solders
- Thermal conductivity of air as a function of temperature can be found at James Ierardi's Fire Protection Engineering Site
- Non-Metallic Solids: The thermal conductivities of non-metallic solids are found in about 1286 pages in the TPRC Data Series volume 2 at the PDF link here (Identifier ADA951936): http://www.dtic.mil/docs/citations/ADA951936 with full text link https://apps.dtic.mil/dtic/tr/fulltext/u2/a951936.pdf retrieved February 2, 2019 at 10:15 PM EST.
- Gasses and Liquids: The thermal conductivities of gasses and liquids are found in the TPRC Data Series volume 3 at the PDF link here (Identifier ADA951937): http://www.dtic.mil/docs/citations/ADA951937 with full text link https://apps.dtic.mil/dtic/tr/fulltext/u2/a951937.pdf retrieved February 2, 2019 at 10:19 PM EST.
- Metals and Alloys: The thermal conductivities of metals are found in about 1595 pages in the TPRC Data Series volume 1 at the PDF link here: http://www.dtic.mil/docs/citations/ADA951935 with full text link https://apps.dtic.mil/dtic/tr/fulltext/u2/a951935.pdf retrieved February 2, 2019 at 10:20 PM EST.
- Specific Heat and Thermal Radiation: Primary sources are found in the TPRC data series volumes 4 — 9, links: https://apps.dtic.mil/dtic/tr/fulltext/u2/a951938.pdf, https://apps.dtic.mil/dtic/tr/fulltext/u2/a951939.pdf, https://apps.dtic.mil/dtic/tr/fulltext/u2/a951940.pdf, https://apps.dtic.mil/dtic/tr/fulltext/u2/a951941.pdf, https://apps.dtic.mil/dtic/tr/fulltext/u2/a951942.pdf and https://apps.dtic.mil/dtic/tr/fulltext/u2/a951943.pdf retrieved at various times February 2 and 3, 2019.
- Vacuums: Vacuums and various levels of vacuums and the thermal conductivities of air at reduced pressures are known at http://www.electronics-cooling.com/2002/11/the-thermal-conductivity-of-air-at-reduced-pressures-and-length-scales/ retrieved February 2, 2019 at 10:44 PM EST.
Original source: https://en.wikipedia.org/wiki/List of thermal conductivities.
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