Thermodynamic Properties
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Transcript of Thermodynamic Properties
Thermodynamic properties[edit]
Phase behavior
Triple point 273.16 K (0.01 °C), 611.73 Pa
Critical point 647 K (374 °C), 22.1 MPa
Std enthalpy change
of fusion, ΔfusHo6.01 kJ/mol
Std entropy change
of fusion, ΔfusSo22.0 J/(mol·K)
Std enthalpy change
of vaporization, ΔvapHo40.68 kJ/mol
Std entropy change
of vaporization, ΔvapSo118.89 J/(mol·K)
Std enthalpy change
of sublimation, ΔsubHo46.70 kJ/mol
Std entropy change
of sublimation, ΔsubSo130.9 J/(mol·K)
Molal freezing point constant −1.858 °C kg/mol
Molal boiling point constant 0.512 °C kg/mol
Solid properties
Std enthalpy change
of formation, ΔfHosolid
−291.83 kJ/mol
Standard molar entropy,
Sosolid
41 J/(mol K)
Heat capacity, cp
12.2 J/(mol K) at −200 °C
15.0 J/(mol K) at −180 °C
17.3 J/(mol K) at −160 °C
19.8 J/(mol K) at −140 °C
24.8 J/(mol K) at −100 °C
29.6 J/(mol K) at −60 °C
32.77 J/(mol K) at −38.3 °C
33.84 J/(mol K) at −30.6 °C
35.20 J/(mol K) at −20.8 °C
36.66 J/(mol K) at −11.0 °C
37.19 J/(mol K) at −4.9 °C
37.84 J/(mol K) at −2.2 °C
Liquid properties
Std enthalpy change
of formation, ΔfHoliquid
−285.83 kJ/mol
Standard molar entropy,
Soliquid
69.95 J/(mol K)
Heat capacity, cp
75.97 J/(mol K) at 0 °C
75.42 J/(mol K) at 10 °C
75.33 J/(mol K) at 20 °C
75.28 J/(mol K) at 25 °C
75.26 J/(mol K) at 30 °C
75.26 J/(mol K) at 40 °C
75.30 J/(mol K) at 50 °C
75.37 J/(mol K) at 60 °C
75.46 J/(mol K) at 70 °C
75.58 J/(mol K) at 80 °C
75.74 J/(mol K) at 90 °C
75.94 J/(mol K) at 100 °C
Gas properties
Std enthalpy change
of formation, ΔfHogas
−241.83 kJ/mol
Standard molar entropy,
Sogas
188.84 J/(mol K)
Heat capacity, cp
36.5 J/(mol K) at 100 °C
36.1 J/(mol K) at 200 °C
36.2 J/(mol K) at 400 °C
37.9 J/(mol K) at 700 °C
41.4 J/(mol K) at 1000 °C
Heat capacity, cv
27.5 J/(mol K) at 100 °C
27.6 J/(mol K) at 200 °C
27.8 J/(mol K) at 400 °C
29.5 J/(mol K) at 700 °C
33.1 J/(mol K) at 1000 °C
Heat capacity ratio,
γ = cp/cv
1.324 at 100 °C
1.310 at 200 °C
1.301 at 400 °C
1.282 at 700 °C
1.252 at 1000 °C
van der Waals' constantsa = 553.6 L2 kPa/mol2
b = 0.03049 liter per mole
Liquid physical properties[edit]
Temperature dependence of the surface tension of pure water
Temperature dependence of the density of ice and water
Velocity of sound in water
c in distilled water at 25 °C 1498 m/s
c at other temperatures[7] 1403 m/s at 0 °C
1427 m/s at 5 °C
1447 m/s at 10 °C
1481 m/s at 20 °C
1507 m/s at 30 °C
1526 m/s at 40 °C
1541 m/s at 50 °C
1552 m/s at 60 °C
1555 m/s at 70 °C
1555 m/s at 80 °C
1550 m/s at 90 °C
1543 m/s at 100 °C
Density [8]
0.99984 g/cm3 at 0 °C 0.98804 g/cm3 at 50 °C
0.99997 g/cm3 at 4 °C 0.98570 g/cm3 at 55 °C
0.99996 g/cm3 at 5 °C 0.98321 g/cm3 at 60 °C
0.99970 g/cm3 at 10 °C 0.98056 g/cm3 at 65 °C
0.99910 g/cm3 at 15 °C 0.97778 g/cm3 at 70 °C
0.99820 g/cm3 at 20 °C 0.97486 g/cm3 at 75 °C
0.99704 g/cm3 at 25 °C 0.97180 g/cm3 at 80 °C
0.99564 g/cm3 at 30 °C 0.96862 g/cm3 at 85 °C
0.99403 g/cm3 at 35 °C 0.96531 g/cm3 at 90 °C
0.99221 g/cm3 at 40 °C 0.96189 g/cm3 at 95 °C
0.99022 g/cm3 at 45 °C 0.95835 g/cm3 at 100 °C
Viscosity [9]
η = 1.7921 mPa·s (cP) at 0 °C η = 0.5494 mPa·s at 50 °C
η = 1.5188 mPa·s at 5 °C η = 0.5064 mPa·s at 55 °C
η = 1.3077 mPa·s at 10 °C η = 0.4688 mPa·s at 60 °C
η = 1.1404 mPa·s at 15 °C η = 0.4355 mPa·s at 65 °C
η = 1.0050 mPa·s at 20 °C η = 0.4061 mPa·s at 70 °C
η = 0.8937 mPa·s at 25 °C η = 0.3799 mPa·s at 75 °C
η = 0.8007 mPa·s at 30 °C η = 0.3635 mPa·s at 80 °C
η = 0.7225 mPa·s at 35 °C η = 0.3355 mPa·s at 85 °C
η = 0.6560 mPa·s at 40 °C η = 0.3165 mPa·s at 90 °C
η = 0.5988 mPa·s at 45 °C η = 0.2994 mPa·s at 95 °C
η = 0.2838 mPa·s at 100 °C
Surface tension [10]
75.64 dyn/cm at 0 °C 69.56 dyn/cm at 40 °C
74.92 dyn/cm at 5 °C 68.74 dyn/cm at 45 °C
74.22 dyn/cm at 10 °C 67.91 dyn/cm at 50 °C
73.49 dyn/cm at 15 °C 66.18 dyn/cm at 60 °C
72.75 dyn/cm at 20 °C 64.42 dyn/cm at 70 °C
71.97 dyn/cm at 25 °C 62.61 dyn/cm at 80 °C
71.18 dyn/cm at 30 °C 60.75 dyn/cm at 90 °C
70.38 dyn/cm at 35 °C 58.85 dyn/cm at 100 °C
Electrical conductivity of highly purified water at saturation pressure[11]
Temperature, °C Conductivity, μS/m
0.01 1.15
25 5.50
100 76.5
200 299
300 241
Water/steam equilibrium properties[edit]
Vapor pressure formula for steam in equilibrium with liquid water:[12]
log10(P) = A − B / (T – C)
where P is equilibrium vapor pressure in kPa, and T is temperature in kelvins.
for T = 273 K to 333 K: A = 7.2326; B = 1750.286; C = 38.1
for T = 333 K to 423 K: A = 7.0917; B = 1668.21; C = 45.1
Steam table[13]
Temp. Pressure H of liquid ΔvapH ΔvapW ρ of vapor
0 °C 0.612 kPa 0.00 J/g2496.5
J/g126.0 J/g 0.004845 kg/m3
10 °C 1.227 kPa 42.0 J/g2473.5
J/g130.5 J/g 0.009398 kg/m3
20 °C 2.536 kPa 83.8 J/g2450.9
J/g135.1 J/g 0.01728 kg/m3
30 °C 4.242 kPa 125.6 J/g2427.9
J/g139.7 J/g 0.03036 kg/m3
40 °C 7.370 kPa 167.2 J/g 2404.9 144.2 J/g 0.05107 kg/m3
J/g
50 °C 12.33 kPa 209.0 J/g2381.4
J/g148.7 J/g 0.08285 kg/m3
60 °C 19.90 kPa 250.8 J/g2357.6
J/g153.0 J/g 0.1300 kg/m3
70 °C 31.15 kPa 292.7 J/g2332.9
J/g157.3 J/g 0.1979 kg/m3
80 °C 46.12 kPa 334.6 J/g2307.7
J/g161.5 J/g 0.2931 kg/m3
90 °C 70.10 kPa 376.6 J/g2282.6
J/g165.5 J/g 0.4232 kg/m3
100 °C 101.32 kPa 419.0 J/g2256.3
J/g169.4 J/g 0.5974 kg/m3
110 °C 143.27 kPa 460.8 J/g2229.5
J/g173.1 J/g 0.8264 kg/m3
120 °C 198.50 kPa 503.2 J/g2201.4
J/g176.7 J/g 1.121 kg/m3
130 °C 270.13 kPa 545.8 J/g2172.5
J/g180.2 J/g 1.497 kg/m3
140 °C 361.4 kPa 588.5 J/g2142.8
J/g183.2 J/g 1.967 kg/m3
150 °C 476.0 kPa 631.5 J/g2111.8
J/g186.1 J/g 2.548 kg/m3
160 °C 618.1 kPa 674.7 J/g2080.0
J/g188.7 J/g 3.263 kg/m3
170 °C 792.0 kPa 718.5 J/g2047.0
J/g190.6 J/g 4.023 kg/m3
180 °C 1002.7 kPa 762.5 J/g2012.2
J/g192.8 J/g 5.165 kg/m3
190 °C 1254.9 kPa 807.0 J/g1975.8
J/g194.5 J/g 6.402 kg/m3
200 °C 1554.3 kPa 851.9 J/g1937.3
J/g195.6 J/g 7.868 kg/m3
210 °C 1907.9 kPa 897.5 J/g1897.5
J/g196.3 J/g 9.606 kg/m3
221.1 °
C2369.8 kPa 948.5 J/g
1850.2
J/g196.6 J/g 11.88 kg/m3
229.4 °
C2769.6 kPa 987.9 J/g
1812.5
J/g196.2 J/g 13.87 kg/m3
240.6 °
C3381.1 kPa 1040.6 J/g
1759.4
J/g195.1 J/g 16.96 kg/m3
248.9 °
C3904.1 kPa 1080.3 J/g
1715.8
J/g193.7 J/g 19.66 kg/m3
260.0 °
C4695.9 kPa 1134.8 J/g
1653.9
J/g190.8 J/g 23.84 kg/m3
271.1 °
C5603.4 kPa 1195.9 J/g
1586.5
J/g186.9 J/g 28.83 kg/m3
279.4 °
C6366.5 kPa 1240.7 J/g
1532.5
J/g183.3 J/g 33.18 kg/m3
290.6 °
C7506.2 kPa 1302.3 J/g
1456.3
J/g177.4 J/g 39.95 kg/m3
298.9 °
C8463.9 kPa 1350.0 J/g
1394.8
J/g172.2 J/g 45.93 kg/m3
310.0 °
C9878.0 kPa 1415.7 J/g
1307.7
J/g164.2 J/g 55.25 kg/m3
321.1 °
C11461 kPa 1483.9 J/g
1212.7
J/g154.5 J/g 66.58 kg/m3
329.4 °
C12785 kPa 1537.9 J/g
1133.2
J/g145.6 J/g 76.92 kg/m3
340.6 °
C14727 kPa 1617.9 J/g
1007.6
J/g130.9 J/g 94.25 kg/m3
348.9 ° 16331 kPa 1687.0 J/g 892.0 J/g 117.0 J/g 111.5 kg/m3
C
360.0 °
C18682 kPa 1797.0 J/g 694.0 J/g 91.0 J/g 145.3 kg/m3
371.1 °
C21349 kPa 1968.3 J/g 365.0 J/g 47.0 J/g 214.5 kg/m3
374.4 °
C22242 kPa 2151.2 J/g 0 J/g 0 J/g 306.8 kg/m3
Temp. Pressure H of liquid ΔvapH ΔvapW ρ of vapor
Data in the table above is given for water-steam equilibria at various temperatures over
the entire temperature range at which liquid water can exist. Pressure of the equilibrium
is given in the second column in kPa. The third column is the heat content of each gram
of the liquid phase relative to water at 0 °C. The fourth column is the heat of vaporization
of each gram of liquid that changes to vapor. The fifth column is the PV work done by
each gram of liquid that changes to vapor. The sixth column is the density of the vapor.
Melting point of ice at various pressures[edit]
Data obtained from CRC Handbook of Chemistry and Physics 44th ed., p. 2390
Pressure kPa Temp. °C
101.325 0.0
32950 −2.5
60311 −5.0
87279 −7.5
113267 −10.0
138274 −12.5
159358 −15.0
179952 −17.5
200251 −20.0
215746 −22.1
Table of various forms of ice[edit]
Properties of various forms of ice[14]
Ice
form
Densit
y
g/cm3
Crystal
structure
Triple
points
TP temp
°C
TP pressure
MPa
Ih 0.92 hexagonal
Lq, Vap, Ih 0.01 0.000612
Lq, Ih, III −22.0 207.5
Ih, II, III −34.7 212.9
Ic 0.92 cubic
II 1.17rhombohedra
l
Ih, II, III −34.7 212.9
II, III, V −24.3 344.3
II, V, VI −55 (est) 620
III 1.14 tetragonal
Lq, Ih, III −22.0 207.5
Lq, III, V −17 346.3
Ih, II, III −34.7 212.9
II, III, V −24.3 344.3
IV 1.27rhombohedra
l
V 1.23 monoclinic
Lq, III, V −17 346.3
Lq, V, VI 0.16 625.9
II, III, V −24.3 344.3
II, V, VI −55 (est) 620
VI 1.31 tetragonal Lq, V, VI 0.16 625.9
Lq, VI, VII 81.6 2200
II, V, VI −55 (est) 620
VI, VII, VIII ≈5 2100
VII 1.50 cubic
Lq, VI, VII 81.6 2200
VI, VII, VIII ≈5 2100
VII, VIII, X −173 62000
VIII 1.46 tetragonalVI, VII, VIII ≈5 2100
VII, VIII, X −173 62000
IX 1.16 tetragonal
X 2.46 cubic VII, VIII, X −173 62000
XI‡ 0.92 orthorhombic Vap, Ih, XI −201.5 0 (expected)
XII 1.29 tetragonal
XIII 1.23 monoclinic
XIV 1.29 orthorhombic
Additional data translated from German "Wasser (Stoffdaten)" page[edit]
The data that follows was copied and translated from the German language Wikipedia version of
this page (which has moved to here). It provides supplementary physical, thermodynamic, and
vapor pressure data, some of which is redundant with data in the tables above, and some of
which is additional.
Physical and thermodynamic tables[edit]
In the following tables, values are temperature dependent and to a lesser degree pressure
dependent, and are arranged by state of aggregation (s=solid, lq=liquid, g=gas), which are
clearly a function of temperature and pressure. All of the data were computed from data given in
"Formulation of the Thermodynamic Properties of Ordinary Water Substance for Scientific and
General Use" (1984). This applies to:
T – temperature in degrees Celsius
V – specific volume in decimeter 3 per kilogram (1 dm3 is equivalent to 1 liter)
H – specific enthalpy in kJ per kilogram
U – specific internal energy in kJ per kilogram
S – specific entropy in kJ per kilogram-kelvin
cp – specific heat capacity at constant pressure in kJ per kilogram-kelvin
γ – Thermal expansion coefficient as 10−3 per kelvin
λ – Heat conductivity in milliwatt per meter-kelvin
η – Viscosity in micropascal-seconds (1 cP = 1000 µPa·s)
σ – surface tension in millinewtons per meter (equivalent to dyn/cm)
Standard conditions[edit]
In the following table, material data are given for standard pressure of 0.1 MPa (equivalent to
1 bar). Up to 99.63 °C (the boiling point of water at 0.1 MPa), at this pressure water exists as a
liquid. Above that, it exists as water vapor. Note that the boiling point of 100.0 °C is at a pressure
of 0.101325 MPa (1atm), which is the average atmospheric pressure.
Water/steam data table at standard pressure (0.1 MPa)
T °CV
dm3/kg
H
kJ/kg
U
kJ/kg
S
kJ/(kg·K
)
cp
kJ/(kg·K
)
γ
10−3/K
λ
mW /
(m·K)
η
µPa·s
σ ‡
mN/m
0lq 1.000
20.06 −0.04 −0.0001 4.228 −0.080 561.0 1792 75.65
51.000
021.1 21.0 0.076 4.200 0.011 570.6 1518 74.95
101.000
342.1 42.0 0.151 4.188 0.087 580.0 1306 74.22
151.000
963.0 62.9 0.224 4.184 0.152 589.4 1137 73.49
201.001
883.9 83.8 0.296 4.183 0.209 598.4 1001 72.74
251.002
9104.8 104.7 0.367 4.183 0.259 607.2 890.4 71.98
30 1.004
4
125.8 125.7 0.437 4.183 0.305 615.5 797.7 71.20
351.006
0146.7 146.6 0.505 4.183 0.347 623.3 719.6 70.41
401.007
9167.6 167.5 0.572 4.182 0.386 630.6 653.3 69.60
451.009
9188.5 188.4 0.638 4.182 0.423 637.3 596.3 68.78
501.012
1209.4 209.3 0.704 4.181 0.457 643.6 547.1 67.95
601.017
1251.2 251.1 0.831 4.183 0.522 654.4 466.6 66.24
701.022
7293.1 293.0 0.955 4.187 0.583 663.1 404.1 64.49
801.029
0335.0 334.9 1.075 4.194 0.640 670.0 354.5 62.68
901.035
9377.0 376.9 1.193 4.204 0.696 675.3 314.6 60.82
99.6
3
lq1.043
1417.5 417.4 1.303 4.217 0.748 679.0 283.0 58.99
g1694.
32675 2505 7.359 2.043 2.885 25.05 12.26 –
100g 1696.
12675 2506 7.361 2.042 2.881 25.08 12.27 58.92
2002172.
32874 2657 7.833 1.975 2.100 33.28 16.18 37.68
300 2638. 3073 2810 8.215 2.013 1.761 43.42 20.29 14.37
8
5003565.
53488 3131 8.834 2.135 1.297 66.970 28.57 –
7504721.
04043 3571 9.455 2.308 0.978 100.30 38.48 –
10005875.
54642 4054 9.978 2.478 0.786 136.3 47.66 –
‡ The values for surface tension for the liquid section of the table are for a liquid/air
interface. Values for the gas section of the table are for a liquid/saturated steam interface.
Triple point[edit]
In the following table, material data are given with a pressure of 611.7 Pa (equivalent to
0.006117 bar). Up to a temperature of 0.01 °C, the triple point of water, water normally exists
as ice, except for supercooled water, for which one data point is tabulated here. At the triple
point, ice can exist together with both liquid water and vapor. At higher temperatures, the
data are for water vapor only.
Water/steam data table at triple point pressure (0.0006117 MPa)
T °C V
dm3/kg
H
kJ/kg
U
kJ/kg
S
kJ/(kg·K
cp γ λ
mW /
η
) kJ/(kg·K) 10−3/K (m·K) µPa·s
0 lq 1.0002 −0.04 −0.04 −0.0002 4.339 −0.081 561.0 1792
0.01
s 1.0908 −333.4 −333.4 −1.221 1.93 0.1 2180 –
lq 1.0002 0.0 0 0 4.229 −0.080 561.0 1791
g 205986 2500 2374 9.154 1.868 3.672 17.07 9.22
5 g 209913 2509 2381 9.188 1.867 3.605 17.33 9.34
10 213695 2519 2388 9.222 1.867 3.540 17.60 9.46
15 217477 2528 2395 9.254 1.868 3.478 17.88 9.59
20 221258 2537 2402 9.286 1.868 3.417 18.17 9.73
25 225039 2547 2409 9.318 1.869 3.359 18.47 9.87
30 228819 2556 2416 9.349 1.869 3.304 18.78 10.02
35 232598 2565 2423 9.380 1.870 3.249 19.10 10.17
40 236377 2575 2430 9.410 1.871 3.197 19.43 10.32
45 240155 2584 2437 9.439 1.872 3.147 19.77 10.47
50 243933 2593 2444 9.469 1.874 3.098 20.11 10.63
60 251489 2612 2459 9.526 1.876 3.004 20.82 10.96
70 259043 2631 2473 9.581 1.880 2.916 21.56 11.29
80 266597 2650 2487 9.635 1.883 2.833 22.31 11.64
90 274150 2669 2501 9.688 1.887 2.755 23.10 11.99
100 281703 2688 2515 9.739 1.891 2.681 23.90 12.53
200 357216 2879 2661 10.194 1.940 2.114 32.89 16.21
300 432721 3076 2811 10.571 2.000 1.745 43.26 20.30
500 583725 3489 3132 11.188 2.131 1.293 66.90 28.57
750 772477 4043 3571 11.808 2.307 0.977 100.20 38.47
1000 961227 4642 4054 12.331 2.478 0.785 136.30 47.66
Saturated vapor pressure[edit]
The following table is based on different, complementary sources and approximation
formulas, whose values are of various quality and accuracy. The values in the
temperature range of −100 °C to 100 °C were inferred from D. Sunday (1982) and are
quite uniform and exact. The values in the temperature range of the boiling point of water
up to the critical point (100 °C to 374 °C) are drawn from different sources and are
substantially less accurate; hence they should be used only as approximate values.[19][20]
[21][22]
To use the values correctly, consider the following points:
The values apply only to smooth interfaces and in the absence other gases or gas
mixtures such as air. Hence they apply only to pure phases and need a correction
factor for systems in which air is present.
The values were not computed according formulas widely used in the US, but using
somewhat more exact formulas (see below), which can also be used to compute
further values in the appropriate temperature ranges.
The saturated vapor pressure over water in the temperature range of −100 °C to
−50 °C is only extrapolated [Translator's note: Supercooled liquid water is not known
to exist below −42 °C].
The values have various units (Pa, hPa or bar), which must be considered when
reading them.
Formulas[edit]
The table values for −100 °C to 100 °C were computed by the following formulas,
where T is in kelvins and vapor pressures, Pw and Pi, are in pascals.
Over liquid water
loge(Pw) = –6094.4642 T−1 + 21.1249952 – 2.724552×10−2 T + 1.6853396×10−5 T2 + 2.4575506 loge(T)
For temperature range: 173.15 K to 373.15 K or equivalently −100 °C to 100 °C
Over ice
loge(Pi) = –5504.4088 T−1 – 3.5704628 – 1.7337458×10−2 T + 6.5204209×10−6 T2 + 6.1295027 loge(T)
For temperature range: 173.15 K to 273.15 K or equivalently −100 °C to 0 °C
At triple point
An important basic value, which is not registered in the table, is the saturated
vapor pressure at the triple point of water. The internationally accepted value
according to measurements of Guildner, Johnson and Jones (1976) amounts to:
Pw(ttp = 0.01 °C) = 611.657 Pa ± 0.010 Pa at (1-α) = 99%
Values of saturated vapor pressure of water
Temp.
T in
°C
Pi(T) over
ice
in Pa
Pw(T) over
water
in Pa
Temp
.
T in
°C
Pw(T) over
water
in hPa
Temp
.
T in
°C
P(T)
in bar
Temp
.
T in
°C
P(T)
in bar
Temp.
T in
°C
P(T)
in bar
−1000.001395
70.0036309 0 6.11213 100 1.01 200 15.55 300 85.88
−990.001709
40.0044121 1 6.57069 101 1.05 201 15.88 301 87.09
−980.002088
90.0053487 2 7.05949 102 1.09 202 16.21 302 88.32
−97 0.002547
0
0.0064692 3 7.58023 103 1.13 203 16.55 303 89.57
−960.003098
70.0078067 4 8.13467 104 1.17 204 16.89 304 90.82
−950.003761
70.0093996 5 8.72469 105 1.21 205 17.24 305 92.09
−940.004556
90.011293 6 9.35222 106 1.25 206 17.60 306 93.38
−930.005508
70.013538 7 10.0193 107 1.30 207 17.96 307 94.67
−920.006645
50.016195 8 10.7280 108 1.34 208 18.32 308 95.98
−910.008000
80.019333 9 11.4806 109 1.39 209 18.70 309 97.31
−900.009613
20.023031 10 12.2794 110 1.43 210 19.07 310 98.65
−89 0.011528 0.027381 11 13.1267 111 1.48 211 19.46 311 100.00
−88 0.013797 0.032489 12 14.0251 112 1.53 212 19.85 312 101.37
−87 0.016482 0.038474 13 14.9772 113 1.58 213 20.25 313 102.75
−86 0.019653 0.045473 14 15.9856 114 1.64 214 20.65 314 104.15
−85 0.02339 0.053645 15 17.0532 115 1.69 215 21.06 315 105.56
−84 0.027788 0.063166 16 18.1829 116 1.75 216 21.47 316 106.98
−83 0.032954 0.074241 17 19.3778 117 1.81 217 21.89 317 108.43
−82 0.039011 0.087101 18 20.6409 118 1.86 218 22.32 318 109.88
−81 0.046102 0.10201 19 21.9757 119 1.93 219 22.75 319 111.35
−80 0.054388 0.11925 20 23.3854 120 1.99 220 23.19 320 112.84
−79 0.064057 0.13918 21 24.8737 121 2.05 221 23.64 321 114.34
−78 0.075320 0.16215 22 26.4442 122 2.12 222 24.09 322 115.86
−77 0.088419 0.18860 23 28.1006 123 2.18 223 24.55 323 117.39
−76 0.10363 0.21901 24 29.8470 124 2.25 224 25.02 324 118.94
−75 0.12127 0.25391 25 31.6874 125 2.32 225 25.49 325 120.51
−74 0.14168 0.29390 26 33.6260 126 2.40 226 25.98 326 122.09
−73 0.16528 0.33966 27 35.6671 127 2.47 227 26.46 327 123.68
−72 0.19252 0.39193 28 37.8154 128 2.55 228 26.96 328 125.30
−71 0.22391 0.45156 29 40.0754 129 2.62 229 27.46 329 126.93
−70 0.26004 0.51948 30 42.4520 130 2.70 230 27.97 330 128.58
−69 0.30156 0.59672 31 44.9502 131 2.78 231 28.48 331 130.24
−68 0.34921 0.68446 32 47.5752 132 2.87 232 29.01 332 131.92
−67 0.40383 0.78397 33 50.3322 133 2.95 233 29.54 333 133.62
−66 0.46633 0.89668 34 53.2267 134 3.04 234 30.08 334 135.33
−65 0.53778 1.0242 35 56.2645 135 3.13 235 30.62 335 137.07
−64 0.61933 1.1682 36 59.4513 136 3.22 236 31.18 336 138.82
−63 0.71231 1.3306 37 62.7933 137 3.32 237 31.74 337 140.59
−62 0.81817 1.5136 38 66.2956 138 3.42 238 32.31 338 142.37
−61 0.93854 1.7195 39 69.9675 139 3.51 239 32.88 339 144.18
−60 1.0753 1.9509 40 73.8127 140 3.62 240 33.47 340 146.00
−59 1.2303 2.2106 41 77.8319 141 3.72 241 34.06 341 147.84
−58 1.4060 2.5018 42 82.0536 142 3.82 242 34.66 342 149.71
−57 1.6049 2.8277 43 86.4633 143 3.93 243 35.27 343 151.58
−56 1.8296 3.1922 44 91.0757 144 4.04 244 35.88 344 153.48
−55 2.0833 3.5993 45 95.8984 145 4.16 245 36.51 345 155.40
−54 2.3694 4.0535 46 100.939 146 4.27 246 37.14 346 157.34
−53 2.6917 4.5597 47 106.206 147 4.39 247 37.78 347 159.30
−52 3.0542 5.1231 48 111.708 148 4.51 248 38.43 348 161.28
−51 3.4618 5.7496 49 117.452 149 4.64 249 39.09 349 163.27
−50 3.9193 6.4454 50 123.4478 150 4.76 250 39.76 350 165.29
−49 4.4324 7.2174 51 129.7042 151 4.89 251 40.44 351 167.33
−48 5.0073 8.0729 52 136.2304 152 5.02 252 41.12 352 169.39
−47 5.6506 9.0201 53 143.0357 153 5.16 253 41.81 353 171.47
−46 6.3699 10.068 54 150.1298 154 5.29 254 42.52 354 173.58
−45 7.1732 11.225 55 157.5226 155 5.43 255 43.23 355 175.70
−44 8.0695 12.503 56 165.2243 156 5.58 256 43.95 356 177.85
−43 9.0685 13.911 57 173.2451 157 5.72 257 44.68 357 180.02
−42 10.181 15.463 58 181.5959 158 5.87 258 45.42 358 182.21
−41 11.419 17.170 59 190.2874 159 6.03 259 46.16 359 184.43
−40 12.794 19.048 60 199.3309 160 6.18 260 46.92 360 186.66
−39 14.321 21.110 61 208.7378 161 6.34 261 47.69 361 188.93
−38 16.016 23.372 62 218.5198 162 6.50 262 48.46 362 191.21
−37 17.893 25.853 63 228.6888 163 6.67 263 49.25 363 193.52
−36 19.973 28.570 64 239.2572 164 6.84 264 50.05 364 195.86
−35 22.273 31.544 65 250.2373 165 7.01 265 50.85 365 198.22
−34 24.816 34.795 66 261.6421 166 7.18 266 51.67 366 200.61
−33 27.624 38.347 67 273.4845 167 7.36 267 52.49 367 203.02
−32 30.723 42.225 68 285.7781 168 7.55 268 53.33 368 205.47
−31 34.140 46.453 69 298.5363 169 7.73 269 54.17 369 207.93
−30 37.903 51.060 70 311.7731 170 7.92 270 55.03 370 210.43
−29 42.046 56.077 71 325.5029 171 8.11 271 55.89 371 212.96
−28 46.601 61.534 72 339.7401 172 8.31 272 56.77 372 215.53
−27 51.607 67.466 73 354.4995 173 8.51 273 57.66 373 218.13
−26 57.104 73.909 74 369.7963 174 8.72 274 58.56 374 220.64
−25 63.134 80.902 75 385.6459 175 8.92 275 59.46 374.15 221.20
−24 69.745 88.485 76 402.0641 176 9.14 276 60.38
−23 76.987 96.701 77 419.0669 177 9.35 277 61.31
−22 84.914 105.60 78 436.6708 178 9.57 278 62.25
−21 93.584 115.22 79 454.8923 179 9.80 279 63.20
−20 103.06 125.63 80 473.7485 180 10.03 280 64.17
−19 113.41 136.88 81 493.2567 181 10.26 281 65.14
−18 124.70 149.01 82 513.4345 182 10.50 282 66.12
−17 137.02 162.11 83 534.3000 183 10.74 283 67.12
−16 150.44 176.23 84 555.8714 184 10.98 284 68.13
−15 165.06 191.44 85 578.1673 185 11.23 285 69.15
−14 180.97 207.81 86 601.2068 186 11.49 286 70.18
−13 198.27 225.43 87 625.0090 187 11.75 287 71.22
−12 217.07 244.37 88 649.5936 188 12.01 288 72.27
−11 237.49 264.72 89 674.9806 189 12.28 289 73.34
−10 259.66 286.57 90 701.1904 190 12.55 290 74.42
−9 283.69 310.02 91 728.2434 191 12.83 291 75.51
−8 309.75 335.16 92 756.1608 192 13.11 292 76.61
−7 337.97 362.10 93 784.9639 193 13.40 293 77.72
−6 368.52 390.95 94 814.6743 194 13.69 294 78.85
−5 401.58 421.84 95 845.3141 195 13.99 295 79.99
−4 437.31 454.88 96 876.9057 196 14.29 296 81.14
−3 475.92 490.19 97 909.4718 197 14.60 297 82.31
−2 517.62 527.93 98 943.0355 198 14.91 298 83.48
−1 562.62 568.22 99 977.6203 199 15.22 299 84.67
0 611.153 611.213 100 1013.25 200 15.55 300 85.88
Temp.
T in
°C
Pi(T) over
ice
in Pa
Pw(T) over
water
in Pa
Temp
.
T in
°C
Pw(T) over
water
in hPa
Temp
.
T in
°C
P(T)
in bar
Temp
.
T in
°C
P(T)
in bar
Temp.
T in
°C
P(T)
in bar
References[edit]
1. Jump up ̂ David R. Lide CRC Handbook of Chemistry and Physics CRC Press, 2004, p. 6-15 ISBN 0-8493-0485-7
2. Jump up ̂ Maksyutenko, Pavlo; Rizzo, Thomas R.; Boyarkin, Oleg V. (2006). "A direct measurement of the dissociation energy of water". The Journal of Chemical Physics 125 (18): 181101. doi:10.1063/1.2387163.
SiCl4
Solids - Specific Heats
A comprehensive list of some common solids as brick, cement, glass and many more - and their specific heats - imperial and SI units
Sponsored Links
Specific heat capacity of some common solids can be found in the table below:
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Agate 0.80
Aluminum bronze 0.436
Aluminum, 0oC 0.21 0.87
Antimony 0.05 0.21
Apatite 0.2 0.84
Arsenic 0.348
Artificial wool 1.357
Asbestos cement board 0.2 0.84
Asbestos mill board 0.2 0.84
Ashes 0.2 0.84
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Asphalt 0.22 0.92
Augite 0.19 0.8
Bakelite. wood filler 0.33 1.38
Bakelite. asbestos filler 0.38 1.59
Barite 0.11 0.46
Barium 0.07 0.29
Basalt rock 0.2 0.84
Beeswax 0.82 3.4
Beryl 0.2 0.84
Beryllium 1.02
Bismuth 0.03 0.13
Boile scale 0.80
Bone 0.11 0.44
Borax 0.24 1
Boron 0.31 1.3
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Brass 0.09 0.38
Brick, common 0.22 0.9
Brick, hard 0.24 1
Bronze, phosphor 0.09
Cadmium 0.06 0.25
Calcite 32 - 100F 0.19 0.8
Calcite 32 - 212F 0.2 0.84
Calcium 0.15 0.63
Calcium carbonat 0.18
Calcium sulfate 0.27
Carbon, Diamond 0.12 0.52
Carbon, Graphite 0.17 0.71
Carborundum 0.16 0.67
Cassiterite 0.09 0.38
Cement dry 0.37 1.55
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Cement powder 0.2 0.84
Cellulose 0.37
Celluloid 0.36
Charcoal 0.24 1
Chalk 0.22 0.9
Chalcopyrite 0.13 0.54
Charcoal, wood 0.24 1
Chromium 0.12 0.5
Clay 0.22 0.92
Coal, anthracite 0.3 1.26
Coal, bituminous 0.33 1.38
Cobalt 0.11 0.46
Coke 0.2 0.85
Concrete, stone 0.18 0.75
Concrete, light 0.23 0.96
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Constantan 0.41
Copper 0.09 0.39
Cork, Corkboard 0.45 1.9
Corundum 0.1 0.42
Cotton 0.32
Diamond 0.15 0.63
Dolomite rock 0.22 0.92
Duralium 0.92
Earth, dry 0.3 1.26
Electron 1.00
Emery 0.96
Fats 0.46
Fiberboard, light 0.6 2.5
Fiber hardboard 0.5 2.1
Fire brick 0.25 1.05
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Fluorite 0.22 0.92
Fluorspar 0.21 0.88
Galena 0.05 0.21
Garnet 0.18 0.75
Glass 0.2 0.84
Glass, crystal 0.12 0.5
Glass, plate 0.12 0.5
Glass, Pyrex 0.18 0.75
Glass, window 0.2 0.84
Glass-wool 0.16 0.67
Gold 0.03 0.13
Granite 0.19 0.79
Graphite 0.17 0.71
Gypsum 0.26 1.09
Hairfelt 0.5 2.1
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Hermatite 0.16 0.67
Hornblende 0.2 0.84
Hypersthene 0.19 0.8
Ice -112oF 0.35 1.47
Ice -40oF 0.43 1.8
Ice -4oF 0.47 1.97
Ice 32oF (0oC) 0.49 2.09
India rubber min 0.27 1.13
India rubber max 0.98 4.1
Ingot iron 0.49
Iodine 0.218
Iridium 0.03 0.13
Iron, 20oC 0.11 0.46
Labradorite 0.19 0.8
Lava 0.2 0.84
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Limestone 0.217 0.908
Litharge 0.21
Lead 0.03 0.13
Leather, dry 0.36 1.5
Lithium 0.86 3.58
Magnetite 0.16 0.67
Malachite 0.18 0.75
Manganese 0.11 0.46
Magnesia (85%) 0.2 0.84
Magnesium 1.05
Marble, mica 0.21 0.88
Mercury 0.03 0.14
Mica 0.12 0.5
Mineral wool blanket 0.2 0.84
Molybdenum 0.272
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Nickel 0.461
Oliglocose 0.21 0.88
Orthoclose 0.19 0.8
Osmium 0.130
Oxide of chrome 0.75
Paper 0.33 1.336
Paraffin wax 0.7 2.9
Peat 0.45 1.88
Phosphorbronze 0.36
Phosphorus 0.80
Pig iron, white 0.54
Pinchbeck 0.38
Pit coal 1.02
Plaster, light 0.24 1
Plaster, sand 0.22 0.9
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Plastics, foam 0.3 1.3
Plastics, solid 0.4 1.67
Platinum, 0oC 0.032 0.13
Porcelain 0.26 1.07
Potassium 0.13 0.54
Pyrex glass 0.2 0.84
Pyrolusite 0.16 0.67
Pyroxylin plastics 0.36 1.51
Quartz mineral 55 - 212oF 0.19 0.8
Quartz mineral 32oF (0oC) 0.17 0.71
Red lead 0.092
Red metal 0.381
Rhenium 0.14
Rhodium 0.24
Rock salt 0.22 0.92
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Rosin 1.30
Rubber 0.48 2.01
Rubidium 0.33
Salt 0.21 0.88
Sand, dry 0.19 0.80
Sandstone 0.22 0.92
Sawdust 0.21 0.9
Selenium 0.33
Serpentine 0.26 1.09
Silica aerogel 0.2 0.84
Silicon 0.75
Silicon, carbide 0.67
Silk 0.33 1.38
Silver, 20oC 0.056 0.23
Slate 0.76
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Sodium 0.3 1.26
Soil, dry 0.19 0.80
Soil, wet 0.35 1.48
Steatite 0.83
Steel 0.49
Stone 0.2 0.84
Stoneware 0.19 0.8
Sulphur, sulfur 0.17 0.71
Tantalium 0.138
Tar 0.35 1.47
Tellurium 0.05 0.21
Thorium 0.14
Tile hollow 0.15 0.63
Timber, see wood
Tin 0.24
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Titanium 0.47
Topaz 0.21 0.88
Tungsten 0.03 0.134
Uranium 0.117
Vanadium 0.12 0.5
Vermiculite 0.2 0.84
Vulcanite 0.33 1.38
Wax 3.43
Welding iron 0.515
White metal 0.147
Wood, balsa 0.7 2.9
Wood, oak 0.48 2
Wood, white pine 0.6 2.5
Wool, loose 0.3 1.26
Wool, felt 0.33 1.38
Product
Specific Heat- cp -
(Btu/lbmoF)
(kcal/kgoC)(kJ/kg K)
Zinc 0.38
1 Btu/lbmo F = 4186.8 J/kg K = 1 kcal/kgo C
T (o C) = 5/9[T (o F) - 32] T (o F) = [T (o C)](9/5) + 32