Naphthalene

Formula: C₁₀H₈
Molecular weight: 128.1705
IUPAC Standard InChI: InChI=1S/C10H8/c1-2-6-10-8-4-3-7-9(10)5-1/h1-8H
IUPAC Standard InChIKey: UFWIBTONFRDIAS-UHFFFAOYSA-N
CAS Registry Number: 91-20-3
Chemical structure:
This structure is also available as a 2d Mol file or as a computed 3d SD file
The 3d structure may be viewed using Java or Javascript.
Isotopologues:
- Naphthalene-D8
Other names: Albocarbon; Dezodorator; Moth flakes; Naphthalin; Naphthaline; Naphthene; Tar camphor; White tar; Camphor tar; Moth balls; Naftalen; NCI-C52904; Mighty 150; Mighty RD1; Rcra waste number U165; UN 1334; UN 2304; NSC 37565
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Gas phase thermochemistry data

Go To: Top, Condensed phase thermochemistry data, Reaction thermochemistry data, Henry's Law data, References, Notes

Data compiled as indicated in comments:
DRB - Donald R. Burgess, Jr.
ALS - Hussein Y. Afeefy, Joel F. Liebman, and Stephen E. Stein
GT - Glushko Thermocenter, Russian Academy of Sciences, Moscow

Quantity	Value	Units	Method	Reference	Comment
Δ_fH°_gas	150. ± 10.	kJ/mol	AVG	N/A	Average of 7 values; Individual data points

Constant pressure heat capacity of gas

C_p,gas (J/mol*K)	Temperature (K)	Reference	Comment
36.18	50.	Thermodynamics Research Center, 1997	p=1 bar. Selected values of S(T) and Cp(T) agree with those calculated by statistical thermodynamics method [ Dorofeeva O.V., 1986, Dorofeeva O.V., 1988] within 1.2 J/molK. Discrepancies with other calculations [ Barrow G.M., 1951, McClellan A.L., 1955, 79CHE/KUD, Lielmezs J., 1981] reach 2-3 J/molK.; GT
47.50	100.
63.89	150.
84.99	200.
120.52	273.15
133.02	298.15
133.94	300.
181.16	400.
220.70	500.
252.37	600.
277.77	700.
298.43	800.
315.50	900.
329.77	1000.
341.8	1100.
352.0	1200.
360.8	1300.
368.2	1400.
374.7	1500.

Constant pressure heat capacity of gas

C_p,gas (J/mol*K)	Temperature (K)	Reference	Comment
201.6 ± 2.0	451.0	Barrow G.M., 1951	GT
226.7 ± 2.3	522.7	Barrow G.M., 1951	GT

Condensed phase thermochemistry data

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Data compiled as indicated in comments:
DH - Eugene S. Domalski and Elizabeth D. Hearing
DRB - Donald R. Burgess, Jr.
ALS - Hussein Y. Afeefy, Joel F. Liebman, and Stephen E. Stein

Quantity	Value	Units	Method	Reference	Comment
S°_liquid	217.59	J/mol*K	N/A	Chirico, Knipmeyer, et al., 1993	DH
Quantity	Value	Units	Method	Reference	Comment
Δ_fH°_solid	77. ± 10.	kJ/mol	AVG	N/A	Average of 7 values; Individual data points
Quantity	Value	Units	Method	Reference	Comment
Δ_cH°_solid	-5160. ± 20.	kJ/mol	AVG	N/A	Average of 18 values; Individual data points
Quantity	Value	Units	Method	Reference	Comment
S°_{solid,1 bar}	167.40	J/mol*K	N/A	McCullough, Finke, et al., 1957	DH
S°_{solid,1 bar}	162.84	J/mol*K	N/A	Southard and Brickwedde, 1933	DH
S°_{solid,1 bar}	166.86	J/mol*K	N/A	Pearce and Tanner, 1934	Extrapolation below 90 K, 58.32 J/mol*K.; DH
S°_{solid,1 bar}	166.9	J/mol*K	N/A	Huffman, Parks, et al., 1930	Extrapolation below 90 K, 53.09 J/mol*K.; DH

Constant pressure heat capacity of liquid

C_p,liquid (J/mol*K)	Temperature (K)	Reference	Comment
196.06	298.15	Chirico, Knipmeyer, et al., 1993	T = 260 to 700 K.; DH

Constant pressure heat capacity of solid

C_p,solid (J/mol*K)	Temperature (K)	Reference	Comment
213.	330.	David, 1964	T = 298 to 353 K. Mean value. T = uncertain.; DH
188.4	342.	Rastogi and Bassi, 1964	T = 342, 384 K.; DH
165.69	298.15	McCullough, Finke, et al., 1957	T = 10 to 370 K.; DH
156.1	298.15	Ueberreiter and Orthmann, 1950	T = 293 to 368 K. Equation only.; DH
195.8	298.1	Eibert, 1944	T = 30 to 200°C, equations only in t°C. Cp(c) = 0.365 cal/gK (30 to 80°C); Cp(liq) = 0.329 + 0.000824t cal/gK (80 to 200°C).; DH
161.5	298.1	Schmidt, 1941	T = 22 to 200°C, equations only, in t°C. Cp(c) = 0.2595 + 0.001672t cal/gK (22 to 80°C); Cp(liq) = 0.3360 + 0.0008180t cal/gK (80 to 200°C).; DH
168.11	301.58	Hicks, 1938	T = 58 to 304 K. Value is unsmoothed experimental datum.; DH
168.07	297.6	Pearce and Tanner, 1934	T = 94 to 298 K. Value is unsmoothed experimental datum.; DH
165.48	294.68	Southard and Brickwedde, 1933	T = 15 to 295 K. Value is unsmoothed experimental datum.; DH
169.0	303.	Spaght, Thomas, et al., 1932	T = 30 to 190°C.; DH
163.6	295.1	Huffman, Parks, et al., 1930	T = 91 to 295 K.; DH
159.4	298.	Andrews, Lynn, et al., 1926	T = 12 to 300°C.; DH

Reaction thermochemistry data

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Data compiled as indicated in comments:
B - John E. Bartmess
M - Michael M. Meot-Ner (Mautner) and Sharon G. Lias
ALS - Hussein Y. Afeefy, Joel F. Liebman, and Stephen E. Stein

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Individual Reactions

C₁₀H₇^- + = Naphthalene

By formula: C₁₀H₇^- + H⁺ = C₁₀H₈

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	1649. ± 5.0	kJ/mol	Bran	Reed and Kass, 2000	gas phase; B
Δ_rH°	1649. ± 5.0	kJ/mol	TDEq	Meot-ner, Liebman, et al., 1988	gas phase; anchored to 88MEO scale, not the "87 acidity scale". The Kiefer, Zhang, et al., 1997 BDE is for ortho.; B
Δ_rH°	1648. ± 21.	kJ/mol	CIDC	Lardin, Squires, et al., 2001	gas phase; B
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	1613. ± 5.4	kJ/mol	H-TS	Reed and Kass, 2000	gas phase; B
Δ_rG°	1606. ± 5.0	kJ/mol	TDEq	Meot-ner, Liebman, et al., 1988	gas phase; anchored to 88MEO scale, not the "87 acidity scale". The Kiefer, Zhang, et al., 1997 BDE is for ortho.; B
Δ_rG°	1613. ± 21.	kJ/mol	H-TS	Lardin, Squires, et al., 2001	gas phase; B

C₆H₇N⁺ + Naphthalene = (C₆H₇N⁺ • )

By formula: C₆H₇N⁺ + C₁₀H₈ = (C₆H₇N⁺ • C₁₀H₈)

Bond type: Charge transfer bond (positive ion)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	64.4	kJ/mol	PHPMS	El-Shall and Meot-Ner (Mautner), 1987	gas phase; Entropy change calculated or estimated; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	110.	J/mol*K	N/A	El-Shall and Meot-Ner (Mautner), 1987	gas phase; Entropy change calculated or estimated; M

Free energy of reaction

Δ_rG° (kJ/mol)	T (K)	Method	Reference	Comment
31.	324.	PHPMS	El-Shall and Meot-Ner (Mautner), 1987	gas phase; Entropy change calculated or estimated; M

C₁₂H₈⁺ + Naphthalene = (C₁₂H₈⁺ • )

By formula: C₁₂H₈⁺ + C₁₀H₈ = (C₁₂H₈⁺ • C₁₀H₈)

Bond type: Charge transfer bond (positive ion)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	52.7	kJ/mol	PHPMS	Meot-Ner (Mautner), 1980	gas phase; Entropy change calculated or estimated; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	120.	J/mol*K	N/A	Meot-Ner (Mautner), 1980	gas phase; Entropy change calculated or estimated; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	21.	kJ/mol	PHPMS	Meot-Ner (Mautner), 1980	gas phase; Entropy change calculated or estimated; M

C₁₂H₉⁺ + Naphthalene = (C₁₂H₉⁺ • )

By formula: C₁₂H₉⁺ + C₁₀H₈ = (C₁₂H₉⁺ • C₁₀H₈)

Bond type: Charge transfer bond (positive ion)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	58.2	kJ/mol	PHPMS	Meot-Ner (Mautner), 1980	gas phase; Entropy change calculated or estimated; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	120.	J/mol*K	N/A	Meot-Ner (Mautner), 1980	gas phase; Entropy change calculated or estimated; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	27.	kJ/mol	PHPMS	Meot-Ner (Mautner), 1980	gas phase; Entropy change calculated or estimated; M

2 + Naphthalene =

By formula: 2H₂ + C₁₀H₈ = C₁₀H₁₂

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-125.	kJ/mol	Eqk	Frye and Weitkamp, 1969	gas phase; ALS
Δ_rH°	-120.5 ± 5.0	kJ/mol	Eqk	Wilson, Caflisch, et al., 1958	gas phase; Reanalyzed by Cox and Pilcher, 1970, Original value = -133.9 ± 5.0 kJ/mol; At 400 K; ALS

= Naphthalene

By formula: C₁₀H₈ = C₁₀H₈

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-248.5 ± 8.0	kJ/mol	Eqk	Dreeskamp, Kapahnke, et al., 1988	liquid phase; solvent: Heptane; Isomerization; ALS
Δ_rH°	-249.2 ± 8.0	kJ/mol	Ciso	Grimme and Heinze, 1978	liquid phase; solvent: Heptane; ALS

C₁₀H₈⁺ + Naphthalene = (C₁₀H₈⁺ • )

By formula: C₁₀H₈⁺ + C₁₀H₈ = (C₁₀H₈⁺ • C₁₀H₈)

Bond type: Charge transfer bond (positive ion)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	74.5	kJ/mol	PHPMS	Meot-Ner (Mautner), 1980	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	120.	J/mol*K	PHPMS	Meot-Ner (Mautner), 1980	gas phase; M

C₁₀H₇^- + = Naphthalene

By formula: C₁₀H₇^- + H⁺ = C₁₀H₈

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	1655. ± 5.4	kJ/mol	Bran	Reed and Kass, 2000	gas phase; B
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	1619. ± 5.9	kJ/mol	H-TS	Reed and Kass, 2000	gas phase; B

H₄O₄^- + Naphthalene + 2 = C₁₀H₁₂O₄^-

By formula: H₄O₄^- + C₁₀H₈ + 2H₂O = C₁₀H₁₂O₄^-

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	219. ± 9.6	kJ/mol	N/A	Le Barbu, Schiedt, et al., 2002	gas phase; Affinity is difference in EAs of lesser solvated species; B

H₂O₃^- + Naphthalene + = C₁₀H₁₀O₃^-

By formula: H₂O₃^- + C₁₀H₈ + H₂O = C₁₀H₁₀O₃^-

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	158. ± 9.6	kJ/mol	N/A	Le Barbu, Schiedt, et al., 2002	gas phase; Affinity is difference in EAs of lesser solvated species; B

C₁₀H₉⁺ + Naphthalene = (C₁₀H₉⁺ • )

By formula: C₁₀H₉⁺ + C₁₀H₈ = (C₁₀H₉⁺ • C₁₀H₈)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	59.0	kJ/mol	PHPMS	Meot-Ner (Mautner), 1980	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	130.	J/mol*K	PHPMS	Meot-Ner (Mautner), 1980	gas phase; M

+ Naphthalene = C₁₀H₈O₂^-

By formula: O₂^- + C₁₀H₈ = C₁₀H₈O₂^-

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	92.5 ± 9.6	kJ/mol	N/A	Le Barbu, Schiedt, et al., 2002	gas phase; Affinity is difference in EAs of lesser solvated species; B

+ Naphthalene = C₁₀H₈NO^-

By formula: NO^- + C₁₀H₈ = C₁₀H₈NO^-

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	60.7 ± 9.6	kJ/mol	N/A	Le Barbu, Schiedt, et al., 2002	gas phase; Affinity is difference in EAs of lesser solvated species; B

C₁₀H₈NO^- + 2 Naphthalene = C₂₀H₁₆NO^-

By formula: C₁₀H₈NO^- + 2C₁₀H₈ = C₂₀H₁₆NO^-

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	99.6 ± 9.6	kJ/mol	N/A	Le Barbu, Schiedt, et al., 2002	gas phase; Affinity is difference in EAs of lesser solvated species; B

5 + Naphthalene =

By formula: 5H₂ + C₁₀H₈ = C₁₀H₁₈

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-318.	kJ/mol	Eqk	Frye and Weitkamp, 1969	gas phase; ALS

Henry's Law data

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Data compiled by: Rolf Sander

Henry's Law constant (water solution)

k_H(T) = k°_H exp(d(ln(k_H))/d(1/T) ((1/T) - 1/(298.15 K)))
k°_H = Henry's law constant for solubility in water at 298.15 K (mol/(kg*bar))
d(ln(k_H))/d(1/T) = Temperature dependence constant (K)

k°_H (mol/(kg*bar))	d(ln(k_H))/d(1/T) (K)	Method	Reference	Comment
0.80		Q	N/A	missing citation give several references for the Henry's law constants but don't assign them to specific species.
2.0		X	N/A
2.1	3600.	X	N/A
2.4		L	N/A
2.1		M	Mackay, Shiu, et al., 1979
2.1		T	Mackay, Shiu, et al., 1979
2.4		V	N/A
1.9		V	Bohon and Claussen, 1951

References

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Thermodynamics Research Center, 1997
Thermodynamics Research Center, Selected Values of Properties of Chemical Compounds., Thermodynamics Research Center, Texas A&M University, College Station, Texas, 1997. [all data]

Dorofeeva O.V., 1986
Dorofeeva O.V., On calculation of thermodynamic properties of polycyclic aromatic hydrocarbons, Thermochim. Acta, 1986, 102, 59-66. [all data]

Dorofeeva O.V., 1988
Dorofeeva O.V., Thermodynamic Properties of Polycyclic Aromatic Hydrocarbons in the Gaseous Phase. Institute for High Temperatures, USSR Academy of Sciences, Preprint No.1-238 (in Russian), Moscow, 1988. [all data]

Barrow G.M., 1951
Barrow G.M., The thermodynamic properties of naphthalene, J. Am. Chem. Soc., 1951, 73, 573-575. [all data]

McClellan A.L., 1955
McClellan A.L., Vibrational assignment and thermodynamic properties of naphthalene, J. Chem. Phys., 1955, 23, 245-248. [all data]

Lielmezs J., 1981
Lielmezs J., Jr., Thermodynamic functions for naphthalene, Thermochim. Acta, 1981, 47, 287-308. [all data]

Chirico, Knipmeyer, et al., 1993
Chirico, R.D.; Knipmeyer, S.E.; Nguyen, A.; Steele, W.V., The thermodynamic properties to the temperature 700 K of naphthalene and of 2,7-dimethylnaphthalene, J. Chem. Thermodyn., 1993, 25, 1461-1494. [all data]

McCullough, Finke, et al., 1957
McCullough, J.P.; Finke, H.L.; Messerly, J.F.; Kincheloe, T.C.; Waddington, G., The low temperature thermodynamic properties of naphthalene, 1-methylnaphthalene, 2-methylnaphthalene, 1,2,3,4-tetrahydronaphthalene, trans-decahydronaphthalene and cis-decahydronaphthalene, J. Phys. Chem., 1957, 61, 1105-1116. [all data]

Southard and Brickwedde, 1933
Southard, J.C.; Brickwedde, F.G., Low temperature specific heats. I. An improved calorimeter for use from 14 to 300 K. The heat capacity and entropy of naphthalene. J. Am. Chem. Soc., 1933, 4378-4384. [all data]

Pearce and Tanner, 1934
Pearce, J.N.; Tanner, W.B., The heat capacity and the free energy of formation of naphthalene, Proc. Iowa Acad. Sci., 1934, 41, 123-126. [all data]

Huffman, Parks, et al., 1930
Huffman, H.M.; Parks, G.S.; Daniels, A.C., Thermal data on organic compounds. VII. The heat capacities, entropies and free energies of twelve aromatic hydrocarbons, J. Am. Chem. Soc., 1930, 52, 1547-1558. [all data]

David, 1964
David, D.J., Determination of specific heat and heat of fusion by differential thermal analysis. Study of theory and operating parameters, Anal. Chem., 1964, 36, 2162-2166. [all data]

Rastogi and Bassi, 1964
Rastogi, R.P.; Bassi, P.S., Mechanism of eutectic crystallization, J. Phys. Chem., 1964, 68, 2398-2406. [all data]

Ueberreiter and Orthmann, 1950
Ueberreiter, K.; Orthmann, H.-J., Specifische Wärme, spezifisches Volumen, Temperatur- und Wärme-leittähigkeit einiger disubstituierter Benzole und polycyclischer Systeme, Z. Natursforsch. 5a, 1950, 101-108. [all data]

Eibert, 1944
Eibert, J., Thesis Washington University (St. Louis), 1944. [all data]

Schmidt, 1941
Schmidt, W.R., Thesis Washington University (St. Louis), 1941. [all data]

Hicks, 1938
Hicks, J.F.G., Jr., A low temperature calorimeter. The heat capacity and entropy of thallium from 14 to 300°K. Low temperature studies. No. 3, J. Am. Chem. Soc., 1938, 60, 1000-1004. [all data]

Spaght, Thomas, et al., 1932
Spaght, M.E.; Thomas, S.B.; Parks, G.S., Some heat capacity data on organic compounds obtained with a radiation calorimeter, J. Phys. Chem., 1932, 36, 882-888. [all data]

Andrews, Lynn, et al., 1926
Andrews, D.H.; Lynn, G.; Johnston, J., The heat capacities and heat of crystallization of some isomeric aromatic compounds, J. Am. Chem. Soc., 1926, 48, 1274-1287. [all data]

Reed and Kass, 2000
Reed, D.R.; Kass, S.R., Experimental determination of the alpha and beta C-H bond dissociation energies in naphthalene, J. Mass Spectrom., 2000, 35, 4, 534-539, https://doi.org/10.1002/(SICI)1096-9888(200004)35:4<534::AID-JMS964>3.0.CO;2-T . [all data]

Meot-ner, Liebman, et al., 1988
Meot-ner, M.; Liebman, J.F.; Kafafi, S.A., Ionic Probes of Aromaticity in Annelated Rings, J. Am. Chem. Soc., 1988, 110, 18, 5937, https://doi.org/10.1021/ja00226a001 . [all data]

Kiefer, Zhang, et al., 1997
Kiefer, J.H.; Zhang, Q.; Kern, R.D.; Yao, J.; Jursic, B., Pyrolysis of Aromatic Azines: Pyrazine, Pyrimidine, and Pyridine, J. Phys. Chem. A, 1997, 101, 38, 7061, https://doi.org/10.1021/jp970211z . [all data]

Lardin, Squires, et al., 2001
Lardin, H.A.; Squires, R.R.; Wenthold, P.G., Determination of the electron affinities of alpha- and beta- naphthyl radicals using the kinetic method with full entropy analysis. The C-H bond dissociation energies of naphthalene, J. Mass Spectrom., 2001, 36, 6, 607-615, https://doi.org/10.1002/jms.159 . [all data]

El-Shall and Meot-Ner (Mautner), 1987
El-Shall, M.S.; Meot-Ner (Mautner), M., Ionic Charge Transfer Complexes. 3. Delocalised pi Systems as Electron Acceptors and Donors, J. Phys. Chem., 1987, 91, 5, 1088, https://doi.org/10.1021/j100289a017 . [all data]

Meot-Ner (Mautner), 1980
Meot-Ner (Mautner), M., Dimer Cations of Polycyclic Aromatics: Experimental Bonding Energies and Resonance Stabilization, J. Phys. Chem., 1980, 84, 21, 2724, https://doi.org/10.1021/j100458a012 . [all data]

Frye and Weitkamp, 1969
Frye, C.G.; Weitkamp, A.W., Equilibrium hydrogenations of multi-ring aromatics, J. Chem. Eng. Data, 1969, 14, 372-376. [all data]

Wilson, Caflisch, et al., 1958
Wilson, T.P.; Caflisch, E.G.; Hurley, G.F., The naphthalene-tetralin-hydrogen equilibrium at elevated temperature and pressure, J. Phys. Chem., 1958, 62, 1059. [all data]

Cox and Pilcher, 1970
Cox, J.D.; Pilcher, G., Thermochemistry of Organic and Organometallic Compounds, Academic Press, New York, 1970, 1-636. [all data]

Dreeskamp, Kapahnke, et al., 1988
Dreeskamp, H.; Kapahnke, P.; Tochtermann, W., Photo valence isomerization of sterically strained aromatic hydrocarbons: 8,9-dicarbethoxy[6]paracyclophane, Radiat. Phys. Chem., 1988, 32, 537-539. [all data]

Grimme and Heinze, 1978
Grimme, W.; Heinze, U., Kinetics and enthalpy of isomerization of benzobicyclo[2.2.0]hexa-2,5-diene, Chem. Ber., 1978, 111, 2563-2570. [all data]

Le Barbu, Schiedt, et al., 2002
Le Barbu, K.; Schiedt, J.; Weinkauf, R.; Schlag, E.W.; Nilles, J.M.; Xu, S.J.; Thomas, O.C.; Bowen, K.H., Microsolvation of small anions by aromatic molecules: An exploratory study, J. Chem. Phys., 2002, 116, 22, 9663-9671, https://doi.org/10.1063/1.1475750 . [all data]

Mackay, Shiu, et al., 1979
Mackay, D.; Shiu, W.-Y.; Sutherland, R.P., Determination of Air-Water Henry's Law Constants for Hydrophobic Pollutants, Environ. Sci. Technol., 1979, 13, 333-337. [all data]

Bohon and Claussen, 1951
Bohon, R.L.; Claussen, W.F., The solubility of aromatic hydrocarbons in water, J. Am. Chem. Soc., 1951, 73, 1571-1578. [all data]

Notes

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Symbols used in this document:

C_p,gas	Constant pressure heat capacity of gas
C_p,liquid	Constant pressure heat capacity of liquid
C_p,solid	Constant pressure heat capacity of solid
S°_liquid	Entropy of liquid at standard conditions
S°_{solid,1 bar}	Entropy of solid at standard conditions (1 bar)
T	Temperature
d(ln(k_H))/d(1/T)	Temperature dependence parameter for Henry's Law constant
k°_H	Henry's Law constant at 298.15K
Δ_cH°_solid	Enthalpy of combustion of solid at standard conditions
Δ_fH°_gas	Enthalpy of formation of gas at standard conditions
Δ_fH°_solid	Enthalpy of formation of solid at standard conditions
Δ_rG°	Free energy of reaction at standard conditions
Δ_rH°	Enthalpy of reaction at standard conditions
Δ_rS°	Entropy of reaction at standard conditions

Data from NIST Standard Reference Database 69: NIST Chemistry WebBook
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