Hydrogen sulfide

Formula: H₂S
Molecular weight: 34.081
IUPAC Standard InChI: InChI=1S/H2S/h1H2
IUPAC Standard InChIKey: RWSOTUBLDIXVET-UHFFFAOYSA-N
CAS Registry Number: 7783-06-4
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: Dihydrogen monosulfide; Dihydrogen sulfide; Hydrosulfuric acid; Stink damp; Sulfur hydride; Sulfureted hydrogen; H2S; Sulfuretted hydrogen; Hydrogen sulphide; Hydrogen sulfide (H2S); Acide sulfhydrique; Hydrogene sulfure; Idrogeno solforato; Rcra waste number U135; Schwefelwasserstoff; Siarkowodor; UN 1053; Zwavelwaterstof; Hepatic gas; Hepatic acid; Hydrogen monosulfide; Sewer gas
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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
0.087	2100.	M	N/A
0.10	2000.	L	N/A
0.10	2300.	Q	N/A	Only the tabulated data between T = 273. K and T = 303. K from missing citation was used to derive k_H and -Δ k_H/R. Above T = 303. K the tabulated data could not be parameterized by equation (reference missing) very well. The partial pressure of water vapor (needed to convert some Henry's law constants) was calculated using the formula given by missing citation. The quantities A and α from missing citation were assumed to be identical.
0.10	2200.	L	N/A
0.097	2200.	X	N/A
0.10	2100.	L	N/A
0.10	2100.	L	N/A
0.10		R	N/A
0.0010	2300.	X	N/A	The value is taken from the compilation of solubilities by W. Asman (unpublished).

Gas phase ion energetics data

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Data evaluated as indicated in comments:
HL - Edward P. Hunter and Sharon G. Lias
L - Sharon G. Lias

Data compiled as indicated in comments:
B - John E. Bartmess
LBLHLM - Sharon G. Lias, John E. Bartmess, Joel F. Liebman, John L. Holmes, Rhoda D. Levin, and W. Gary Mallard
LLK - Sharon G. Lias, Rhoda D. Levin, and Sherif A. Kafafi
RDSH - Henry M. Rosenstock, Keith Draxl, Bruce W. Steiner, and John T. Herron

View reactions leading to H₂S⁺ (ion structure unspecified)

Quantity	Value	Units	Method	Reference	Comment
IE (evaluated)	10.457 ± 0.012	eV	N/A	N/A	L
Quantity	Value	Units	Method	Reference	Comment
Proton affinity (review)	168.	kcal/mol	N/A	Hunter and Lias, 1998	HL
Quantity	Value	Units	Method	Reference	Comment
Gas basicity	161.0	kcal/mol	N/A	Hunter and Lias, 1998	HL

Ionization energy determinations

IE (eV)	Method	Reference	Comment
10.453 ± 0.008	PI	Walters and Blais, 1984	LBLHLM
10.4607 ± 0.0026	PI	Prest, Tzeng, et al., 1983	LBLHLM
10.449 ± 0.006	PI	Walters and Blais, 1981	LLK
10. ± 4.	END	Smith, Adams, et al., 1981	LLK
10.48	PE	Kimura, Katsumata, et al., 1981	LLK
10.466 ± 0.002	S	Karlsson, Mattsson, et al., 1976	LLK
10.56 ± 0.05	EI	Balkis, Gaines, et al., 1976	LLK
10.5	PI	Rabalais, Debies, et al., 1974	LLK
10.43	PE	Natalis, 1973	LLK
10.45	EI	Morrison and Traeger, 1973	LLK
10.47	PE	Potts and Price, 1972	LLK
10.43	PE	Delwiche and Natalis, 1970	RDSH
12.76	PE	Delwiche and Natalis, 1970	RDSH
14.91	PE	Delwiche and Natalis, 1970	RDSH
20.8	PE	Delwiche and Natalis, 1970	RDSH
18.0	PE	Delwiche and Natalis, 1970	RDSH
12.81	PE	Delwiche, Natalis, et al., 1970	RDSH
14.79	PE	Delwiche, Natalis, et al., 1970	RDSH
10.43 ± 0.01	PI	Dibeler and Liston, 1968	RDSH
10.42	PE	Al-Joboury and Turner, 1964	RDSH
12.62	PE	Al-Joboury and Turner, 1964	RDSH
14.82	PE	Al-Joboury and Turner, 1964	RDSH
18.00	PE	Al-Joboury and Turner, 1964	RDSH
20.12	PE	Al-Joboury and Turner, 1964	RDSH
10.45 ± 0.03	EI	Frost and McDowell, 1958	RDSH
10.46 ± 0.01	PI	Watanabe, 1954	RDSH
10.47 ± 0.01	S	Price, 1935	RDSH
10.5	PE	Bieri, Asbrink, et al., 1982	Vertical value; LBLHLM
10.43	PE	Wagner and Bock, 1974	Vertical value; LLK
10.47	PE	Schweig and Thiel, 1974	Vertical value; LLK
10.48	PE	Bock, Wagner, et al., 1972	Vertical value; LLK

Appearance energy determinations

Ion	AE (eV)	Other Products	Method	Reference	Comment
HS⁺	14.300 ± 0.024	H	PI	Prest, Tzeng, et al., 1983	LBLHLM
HS⁺	14.7 ± 0.2	H	EI	Balkis, Gaines, et al., 1976	LLK
HS⁺	14.4	H	EI	Morrison and Traeger, 1973	LLK
HS⁺	14.27 ± 0.02	H	PI	Dibeler and Liston, 1968	RDSH
HS⁺	14.4 ± 0.1	H	EI	Palmer and Lossing, 1962	RDSH
S⁺	13.375 ± 0.022	H₂	PI	Prest, Tzeng, et al., 1983	LBLHLM
S⁺	13.41	H₂	PIPECO	Eland, 1979	LLK
S⁺	13.5	H₂	EI	Morrison and Traeger, 1973	LLK
S⁺	13.36 ± 0.01	H₂	PI	Dibeler and Liston, 1968	RDSH
S⁺	13.40 ± 0.01	H₂	PI	Dibeler and Liston, 1968	RDSH

De-protonation reactions

HS^- + = Hydrogen sulfide

By formula: HS^- + H⁺ = H₂S

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	351.4 ± 0.7	kcal/mol	AVG	N/A	Average of 6 out of 7 values; Individual data points
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	344.4 ± 3.0	kcal/mol	H-TS	Rempala and Ervin, 2000	gas phase; B
Δ_rG°	344.8 ± 2.0	kcal/mol	IMRE	Bartmess, Scott, et al., 1979	gas phase; value altered from reference due to change in acidity scale; B
Δ_rG°	344.90 ± 0.10	kcal/mol	H-TS	Shiell, Hu, et al., 1900	gas phase; 0K:350.125±0.009 kcal/mol, corr to 298K from Gurvich, Veyts, et al., With EA( Breyer, Frey, et al., 1981)BDE(0K)=89.97±0.05; B
Δ_rG°	345.6 ± 2.0	kcal/mol	IMRE	Cumming and Kebarle, 1978	gas phase; B
Δ_rG°	342.30	kcal/mol	N/A	Check, Faust, et al., 2001	gas phase; MnO2-(t); ; ΔS(EA)=5.4; B

Ion clustering data

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Data compiled as indicated in comments:
M - Michael M. Meot-Ner (Mautner) and Sharon G. Lias
B - John E. Bartmess

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Clustering reactions

CH₆N⁺ + Hydrogen sulfide = (CH₆N⁺ • )

By formula: CH₆N⁺ + H₂S = (CH₆N⁺ • H₂S)

Bond type: Hydrogen bond (positive ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	10.8	kcal/mol	PHPMS	Meot-Ner (Mautner) and Sieck, 1985	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	20.	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Sieck, 1985	gas phase; M

Free energy of reaction

Δ_rG° (kcal/mol)	T (K)	Method	Reference	Comment
5.4	270.	PHPMS	Meot-Ner (Mautner) and Sieck, 1985	gas phase; M

CN^- + Hydrogen sulfide = (CN^- • )

By formula: CN^- + H₂S = (CN^- • H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	18.9 ± 1.0	kcal/mol	TDEq	Meot-ner, 1988	gas phase; B
Δ_rH°	19.8 ± 3.5	kcal/mol	IMRE	Larson and McMahon, 1987	gas phase; B,M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	23.8	cal/mol*K	N/A	Larson and McMahon, 1987	gas phase; switching reaction,Thermochemical ladder(CN-)H2O, Entropy change calculated or estimated; Payzant, Yamdagni, et al., 1971; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	12.9 ± 1.0	kcal/mol	TDEq	Meot-ner, 1988	gas phase; B
Δ_rG°	12.4 ± 2.3	kcal/mol	IMRE	Larson and McMahon, 1987	gas phase; B,M

C₃H₇⁺ + Hydrogen sulfide = (C₃H₇⁺ • )

By formula: C₃H₇⁺ + H₂S = (C₃H₇⁺ • H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	32.0	kcal/mol	PHPMS	Meot-Ner (Mautner) and Sieck, 1991	gas phase; condensation; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	34.8	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Sieck, 1991	gas phase; condensation; M

+ Hydrogen sulfide = ( • )

By formula: F^- + H₂S = (F^- • H₂S)

Bond type: Hydrogen bond (negative ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	34.6 ± 2.0	kcal/mol	IMRE	Larson and McMahon, 1983	gas phase; These relative affinities are ca. 10 kcal/mol weaker than threshold values (see Wenthold and Squires, 1995) for donors greater than ca. 27 kcal/mol in free energy. This discrepancy has not yet been resolved, though the stronger value appears preferable.; B,M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	18.8	cal/mol*K	N/A	Larson and McMahon, 1983	gas phase; switching reaction(F-)H2O, Entropy change calculated or estimated; Arshadi, Yamdagni, et al., 1970; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	29.0 ± 2.0	kcal/mol	IMRE	Larson and McMahon, 1983	gas phase; These relative affinities are ca. 10 kcal/mol weaker than threshold values (see Wenthold and Squires, 1995) for donors greater than ca. 27 kcal/mol in free energy. This discrepancy has not yet been resolved, though the stronger value appears preferable.; B,M

F₅S^- + Hydrogen sulfide = (F₅S^- • )

By formula: F₅S^- + H₂S = (F₅S^- • H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	51. ± 12.	kcal/mol	SIFT	Zangerle, Hansel, et al., 1993	gas phase; CID with Ar; M

HS^- + Hydrogen sulfide = (HS^- • )

By formula: HS^- + H₂S = (HS^- • H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	13.2 ± 1.0	kcal/mol	TDAs	Meot-ner, 1988	gas phase; B,M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	19.7	cal/mol*K	PHPMS	Meot-ner, 1988	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rG°	7.3 ± 1.0	kcal/mol	TDAs	Meot-ner, 1988	gas phase; B

H₂S⁺ + Hydrogen sulfide = (H₂S⁺ • )

By formula: H₂S⁺ + H₂S = (H₂S⁺ • H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	21.2	kcal/mol	PI	Prest, Tzeng, et al., 1983, 2	gas phase; M
Δ_rH°	17.0	kcal/mol	PI	Walters and Blais, 1981	gas phase; M

(H₂S⁺ • Hydrogen sulfide ) + = (H₂S⁺ • 2)

By formula: (H₂S⁺ • H₂S) + H₂S = (H₂S⁺ • 2H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	4.2	kcal/mol	PI	Prest, Tzeng, et al., 1983, 2	gas phase; M
Δ_rH°	3.2	kcal/mol	PI	Walters and Blais, 1981	gas phase; M

(H₂S⁺ • 2 Hydrogen sulfide ) + = (H₂S⁺ • 3)

By formula: (H₂S⁺ • 2H₂S) + H₂S = (H₂S⁺ • 3H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	1.2	kcal/mol	PI	Walters and Blais, 1981	gas phase; M

(H₂S⁺ • 3 Hydrogen sulfide ) + = (H₂S⁺ • 4)

By formula: (H₂S⁺ • 3H₂S) + H₂S = (H₂S⁺ • 4H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	1.4	kcal/mol	PI	Walters and Blais, 1981	gas phase; M

(H₂S⁺ • 4 Hydrogen sulfide ) + = (H₂S⁺ • 5)

By formula: (H₂S⁺ • 4H₂S) + H₂S = (H₂S⁺ • 5H₂S)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	2.6	kcal/mol	PI	Walters and Blais, 1981	gas phase; M

H₃S⁺ + Hydrogen sulfide = (H₃S⁺ • )

By formula: H₃S⁺ + H₂S = (H₃S⁺ • H₂S)

Bond type: Hydrogen bond (positive ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	15.4	kcal/mol	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rH°	10.8	kcal/mol	PI	Walters and Blais, 1984	gas phase; M
Δ_rH°	10.6	kcal/mol	PI	Prest, Tzeng, et al., 1983, 2	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	24.4	cal/mol*K	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rS°	17.8	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; Entropy change is questionable; M
Δ_rS°	18.7	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; M

(H₃S⁺ • Hydrogen sulfide ) + = (H₃S⁺ • 2)

By formula: (H₃S⁺ • H₂S) + H₂S = (H₃S⁺ • 2H₂S)

Bond type: Hydrogen bond (positive ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	9.1	kcal/mol	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rH°	6.0	kcal/mol	PI	Walters and Blais, 1984	gas phase; M
Δ_rH°	7.2	kcal/mol	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	20.9	cal/mol*K	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rS°	17.3	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; M

(H₃S⁺ • 2 Hydrogen sulfide ) + = (H₃S⁺ • 3)

By formula: (H₃S⁺ • 2H₂S) + H₂S = (H₃S⁺ • 3H₂S)

Bond type: Hydrogen bond (positive ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	4.4	kcal/mol	PI	Walters and Blais, 1984	gas phase; M
Δ_rH°	8.4	kcal/mol	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rH°	5.4	kcal/mol	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; Entropy change is questionable; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	24.5	cal/mol*K	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rS°	14.	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; Entropy change is questionable; M

(H₃S⁺ • 3 Hydrogen sulfide ) + = (H₃S⁺ • 4)

By formula: (H₃S⁺ • 3H₂S) + H₂S = (H₃S⁺ • 4H₂S)

Bond type: Hydrogen bond (positive ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	6.7	kcal/mol	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rH°	2.5	kcal/mol	PI	Walters and Blais, 1984	gas phase; M
Δ_rH°	3.3	kcal/mol	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; Entropy change is questionable; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	24.7	cal/mol*K	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Δ_rS°	10.	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Field, 1977	gas phase; Entropy change is questionable; M

(H₃S⁺ • 4 Hydrogen sulfide ) + = (H₃S⁺ • 5)

By formula: (H₃S⁺ • 4H₂S) + H₂S = (H₃S⁺ • 5H₂S)

Bond type: Hydrogen bond (positive ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	6.1	kcal/mol	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	24.	cal/mol*K	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M

Free energy of reaction

Δ_rG° (kcal/mol)	T (K)	Method	Reference	Comment
1.7	185.	PHPMS	Hiraoka and Kebarle, 1977	gas phase; M

+ Hydrogen sulfide = ( • )

By formula: H₄N⁺ + H₂S = (H₄N⁺ • H₂S)

Bond type: Hydrogen bond (positive ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	11.4	kcal/mol	PHPMS	Meot-Ner (Mautner) and Sieck, 1985	gas phase; M
Quantity	Value	Units	Method	Reference	Comment
Δ_rS°	16.7	cal/mol*K	PHPMS	Meot-Ner (Mautner) and Sieck, 1985	gas phase; M

+ Hydrogen sulfide = ( • )

By formula: I^- + H₂S = (I^- • H₂S)

Bond type: Hydrogen bond (negative ion to hydride)

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	8.8 ± 1.0	kcal/mol	TDAs	Caldwell, Masucci, et al., 1989	gas phase; B,M

+ Hydrogen sulfide = H₂NOS^-

By formula: NO^- + H₂S = H₂NOS^-

Quantity	Value	Units	Method	Reference	Comment
Δ_rH°	5.60	kcal/mol	N/A	Hendricks, de Clercq, et al., 2002	gas phase; B

IR Spectrum

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Data compiled by: Coblentz Society, Inc.

Gas Phase Spectrum

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Notice: Except where noted, spectra from this collection were measured on dispersive instruments, often in carefully selected solvents, and hence may differ in detail from measurements on FTIR instruments or in other chemical environments. More information on the manner in which spectra in this collection were collected can be found here.

Notice: Concentration information is not available for this spectrum and, therefore, molar absorptivity values cannot be derived.

Additional Data

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Owner	COBLENTZ SOCIETY Collection (C) 2018 copyright by the U.S. Secretary of Commerce on behalf of the United States of America. All rights reserved.
Origin	DOW CHEMICAL COMPANY
Source reference	COBLENTZ NO. 8759
Date	1964
State	GAS (600 mmHg DILUTED TO A TOTAL PRESSURE OF 600 mmHg WITH N2)
Instrument	DOW KBr FOREPRISM
Instrument parameters	GRATING CHANGED AT 5.0, 7.5, 15.0 MICRON
Path length	12.5 CM
Resolution	4
Sampling procedure	TRANSMISSION
Data processing	DIGITIZED BY NIST FROM HARD COPY (FROM TWO SEGMENTS)

This IR spectrum is from the Coblentz Society's evaluated infrared reference spectra collection.

Mass spectrum (electron ionization)

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Data compiled by: NIST Mass Spectrometry Data Center, William E. Wallace, director

Spectrum

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Additional Data

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Due to licensing restrictions, this spectrum cannot be downloaded.

Owner	NIST Mass Spectrometry Data Center Collection (C) 2014 copyright by the U.S. Secretary of Commerce on behalf of the United States of America. All rights reserved.
NIST MS number	43

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Vibrational and/or electronic energy levels

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Data compiled by: Takehiko Shimanouchi

Symmetry: C_2ν Symmetry Number σ = 2

Sym.	No	Approximate	Selected Freq.		Infrared		Raman

Species		type of mode	Value	Rating	Value	Phase	Value	Phase

a₁	1	Sym str	2615	A	2614.6	gas
a₁	2	Bend	1183	A	1182.7	gas
b₁	3	Anti str	2626	B	2626	gas

Source: Shimanouchi, 1972

Notes

0~1 cm^-1 uncertainty

1~3 cm^-1 uncertainty

Gas Chromatography

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Data compiled by: NIST Mass Spectrometry Data Center, William E. Wallace, director

Normal alkane RI, non-polar column, temperature ramp

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Column type	Active phase	I	Reference	Comment
Capillary	PONA	340.	Yang, Wang, et al., 2004	50. m/0.20 mm/0.50 μm, N2, 2. K/min; T_start: 35. C; T_end: 170. C
Capillary	PONA	338.	Yang, Wang, et al., 2003	50. m/0.20 mm/0.50 μm, 2. K/min; T_start: 30. C; T_end: 150. C

Normal alkane RI, non-polar column, custom temperature program

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Column type	Active phase	I	Reference	Comment
Capillary	PONA	338.	Yang, Wang, et al., 2003	50. m/0.20 mm/0.50 μm; Program: not specified

Normal alkane RI, polar column, temperature ramp

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Column type	Active phase	I	Reference	Comment
Capillary	TC-Wax	480.	Ishizaki, Tachihara, et al., 2005	60. m/0.25 mm/0.25 μm, N2, 3. K/min, 220. C @ 40. min; T_start: 70. C

Normal alkane RI, polar column, custom temperature program

View large format table.

Column type	Active phase	I	Reference	Comment
Capillary	TC-Wax	480.	Kraft and Switt, 2005	Program: not specified
Capillary	TC-Wax	480.	Tachihara, Ishizaki, et al., 2004	Program: not specified

References

Go To: Top, Henry's Law data, Gas phase ion energetics data, Ion clustering data, IR Spectrum, Mass spectrum (electron ionization), Vibrational and/or electronic energy levels, Gas Chromatography, Notes

Hunter and Lias, 1998
Hunter, E.P.; Lias, S.G., Evaluated Gas Phase Basicities and Proton Affinities of Molecules: An Update, J. Phys. Chem. Ref. Data, 1998, 27, 3, 413-656, https://doi.org/10.1063/1.556018 . [all data]

Walters and Blais, 1984
Walters, E.A.; Blais, N.C., Molecular beam photoionization and fragmentation of D₂S, (H₂S)₂, (D₂S)₂, and H₂S.H₂O, J. Chem. Phys., 1984, 80, 3501. [all data]

Prest, Tzeng, et al., 1983
Prest, H.F.; Tzeng, W.-B.; Brom, J.M., Jr.; Ng, C.Y., Molecular beam photoionization study of H₂S, Int. J. Mass Spectrom. Ion Processes, 1983, 50, 315. [all data]

Walters and Blais, 1981
Walters, E.A.; Blais, N.C., Molecular beam photoionization of (H₂S)n,n = 1 - 7, J. Chem. Phys., 1981, 75, 4208. [all data]

Smith, Adams, et al., 1981
Smith, D.; Adams, N.G.; Lindinger, W., Reactions of the HnS ions (n = 0 to 3) with several molecular gases at thermal energies, J. Chem. Phys., 1981, 75, 3365. [all data]

Kimura, Katsumata, et al., 1981
Kimura, K.; Katsumata, S.; Achiba, Y.; Yamazaki, T.; Iwata, S., Ionization energies, Ab initio assignments, and valence electronic structure for 200 molecules in Handbook of HeI Photoelectron Spectra of Fundamental Organic Compounds, Japan Scientific Soc. Press, Tokyo, 1981. [all data]

Karlsson, Mattsson, et al., 1976
Karlsson, L.; Mattsson, L.; Jadrny, R.; Bergmark, T.; Siegbahn, K., Vibrational ans vibronic structure in the valence electron spectrum of H₂S, Phys. Scr., 1976, 13, 229. [all data]

Balkis, Gaines, et al., 1976
Balkis, T.; Gaines, A.F.; Ozgen, G.; Ozgen, I.T.; Flowers, M.C., Ionization of hydrogen sul- phide, selenide and telluride by electron impact, J. Chem. Soc. Faraday Trans. 2, 1976, 72, 524. [all data]

Rabalais, Debies, et al., 1974
Rabalais, J.W.; Debies, T.P.; Berkosky, J.L.; Huang, J.-T.J.; Ellison, F.O., Calculated photoionization cross sections relative experimental photoionization intensities for a selection of small molecules, J. Chem. Phys., 1974, 61, 516. [all data]

Natalis, 1973
Natalis, P., Contribution a la spectroscopie photoelectronique. Effets de l'autoionisation dans less spectres photoelectroniques de molecules diatomiques et triatomiques, Acad. R. Belg. Mem. Cl. Sci. Collect. 8, 1973, 41, 1. [all data]

Morrison and Traeger, 1973
Morrison, J.D.; Traeger, J.C., Ionization and dissociation by electron impact. I. H₂O and H₂S, Int. J. Mass Spectrom. Ion Phys., 1973, 11, 77. [all data]

Potts and Price, 1972
Potts, A.W.; Price, W.C., Photoelectron spectra and valence shell orbital structures of groups V VI hydrides, Proc. R. Soc. London A:, 1972, 326, 181. [all data]

Delwiche and Natalis, 1970
Delwiche, J.; Natalis, P., Photoelectron spectrometry of hydrogen sulfide, Chem. Phys. Lett., 1970, 5, 564. [all data]

Delwiche, Natalis, et al., 1970
Delwiche, J.; Natalis, P.; Collin, J.E., High resolution photoelectron spectrometry of H₂S and H₂Se, Intern. J. Mass Spectrom. Ion Phys., 1970, 5, 443. [all data]

Dibeler and Liston, 1968
Dibeler, V.H.; Liston, S.K., Mass-spectrometric study of photoionization. XI.Hydrogen sulfide and sulfur dioxide, J. Chem. Phys., 1968, 49, 482. [all data]

Al-Joboury and Turner, 1964
Al-Joboury, M.I.; Turner, D.W., Molecular photoelectron spectroscopy. Part II. A summary of ionization potentials, J. Chem. Soc., 1964, 4434. [all data]

Frost and McDowell, 1958
Frost, D.C.; McDowell, C.A., Excited states of the molecular ions of hydrogen fluoride, hydrogen iodide, water, hydrogen sulphide, and ammonia, Can. J. Chem., 1958, 36, 39. [all data]

Watanabe, 1954
Watanabe, K., Photoionization and total absorption cross section of gases. I. Ionization potentials of several molecules. Cross sections of NH₃ and NO, J. Chem. Phys., 1954, 22, 1564. [all data]

Price, 1935
Price, W.C., The far ultraviolet absorption spectra and ionization potentials of H₂S, CS₂, and SO₂, Bull. Am. Phys. Soc., 1935, 10, 9. [all data]

Bieri, Asbrink, et al., 1982
Bieri, G.; Asbrink, L.; Von Niessen, W., 30.4-nm He(II) photoelectron spectra of organic molecules, J. Electron Spectrosc. Relat. Phenom., 1982, 27, 129. [all data]

Wagner and Bock, 1974
Wagner, G.; Bock, H., Photoelektronenspektren und molekuleigenschaften, XXVI. Die delokalisation von schwefel-elektronenpaaren in alkylsulfiden und -disulfiden, Chem. Ber., 1974, 107, 68. [all data]

Schweig and Thiel, 1974
Schweig, A.; Thiel, W., Photoionization cross sections: He I- and He II-photoelectron spectra of homologous oxygen and sulphur compounds, Mol. Phys., 1974, 27, 265. [all data]

Bock, Wagner, et al., 1972
Bock, H.; Wagner, G.; Kroner, J., Photoelektronenspektren und molekuleigenschaften, XIV. Die delokalisation des schwefel-elektronenpaar in CH₃S-substituierten aromaten, Chem. Ber., 1972, 105, 3850. [all data]

Palmer and Lossing, 1962
Palmer, T.F.; Lossing, F.P., Free radicals by mass spectrometry. XXVIII. The HS, CH₃S, and phenyl-S radicals: ionization potentials and heats of formation, J. Am. Chem. Soc., 1962, 84, 4661. [all data]

Eland, 1979
Eland, J.H.D., Dissociations of state-selected C₂H₂⁺, H₂S⁺ and D₂S⁺ ions studied by photoelectron-photoion coincidence spectroscopy, Int. J. Mass Spectrom. Ion Phys., 1979, 31, 161. [all data]

Rempala and Ervin, 2000
Rempala, K.; Ervin, K.M., Collisional activation of the Endoergic Hydrogen Atom Transfer Reaction S-(2P) + H2 - SH- + H, J. Chem. Phys., 2000, 112, 10, 4579, https://doi.org/10.1063/1.481016 . [all data]

Bartmess, Scott, et al., 1979
Bartmess, J.E.; Scott, J.A.; McIver, R.T., Jr., The gas phase acidity scale from methanol to phenol, J. Am. Chem. Soc., 1979, 101, 6047. [all data]

Shiell, Hu, et al., 1900
Shiell, R.C.; Hu, X.K.; Hu, Q.J.; Hepburn, J.W., A determination of the bond dissociation energy (D-0(H-SH)): Threshold ion-pair production spectroscopy (TIPPS) of a triatomic molecule, J. Phys. Chem. A, 1900, 104, 19, 4339-4342, https://doi.org/10.1021/jp000025k . [all data]

Gurvich, Veyts, et al.
Gurvich, L.V.; Veyts, I.V.; Alcock, C.B., Hemisphere Publishing, NY, 1989, V. 1 2, Thermodynamic Properties of Individual Substances, 4th Ed. [all data]

Breyer, Frey, et al., 1981
Breyer, F.; Frey, P.; Hotop, H., High Resolution Photoelectron Spectrometry of Negative Ions: Rotational Transitions in Laser-Photodetachment of OH-, SH-, and SD-, Z. Phys. A, 1981, 300, 1, 7, https://doi.org/10.1007/BF01412609 . [all data]

Cumming and Kebarle, 1978
Cumming, J.B.; Kebarle, P., Summary of gas phase measurements involving acids AH. Entropy changes in proton transfer reactions involving negative ions. Bond dissociation energies D(A-H) and electron affinities EA(A), Can. J. Chem., 1978, 56, 1. [all data]

Check, Faust, et al., 2001
Check, C.E.; Faust, T.O.; Bailey, J.M.; Wright, B.J.; Gilbert, T.M.; Sunderlin, L.S., Addition of Polarization and Diffuse Functions to the LANL2DZ Basis Set for P-Block Elements, J. Phys. Chem. A,, 2001, 105, 34, 8111, https://doi.org/10.1021/jp011945l . [all data]

Meot-Ner (Mautner) and Sieck, 1985
Meot-Ner (Mautner), M.; Sieck, L.W., The Ionic Hydrogen Bond and Ion Solvation. 4. SH+ O and NH+ S Bonds. Correlations with Proton Affinity. Mutual Effects of Weak and Strong Ligands in Mixed Clusters, J. Phys. Chem., 1985, 89, 24, 5222, https://doi.org/10.1021/j100270a021 . [all data]

Meot-ner, 1988
Meot-ner, M., Ionic Hydrogen Bond and Ion Solvation. ₆. Interaction Energies of the Acetate Ion with Organic Molecules. Comparison of CH₃COO^- with Cl^-, CN^-, and SH^-, J. Am. Chem. Soc., 1988, 110, 12, 3854, https://doi.org/10.1021/ja00220a022 . [all data]

Larson and McMahon, 1987
Larson, J.W.; McMahon, T.B., Hydrogen bonding in gas phase anions. The energetics of interaction between cyanide ion and bronsted acids, J. Am. Chem. Soc., 1987, 109, 6230. [all data]

Payzant, Yamdagni, et al., 1971
Payzant, J.D.; Yamdagni, R.; Kebarle, P., Hydration of CN-, NO₂-, NO₃-, and HO- in the gas phase, Can. J. Chem., 1971, 49, 3308. [all data]

Meot-Ner (Mautner) and Sieck, 1991
Meot-Ner (Mautner), M.; Sieck, L.W., Proton affinity ladders from variable-temperature equilibrium measurements. 1. A reevaluation of the upper proton affinity range, J. Am. Chem. Soc., 1991, 113, 12, 4448, https://doi.org/10.1021/ja00012a012 . [all data]

Larson and McMahon, 1983
Larson, J.W.; McMahon, T.B., Strong hydrogen bonding in gas-phase anions. An ion cyclotron resonance determination of fluoride binding energetics to bronsted acids from gas-phase fluoride exchange equilibria measurements, J. Am. Chem. Soc., 1983, 105, 2944. [all data]

Wenthold and Squires, 1995
Wenthold, P.G.; Squires, R.R., Bond dissociation energies of F2(-) and HF2(-). A gas-phase experimental and G2 theoretical study, J. Phys. Chem., 1995, 99, 7, 2002, https://doi.org/10.1021/j100007a034 . [all data]

Arshadi, Yamdagni, et al., 1970
Arshadi, M.; Yamdagni, R.; Kebarle, P., Hydration of Halide Negative Ions in the Gas Phase. II. Comparison of Hydration Energies for the Alkali Positive and Halide Negative Ions, J. Phys. Chem., 1970, 74, 7, 1475, https://doi.org/10.1021/j100702a014 . [all data]

Zangerle, Hansel, et al., 1993
Zangerle, R.; Hansel, A.; Richter, R.; Lindinger, W., The Reaction of SF5+ + H2S at Near Thermal Energies: Competition between Association and Binary Reactions, Int. J. Mass Spectrom. Ion Proc., 1993, 129, 117, https://doi.org/10.1016/0168-1176(93)87035-Q . [all data]

Prest, Tzeng, et al., 1983, 2
Prest, H.F.; Tzeng, W.-B.; Brom, J.M., Jr.; Ng, C.Y., Photoionization study of (H₂S)₂ and (H₂S)₃, J. Am. Chem. Soc., 1983, 105, 7531. [all data]

Hiraoka and Kebarle, 1977
Hiraoka, K.; Kebarle, P., Gas Phase Ion Equilibria Studies of the Proton in Hydrogen Sulfide and Hydrogen Sulfide - Water Mixtures. Stabilities of the Hydrogen Bonded Complexes H+(H2S)x(H2O)y, Can. J. Chem., 1977, 55, 1, 24, https://doi.org/10.1139/v77-005 . [all data]

Meot-Ner (Mautner) and Field, 1977
Meot-Ner (Mautner), M.; Field, F.H., Stability, Association and Dissociation in the Cluster Ions H3S+.nH2S, H3O+.nH2O and H3O+.H2O, J. Am. Chem. Soc., 1977, 99, 4, 998, https://doi.org/10.1021/ja00446a004 . [all data]

Caldwell, Masucci, et al., 1989
Caldwell, G.W.; Masucci, J.A.; Ikonomou, M.G., Negative Ion Chemical Ionization Mass Spectrometry - Binding of Molecules to Bromide and Iodide Anions, Org. Mass Spectrom., 1989, 24, 1, 8, https://doi.org/10.1002/oms.1210240103 . [all data]

Hendricks, de Clercq, et al., 2002
Hendricks, J.H.; de Clercq, H.L.; Freidhoff, C.B.; Arnold, S.T.; Eaton, J.G.; Fancher, C.; Lyapustina, S.A.; S., Anion solvation at the microscopic level: Photoelectron spectroscopy of the solvated anion clusters, NO-(Y)(n), where Y=Ar, Kr, Xe, N2O, H2S, NH3, H2O, and C2H4(OH)(2), J. Chem. Phys., 2002, 116, 18, 7926-7938, https://doi.org/10.1063/1.1457444 . [all data]

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

Yang, Wang, et al., 2004
Yang, Y.; Wang, Z.; Zong, B.; Yang, H., Determination of sulfur compounds in fluid catalytic cracking gasoline by gas chromatography with a sulfur chemiluminiscence detector, Chin. J. Chromatogr., 2004, 22, 3, 216-219. [all data]

Yang, Wang, et al., 2003
Yang, Y.-T.; Wang, Z.; Han. J.-H.; Tian, H.-P.; Yang, H.-Y., Determination of sulfur compounds in gasoline fraction of microreactor products by gas chromatography - Atomic emission detector, Petrochemical Technology (Shiyou Huagong), 2003, 32, 11, 995-998. [all data]

Ishizaki, Tachihara, et al., 2005
Ishizaki, S.; Tachihara, T.; Tamura, H.; Yanai, T.; Kitahara, T., Evaluation of odour-active compounds in roasted shrimp (Sergia lucens Hansen) by aroma extract dilution analysis, Flavour Fragr. J., 2005, 20, 6, 562-566, https://doi.org/10.1002/ffj.1484 . [all data]

Kraft and Switt, 2005
Kraft, P.; Switt, K.A.D. (Eds), Perspectives in Flavor and Fragrance Research, Wiley-VCH, Weinheim, Germany, 2005, 251. [all data]

Tachihara, Ishizaki, et al., 2004
Tachihara, T.; Ishizaki, S.; Ishikawa, M.; Kitahara, T., Studies on the volatile compounds of roasted spotted shrimp, Chemistry Biodiversity, 2004, 1, 12, 2024-2033, https://doi.org/10.1002/cbdv.200490155 . [all data]

Notes

Symbols used in this document:

AE	Appearance energy
IE (evaluated)	Recommended ionization energy
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_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
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.
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NIST Chemistry WebBook, SRD 69

Hydrogen sulfide

Data at NIST subscription sites:

Henry's Law data

Henry's Law constant (water solution)

Gas phase ion energetics data

Ionization energy determinations

Appearance energy determinations

De-protonation reactions

Ion clustering data

Clustering reactions

Free energy of reaction

Free energy of reaction

IR Spectrum

Gas Phase Spectrum

Help

Credits

Additional Data

Mass spectrum (electron ionization)

Spectrum

Help

Credits

Additional Data

Vibrational and/or electronic energy levels

Symmetry: C_2ν Symmetry Number σ = 2

Notes

Gas Chromatography

Normal alkane RI, non-polar column, temperature ramp

Normal alkane RI, non-polar column, custom temperature program

Normal alkane RI, polar column, temperature ramp

Normal alkane RI, polar column, custom temperature program

References

Notes

Hydrogen sulfide

Data at NIST subscription sites:

Henry's Law data

Henry's Law constant (water solution)

Gas phase ion energetics data

Ionization energy determinations

Appearance energy determinations

De-protonation reactions

Ion clustering data

Clustering reactions

Free energy of reaction

Free energy of reaction

IR Spectrum

Gas Phase Spectrum

Help

Credits

Additional Data

Mass spectrum (electron ionization)

Spectrum

Help

Credits

Additional Data

Vibrational and/or electronic energy levels

Symmetry: C2ν Symmetry Number σ = 2

Notes

Gas Chromatography

Normal alkane RI, non-polar column, temperature ramp

Normal alkane RI, non-polar column, custom temperature program

Normal alkane RI, polar column, temperature ramp

Normal alkane RI, polar column, custom temperature program

References

Notes

Symmetry: C_2ν Symmetry Number σ = 2