Butane

Formula: C₄H₁₀
Molecular weight: 58.1222
IUPAC Standard InChI: InChI=1S/C4H10/c1-3-4-2/h3-4H2,1-2H3
IUPAC Standard InChIKey: IJDNQMDRQITEOD-UHFFFAOYSA-N
CAS Registry Number: 106-97-8
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.
Other names: n-Butane; Diethyl; Freon 600; Liquefied petroleum gas; LPG; n-C4H10; Butanen; Butani; Methylethylmethane; UN 1011; A 21; HC 600; HC 600 (hydrocarbon); R 600; R 600 (alkane)
Permanent link for this species. Use this link for bookmarking this species for future reference.
Information on this page:
Other data available:
Data at other public NIST sites:
- Computational Chemistry Comparison and Benchmark Database
- Gas Phase Kinetics Database
Options:
- Switch to calorie-based units

Data at NIST subscription sites:

NIST subscription sites provide data under the NIST Standard Reference Data Program, but require an annual fee to access. The purpose of the fee is to recover costs associated with the development of data collections included in such sites. Your institution may already be a subscriber. Follow the links above to find out more about the data in these sites and their terms of usage.

Gas phase thermochemistry data

Go To: Top, Reaction thermochemistry data, Henry's Law data, Vibrational and/or electronic energy levels, References, Notes

Data compiled as indicated in comments:
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	-125.6 ± 0.67	kJ/mol	Ccb	Pittam and Pilcher, 1972	ALS
Δ_fH°_gas	-127.1 ± 0.67	kJ/mol	Cm	Prosen, Maron, et al., 1951	see Prosen and Rossini, 1945; ALS
Quantity	Value	Units	Method	Reference	Comment
Δ_cH°_gas	-2877.5 ± 0.63	kJ/mol	Ccb	Pittam and Pilcher, 1972	Corresponding Δ_fHº_gas = -125.6 kJ/mol (simple calculation by NIST; no Washburn corrections); ALS
Δ_cH°_gas	-2876.2 ± 0.63	kJ/mol	Cm	Prosen, Maron, et al., 1951	see Prosen and Rossini, 1945; Corresponding Δ_fHº_gas = -127.0 kJ/mol (simple calculation by NIST; no Washburn corrections); ALS
Δ_cH°_gas	-2878.3 ± 0.63	kJ/mol	Ccb	Rossini, 1934	Corresponding Δ_fHº_gas = -124.9 kJ/mol (simple calculation by NIST; no Washburn corrections); ALS

Constant pressure heat capacity of gas

C_p,gas (J/mol*K)	Temperature (K)	Reference	Comment
38.07	50.	Chen S.S., 1975	Recommended values are in good agreement with those calculated by [ Pitzer K.S., 1944, Pitzer K.S., 1946].; GT
55.35	100.
67.32	150.
76.44	200.
92.30	273.15
98.49	298.15
98.95	300.
124.77	400.
148.66	500.
169.28	600.
187.02	700.
202.38	800.
215.73	900.
227.36	1000.
237.48	1100.
246.27	1200.
253.93	1300.
260.58	1400.
266.40	1500.

Constant pressure heat capacity of gas

C_p,gas (J/mol*K)	Temperature (K)	Reference	Comment
110.58	344.9	Dailey B.P., 1943	Other experimental values of heat capacity [ Sage B.H., 1937] are believed to be less reliable, see [ Chen S.S., 1975].; GT
114.93	359.6
121.75	387.5
137.99	451.6
154.01	521.0
162.26	561.3
170.33	600.8
185.85	692.6

Reaction thermochemistry data

Go To: Top, Gas phase thermochemistry data, Henry's Law data, Vibrational and/or electronic energy levels, References, Notes

Data compiled as indicated in comments:
B - John E. Bartmess
MS - José A. Martinho Simões
ALS - Hussein Y. Afeefy, Joel F. Liebman, and Stephen E. Stein

Note: Please consider using the reaction search for this species. This page allows searching of all reactions involving this species. A general reaction search form is also available. Future versions of this site may rely on reaction search pages in place of the enumerated reaction displays seen below.

Individual Reactions

C₄H₉^- + = Butane

By formula: C₄H₉^- + H⁺ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	1739. ± 8.4	kJ/mol	Bran	DePuy, Gronert, et al., 1989	gas phase; The HOF(Et(Me)N.) in Seetula, Russell, et al., 1990 gives BDE(N-H) = 99 kcal/mol, ca. 5 kcal/mol too strong; B
Δ_rH°	1745. ± 20.	kJ/mol	Bran	Peerboom, Rademaker, et al., 1992	gas phase; B
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	1703. ± 8.8	kJ/mol	H-TS	DePuy, Gronert, et al., 1989	gas phase; The HOF(Et(Me)N.) in Seetula, Russell, et al., 1990 gives BDE(N-H) = 99 kcal/mol, ca. 5 kcal/mol too strong; B
Δ_rG°	1709. ± 21.	kJ/mol	H-TS	Peerboom, Rademaker, et al., 1992	gas phase; B

C₄H₉Li (l) + (g) = Butane (l) + (cr)

By formula: C₄H₉Li (l) + HBr (g) = C₄H₁₀ (l) + BrLi (cr)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-374.0 ± 2.0	kJ/mol	RSC	Holm, 1974	Please also see Pedley and Rylance, 1977. The reaction enthalpy was quoted from Pedley and Rylance, 1977. See Liebman, Martinho Simões, et al., 1995 for comments; MS

(g) + C₄H₉Li (l) = Butane (l) + (cr)

By formula: HBr (g) + C₄H₉Li (l) = C₄H₁₀ (l) + BrLi (cr)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-352.7 ± 2.0	kJ/mol	RSC	Holm, 1974	Please also see Pedley and Rylance, 1977. The reaction enthalpy was quoted from Pedley and Rylance, 1977. See Liebman, Martinho Simões, et al., 1995 for comments; MS

2 + = Butane

By formula: 2H₂ + C₄H₆ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-272.4 ± 1.3	kJ/mol	Chyd	Conn, Kistiakowsky, et al., 1939	gas phase; Reanalyzed by Cox and Pilcher, 1970, Original value = -274.4 ± 0.54 kJ/mol; At 355 K; ALS

+ = Butane

By formula: H₂ + C₄H₈ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-114.6 ± 0.42	kJ/mol	Chyd	Kistiakowsky, Ruhoff, et al., 1935	gas phase; Reanalyzed by Cox and Pilcher, 1970, Original value = -115.57 ± 0.088 kJ/mol; At 355 °K; ALS

+ = Butane

By formula: H₂ + C₄H₈ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-118.5 ± 0.42	kJ/mol	Chyd	Kistiakowsky, Ruhoff, et al., 1935	gas phase; Reanalyzed by Cox and Pilcher, 1970, Original value = -119.54 ± 0.079 kJ/mol; At 355 °K; ALS

+ 2 = Butane

By formula: C₄H₆ + 2H₂ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-236.7 ± 0.42	kJ/mol	Chyd	Kistiakowsky, Ruhoff, et al., 1936	gas phase; Reanalyzed by Cox and Pilcher, 1970, Original value = -238.8 ± 0.4 kJ/mol; At 355 °K; ALS

C₄H₉Li (l) + (g) = Butane (g) + HLiO (cr)

By formula: C₄H₉Li (l) + H₂O (g) = C₄H₁₀ (g) + HLiO (cr)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-240.2 ± 2.9	kJ/mol	RSC	Fowell and Mortimer, 1961	Please also see Pedley and Rylance, 1977 and Cox and Pilcher, 1970, 2.; MS

C₄H₉ClMg (cr) + ( • 556) (solution) = Butane (g) + (Cl₂Mg • 900) (solution)

By formula: C₄H₉ClMg (cr) + (HCl • 556H₂O) (solution) = C₄H₁₀ (g) + (Cl₂Mg • 900H₂O) (solution)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-305.8 ± 1.8	kJ/mol	RSC	Genchel, Evstigneeva, et al., 1976	MS

C₄H₉BrMg (solution) + (g) = Butane (solution) + Br₂Mg (solution)

By formula: C₄H₉BrMg (solution) + HBr (g) = C₄H₁₀ (solution) + Br₂Mg (solution)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-292.5 ± 2.2	kJ/mol	RSC	Holm, 1981	solvent: Diethyl ether; MS

C₄H₉BrMg (solution) + (g) = Butane (solution) + Br₂Mg (solution)

By formula: C₄H₉BrMg (solution) + HBr (g) = C₄H₁₀ (solution) + Br₂Mg (solution)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-305.9 ± 2.2	kJ/mol	RSC	Holm, 1981	solvent: Diethyl ether; MS

C₅O₅W (g) + Butane (g) = C₉H₁₀O₅W (g)

By formula: C₅O₅W (g) + C₄H₁₀ (g) = C₉H₁₀O₅W (g)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-38. ± 13.	kJ/mol	EqG	Brown, Ishikawa, et al., 1990	Temperature range: ca. 300-350 K; MS

+ = Butane

By formula: C₄H₈ + H₂ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-125.9 ± 0.42	kJ/mol	Chyd	Kistiakowsky, Ruhoff, et al., 1935	gas phase; At 355 °K; ALS

Butane =

By formula: C₄H₁₀ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-9.699	kJ/mol	Eqk	Pines, Kvetinskas, et al., 1945	gas phase; Heat of isomerization; ALS

3 + = Butane

By formula: 3H₂ + C₄H₄ = C₄H₁₀

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	-422. ± 2.	kJ/mol	Chyd	Roth, Adamczak, et al., 1991	liquid phase; ALS

Henry's Law data

Go To: Top, Gas phase thermochemistry data, Reaction thermochemistry data, Vibrational and/or electronic energy levels, References, Notes

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
0.0011		Q	N/A	missing citation give several references for the Henry's law constants but don't assign them to specific species.
0.0011		L	N/A
0.0012	3100.	L	N/A
0.0011		V	N/A
0.0049		V	N/A

Vibrational and/or electronic energy levels

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

Data compiled by: Takehiko Shimanouchi

Trans form Symmetry: C_2h Symmetry Number σ = 2

Sym.	No	Approximate	Selected Freq.		Infrared		Raman		Comments

Species		type of mode	Value	Rating	Value	Phase	Value	Phase

ag	1	CH3 d-str	2965	C	ia		2965	sln.	SF(ν₂₀)
ag	2	CH3 s-str	2872	C	ia		2872	sln.
ag	3	CH2 s-str	2853	D	ia		2853	sln.
ag	4	CH3 d-deform	1460	C	ia		1460	sln.	SF(ν₂₂)
ag	5	CH2 scis	1442	D	ia		1442	sln.
ag	6	CH3 s-deform	1382	C	ia				CF
ag	7	CH2 wag	1361	D	ia				CF
ag	8	CH3 rock	1151	C	ia		1151	sln.
ag	9	CC str	1059	C	ia		1059	sln.
ag	10	CC str	837	C	ia		837	sln.
ag	11	CCC deform	425	C	ia		425	sln.
au	12	CH3 d-str	2968	C	2968 S	solid solid	ia		SF(ν₂₇)
au	13	CH2 a-str	2930	C	2930 S	solid solid	ia
au	14	CH3 d-deform	1461	C	1461 S	solid solid	ia		SF(ν₃₀, )OV(ν₃₀,ν₃₁)
au	15	CH2 twist	1257	C	1257 W	sln.	ia
au	16	CH3 rock	948	B	948 M	solid solid	ia
au	17	CH2 rock	731	B	731 S	solid solid	ia
au	18	CH3-CH2 torsion	194	E			ia		CF
au	19	CH2-CH2 torsion	102	E			ia		CF
bg	20	CH3 d-str	2965	C	ia		2965	sln.	SF(ν₁)
bg	21	CH2 a-str	2912	C	ia		2912	sln.
bg	22	CH3 d-deform	1460	C	ia		1460	sln.	SF(ν₄)
bg	23	CH2 twist	1300	C	ia		1300	sln.
bg	24	CH3 rock	1180	D	ia				CF
bg	25	CH2 rock	803	D	ia				CF
bg	26	CH3-CH2 torsion	225	E	ia				CF
bu	27	CH3 d-str	2968	C	2968 S	solid solid	ia		SF(ν₁₂)
bu	28	CH3 s-str	2870	C	2870 S	solid solid	ia
bu	29	CH2 s-str	2853	E			ia		SF(ν₃)
bu	30	CH3 d-deform	1461	C	1461 S	solid solid	ia		SF(ν₁₄, )OV(ν₁₄,ν₃₁)
bu	31	CH2 scis	1461	C	1461 S	solid solid	ia		OV(ν₁₄,ν₃₀)
bu	32	CH3 s-deform	1379	B	1379 M	solid solid	ia
bu	33	CH2 wag	1290	B	1290 W	solid solid	ia
bu	34	CC str	1009	C	1009 W	sln.	ia
bu	35	CH3 rock	964	B	964 M	solid solid	ia
bu	36	CCC deform	271	E			ia		CF

Source: Shimanouchi, 1972

Gauche form Symmetry: C₂ Symmetry Number σ = 2

Sym.	No	Approximate	Selected Freq.		Infrared		Raman		Comments

Species		type of mode	Value	Rating	Value	Phase	Value	Phase

a	1	CH3 d-str	2968	C					Deduced from the corresponding frequencies of the trans form
a	2	CH3 d-str	2968	C					Deduced from the corresponding frequencies of the trans form
a	3	CH2 a-str	2920	D					Deduced from the corresponding frequencies of the trans form
a	4	CH3 s-str	2870	C					Deduced from the corresponding frequencies of the trans form
a	5	CH2 s-str	2860	D					Deduced from the corresponding frequencies of the trans form
a	6	CH3 d-deform	1460	C					Deduced from the corresponding frequencies of the trans form
a	7	CH3 d-deform	1460	C					Deduced from the corresponding frequencies of the trans form
a	8	CH2 scis	1450	D					Deduced from the corresponding frequencies of the trans form
a	9	CH3 s-deform	1380	C					Deduced from the corresponding frequencies of the trans form
a	10	CH2 wag	1350	C	1350 W	liq.
a	11	CH2 twist	1281	C			1281	liq.
a	12	CH3 rock	1168	D			1168	liq.
a	13	CC str	1077	D			1077	liq.
a	14	CH3 rock	980	D			980	liq.	OV(ν₃₂)
a	15	CC str	827	D			827	liq.
a	16	CH2 rock	788	C	788 M	liq.	789	liq.
a	17	CCC deform	320	C			320	liq.
a	18	CH3-CH2 torsion	201	E					CF
a	19	CH2-CH2 torsion	101	E					CF
b	20	CH3 d-str	2968	C					Deduced from the corresponding frequencies of the trans form
b	21	CH3 d-str	2968	C					Deduced from the corresponding frequencies of the trans form
b	22	CH2 a-str	2920	D					Deduced from the corresponding frequencies of the trans form
b	23	CH3 s-str	2870	C					Deduced from the corresponding frequencies of the trans form
b	24	CH2 s-str	2860	D					Deduced from the corresponding frequencies of the trans form
b	25	CH3 d-deform	1460	C					Deduced from the corresponding frequencies of the trans form
b	26	CH3 d-deform	1460	C					Deduced from the corresponding frequencies of the trans form
b	27	CH2 scis	1450	D					Deduced from the corresponding frequencies of the trans form
b	28	CH3 s-deform	1380	C					Deduced from the corresponding frequencies of the trans form
b	29	CH2 wag	1370	D			1370 VW	liq.
b	30	CH2 twist	1233	C	1233 W	liq.
b	31	CC str	1133	D	1133 M	liq.
b	32	CH3 rock	980	D			980	liq.	OV(ν₁₄,ν₃₀)
b	33	CH3 rock	955	C			955	liq.
b	34	CH2 rock	747	C	747 S	liq.
b	35	CCC deform	469	D					CF
b	36	CH3-CH2 torsion	197	E					CF

Source: Shimanouchi, 1972

Notes

Strong

Medium

Weak

Very weak

Inactive

Calculated frequency

Calculation shows that the frequency approximately equals that of the vibration indicated in the parentheses.

Overlapped by band indicated in parentheses.

1~3 cm^-1 uncertainty

3~6 cm^-1 uncertainty

6~15 cm^-1 uncertainty

15~30 cm^-1 uncertainty

References

Go To: Top, Gas phase thermochemistry data, Reaction thermochemistry data, Henry's Law data, Vibrational and/or electronic energy levels, Notes

Pittam and Pilcher, 1972
Pittam, D.A.; Pilcher, G., Measurements of heats of combustion by flame calorimetry. Part 8.-Methane, ethane, propane, n-butane and 2-methylpropane, J. Chem. Soc. Faraday Trans. 1, 1972, 68, 2224-2229. [all data]

Prosen, Maron, et al., 1951
Prosen, E.J.; Maron, F.W.; Rossini, F.D., Heats of combustion, formation, and insomerization of ten C₄ hydrocarbons, J. Res. NBS, 1951, 46, 106-112. [all data]

Prosen and Rossini, 1945
Prosen, E.J.; Rossini, F.D., Heats of formation and combustion of 1,3-butadiene and styrene, J. Res. NBS, 1945, 34, 59-63. [all data]

Rossini, 1934
Rossini, F.D., Calorimetric determination of the heats of combustion of ethane, propane, normal butane, and normal pentane, J. Res. NBS, 1934, 12, 735-750. [all data]

Chen S.S., 1975
Chen S.S., Ideal gas thermodynamic properties and isomerization of n-butane and isobutane, J. Phys. Chem. Ref. Data, 1975, 4, 859-869. [all data]

Pitzer K.S., 1944
Pitzer K.S., Thermodynamics of gaseous paraffins. Specific heat and related properties, Ind. Eng. Chem., 1944, 36, 829-831. [all data]

Pitzer K.S., 1946
Pitzer K.S., The entropies and related properties of branched paraffin hydrocarbons, Chem. Rev., 1946, 39, 435-447. [all data]

Dailey B.P., 1943
Dailey B.P., Heat capacities and hindered rotation in n-butane and isobutane, J. Am. Chem. Soc., 1943, 65, 44-46. [all data]

Sage B.H., 1937
Sage B.H., Phase equilibria in hydrocarbon systems. XX. Isobaric heat capacity of gaseous propane, n-butane, isobutane, and n-pentane, Ind. Eng. Chem., 1937, 29, 1309-1314. [all data]

DePuy, Gronert, et al., 1989
DePuy, C.H.; Gronert, S.; Barlow, S.E.; Bierbaum, V.M.; Damrauer, R., The Gas Phase Acidities of the Alkanes, J. Am. Chem. Soc., 1989, 111, 6, 1968, https://doi.org/10.1021/ja00188a003 . [all data]

Seetula, Russell, et al., 1990
Seetula, J.A.; Russell, J.J.; Gutman, D., Kinetics and Thermochemistry of the Reactions of Alkyl Radicals with HI: A Reconciliation of the Alkyl Radical Heats of Formation, J. Am. Chem. Soc., 1990, 112, 4, 1347, https://doi.org/10.1021/ja00160a009 . [all data]

Peerboom, Rademaker, et al., 1992
Peerboom, R.A.L.; Rademaker, G.J.; Dekoning, L.J.; Nibbering, N.M.M., Stabilization of Cycloalkyl Carbanions in the Gas Phase, Rapid Commun. Mass Spectrom., 1992, 6, 6, 394, https://doi.org/10.1002/rcm.1290060608 . [all data]

Holm, 1974
Holm, T., J. Organometal. Chem., 1974, 77, 27. [all data]

Pedley and Rylance, 1977
Pedley, J.B.; Rylance, J., Computer Analysed Thermochemical Data: Organic and Organometallic Compounds, University of Sussex, Brigton, 1977. [all data]

Liebman, Martinho Simões, et al., 1995
Liebman, J.F.; Martinho Simões, J.A.; Slayden, S.W., In Lithium Chemistry: A Theoretical and Experimental Overview Wiley: New York, Sapse, A.-M.; Schleyer, P. von Ragué, ed(s)., 1995. [all data]

Conn, Kistiakowsky, et al., 1939
Conn, J.B.; Kistiakowsky, G.B.; Smith, E.A., Heats of organic reactions. VIII. Some further hydrogenations, including those of some acetylenes, J. Am. Chem. Soc., 1939, 61, 1868-1876. [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]

Kistiakowsky, Ruhoff, et al., 1935
Kistiakowsky, G.B.; Ruhoff, J.R.; Smith, H.A.; Vaughan, W.E., Heats of organic reactions. II. Hydrogenation of some simpler olefinic hydrocarbons, J. Am. Chem. Soc., 1935, 57, 876-882. [all data]

Kistiakowsky, Ruhoff, et al., 1936
Kistiakowsky, G.B.; Ruhoff, J.R.; Smith, H.A.; Vaughan, W.E., Heats of organic reactions. IV. Hydrogenation of some dienes and of benzene, J. Am. Chem. Soc., 1936, 58, 146-153. [all data]

Fowell and Mortimer, 1961
Fowell, P.A.; Mortimer, C.T., J. Chem. Soc., 1961, 3793.. [all data]

Cox and Pilcher, 1970, 2
Cox, J.D.; Pilcher, G., Thermochemistry of Organic and Organometallic Compounds in Academic Press, New York, 1970. [all data]

Genchel, Evstigneeva, et al., 1976
Genchel, V.G.; Evstigneeva, E.V.; Petrova, N.V., Zh. Fiz. Khim., 1976, 50, 1909. [all data]

Holm, 1981
Holm, T., J. Chem. Soc., Perkin Trans. II, 1981, 464.. [all data]

Brown, Ishikawa, et al., 1990
Brown, C.E.; Ishikawa, Y.; Hackett, P.A.; Rayner, D.M., J. Am. Chem. Soc., 1990, 112, 2530. [all data]

Pines, Kvetinskas, et al., 1945
Pines, H.; Kvetinskas, B.; Kassel, L.S.; Ipatieff, V.N., Determination of equilibrium constants for butanes and pentanes, J. Am. Chem. Soc., 1945, 67, 631-637. [all data]

Roth, Adamczak, et al., 1991
Roth, W.R.; Adamczak, O.; Breuckmann, R.; Lennartz, H.-W.; Boese, R., Die Berechnung von Resonanzenergien; das MM2ERW-Kraftfeld, Chem. Ber., 1991, 124, 2499-2521. [all data]

Shimanouchi, 1972
Shimanouchi, T., Tables of Molecular Vibrational Frequencies Consolidated Volume I, National Bureau of Standards, 1972, 1-160. [all data]

Notes

Go To: Top, Gas phase thermochemistry data, Reaction thermochemistry data, Henry's Law data, Vibrational and/or electronic energy levels, References

Symbols used in this document:

C_p,gas	Constant pressure heat capacity of gas
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°_gas	Enthalpy of combustion of gas at standard conditions
Δ_fH°_gas	Enthalpy of formation of gas at standard conditions
Δ_rG°	Free energy of reaction at standard conditions
Δ_rH°	Enthalpy of reaction at standard conditions

Data from NIST Standard Reference Database 69: NIST Chemistry WebBook
The National Institute of Standards and Technology (NIST) uses its best efforts to deliver a high quality copy of the Database and to verify that the data contained therein have been selected on the basis of sound scientific judgment. However, NIST makes no warranties to that effect, and NIST shall not be liable for any damage that may result from errors or omissions in the Database.
Customer support for NIST Standard Reference Data products.

Butane

Data at NIST subscription sites:

Gas phase thermochemistry data

Constant pressure heat capacity of gas

Constant pressure heat capacity of gas

Reaction thermochemistry data

Individual Reactions

Henry's Law data

Henry's Law constant (water solution)

Vibrational and/or electronic energy levels

Trans form Symmetry: C2h Symmetry Number σ = 2

Gauche form Symmetry: C2 Symmetry Number σ = 2

Notes

References

Notes

Trans form Symmetry: C_2h Symmetry Number σ = 2

Gauche form Symmetry: C₂ Symmetry Number σ = 2