Dimethyl disulfide

624-92-0

METHYL DISULFIDE

Dimethyldisulfide

Dimethyl disulphide

DMDS

Disulfide, dimethyl

2,3-Dithiabutane

(Methyldisulfanyl)methane

Methyldisulfide

Methyldithiomethane

(Methyldithio)methane

Sulfa-hitech

dimethyldisulphide

FEMA No. 3536

NSC 9370

1,2-Dimethyldisulfane

CCRIS 2939

HSDB 6400

EINECS 210-871-0

UNII-3P8D642K5E

CHEBI:4608

Dimethyl-d6 disulfide

AI3-25305

3P8D642K5E

NSC-9370

MFCD00008561

DTXSID4025117

(CH3S)2

EC 210-871-0

Paladin

UN2381

dimethydisulfide

methyl disulphide

Dimethyl disulfane

Disulfide dimethyl

MeS-SMe

Disulfide, dimethyl-

methyldisulfanyl methane

Dimethyl disulfide, 98%

Dimethyl disulfide, 99%

(Methyldisulfanyl)methane #

Dimethyl disulfide, >=99%

WLN: 1SS1

DTXCID805117

METHYL DISULFIDE [HSDB]

CHEMBL1347061

Dimethyl disulfide, >=99.0%

DIMETHYL DISULFIDE [FHFI]

NSC9370

BDBM233038

Dimethyl disulfide, >=98%, FG

AMY39506

EINECS 272-923-9

Tox21_201525

AKOS009157459

Dimethyl disulfide, analytical standard

MCULE-7451882535

UN 2381

NCGC00091798-01

NCGC00091798-02

NCGC00259075-01

CAS-624-92-0

Dimethyl disulfide, natural, >=98%, FG

D0714

Dimethyl disulfide, purum, >=98.0% (GC)

NS00001484

EN300-36043

InChI=1/C2H6S2/c1-3-4-2/h1-2H

C08371

E78981

A833808

Dimethyl disulfide [UN2381] [Flammable liquid]

Q419800

Q-100719

F0001-1676

The Henry's Law constant for dimethyl disulfide is reported as 1.21X10-3 atm-cu m/mole(1). This Henry's Law constant indicates that dimethyl disulfide is expected to volatilize rapidly from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 3.5 hours(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 4.1 days(SRC). Dimethyl disulfide's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). In a laboratory study, the volatilization rate of dimethyl disulfide from a tidal marsh soil (at field capacity or 1.5 field capacity) ranged from 0.1 to 0.4 ng (sulfur basis)/min(3). Dimethyl disulfide is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 28.7 mm Hg(4).
Literature: (1) Vitenberg AG et al; J Chromatography 112: 319-27 (1975) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Farwell SO et al; Soil Biol Biochem 11: 411-5 (1979) (4) Daubert TE, Danner RP; Physical & Thermodynamic Properties of Pure Chemicals: Data Compilation. New York, NY: Hemisphere Pub Corp (1989)

Using a structure estimation method based on molecular connectivity indices(1), the Koc of dimethyl disulfide can be estimated to be 40(SRC). According to a classification scheme(2), this estimated Koc value suggests that dimethyl disulfide is expected to have very high mobility in soil. Gas chromatographic studies with various air-dry and moist soils have shown that soil can sorb atmospheric, gas phase dimethyl disulfide(3). In one closed-system test, 17-94% of input dimethyl disulfide was sorbed by the soil in 10 min(3); in a 15-day test, dimethyl disulfide sorption was 101-306 ug sorbed/g soil(3). Soil microbes were found to be important for the gas phase sorption of dimethyl disulfide as 15-day sorption in sterilized soil was only 9-98 ug sorbed/g soil(3).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Jan, 2011. Available from, as of Nov 7, 2013: http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm (2) Swann RL et al; Res Rev 85: 17-28 (1983) (3) Bremner JM, Banwart WL; Soil Biol Biochem 8: 79-83 (1976)

lauric acid

DODECANOIC ACID

143-07-7

n-Dodecanoic acid

Dodecylic acid

Vulvic acid

Laurostearic acid

Dodecoic acid

Duodecylic acid

1-Undecanecarboxylic acid

Aliphat No. 4

Ninol AA62 Extra

Wecoline 1295

Hydrofol acid 1255

Hydrofol acid 1295

Duodecyclic acid

Hystrene 9512

Univol U-314

Lauric acid, pure

Dodecylcarboxylate

Lauric acid (natural)

Laurinsaeure

Undecane-1-carboxylic acid

ABL

NSC-5026

FEMA No. 2614

laurate

C-1297

Philacid 1200

CCRIS 669

C12:0

Emery 651

Lunac L 70

CHEBI:30805

HSDB 6814

EINECS 205-582-1

UNII-1160N9NU9U

BRN 1099477

n-Dodecanoate

Kortacid 1299

Dodecanoic Acid Anion

DTXSID5021590

Prifrac 2920

AI3-00112

Lunac L 98

Univol U 314

Prifac 2920

1160N9NU9U

MFCD00002736

DAO

DTXCID801590

CH3-[CH2]10-COOH

NSC5026

EC 205-582-1

dodecylate

laurostearate

vulvate

4-02-00-01082 (Beilstein Handbook Reference)

DODECANOIC ACID (LAURIC ACID)

1-undecanecarboxylate

LAURIC ACID (USP-RS)

LAURIC ACID [USP-RS]

CH3-(CH2)10-COOH

8000-62-2

CAS-143-07-7

SMR001253907

laurinsaure

dodecanic acid

Nuvail

lauric-acid

Acide Laurique

n-Dodecanoicacid

3uil

Lauric acid (NF)

DODECANOICACID

fatty acid 12:0

Lauric Acid, Reagent

Nissan NAA 122

Emery 650

Dodecanoic acid, 98%

Dodecanoic acid, 99%

Guaranteed Reagent,99%

Dodecanoic (Lauric) acid

LAURIC ACID [MI]

bmse000509

LAURIC ACID [FCC]

LAURIC ACID [FHFI]

LAURIC ACID [INCI]

SCHEMBL5895

NCIOpen2_009480

MLS002177807

MLS002415737

WLN: QV11

Dodecanoic acid (lauric acid)

LAURIC ACID [WHO-DD]

Dodecanoic acid, >=99.5%

Edenor C 1298-100

DODECANOIC ACID [HSDB]

CHEMBL108766

GTPL5534

NAA 122

NAA 312

HMS2268C14

HMS3649N06

HY-Y0366

STR08039

Dodecanoic acid, analytical standard

Lauric acid, >=98%, FCC, FG

Tox21_202149

Tox21_303010

BDBM50180948

LMFA01010012

s4726

STL281860

AKOS000277433

CCG-266587

DB03017

FA 12:0

MCULE-2795129925

HYDROFOL ACID 1255 OR 1295

NCGC00090919-01

NCGC00090919-02

NCGC00090919-03

NCGC00256486-01

NCGC00259698-01

AC-16451

BP-27913

Dodecanoic acid, >=99% (GC/titration)

LAU

Dodecanoic acid, purum, >=96.0% (GC)

Lauric acid, natural, >=98%, FCC, FG

CS-0015078

L0011

NS00008441

EN300-19951

C02679

D10714

A808010

LAURIC ACID (CONSTITUENT OF SAW PALMETTO)

Q422627

SR-01000838338

J-007739

SR-01000838338-3

F0001-0507

LAURIC ACID (CONSTITUENT OF SAW PALMETTO) [DSC]

Z104476194

76C2A2EB-E8BA-40A6-8032-40A98625ED7B

Lauric acid, European Pharmacopoeia (EP) Reference Standard

Lauric acid, United States Pharmacopeia (USP) Reference Standard

Lauric Acid, Pharmaceutical Secondary Standard; Certified Reference Material

203714-07-2

7632-48-6

InChI=1/C12H24O2/c1-2-3-4-5-6-7-8-9-10-11-12(13)14/h2-11H2,1H3,(H,13,14

A pKa of 5.3(1) indicates dodecanoic acid will exist almost entirely in the anion form at pH values of 5 to 9 and therefore volatilization from water surfaces and moist soil is not expected to be an important fate process(2). Dodecanoic acid is not expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 1.6X10-5 mm Hg(3).
Literature: (1) Serjeant EP, Dempsey B; IUPAC Chemical Data Series No 23 NY, NY: Pergamon Press (1979) (2) Doucette WJ; pp. 141-188 in Handbook of Property Estimation Methods for Chemicals. Boethling RS, Mackay D, eds. Boca Raton, FL: Lewis Publ (2000) (3) Yaws CL; Handbook of Vapor Pressure. Vol 3: C8-C28 Compounds. Houston, TX: Gulf Pub Co (1994)

The Koc of undissociated dodecanoic acid is estimated as 7,600 for the free acid(SRC), using a log Kow of 4.60(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that undissociated dodecanoic acid is expected to be immobile in soil. The pKa of dodecanoic acid is 5.3(4) , indicating that this compound will exist almost entirely in anion form in the environment and anions generally do not adsorb more strongly to soils containing organic carbon and clay than their neutral counterparts(5).
Literature: (1) Sangster J; LOGKOW Databank. Sangster Res Lab Montreal Quebec, Canada (1994) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 4-9 (1990) (3) Swann RL et al; Res Rev 85: 17-28 (1983) (4) Serjeant EP, Dempsey B; IUPAC Chemical Data Series No 23 NY, NY: Pergamon Press (1979) (5) Doucette WJ; pp. 141-188 in Handbook of Property Estimation Methods for Chemicals. Boethling RS, Mackay D, eds. Boca Raton, FL: Lewis Publ (2000)

acetoin

3-hydroxy-2-butanone

513-86-0

3-hydroxybutan-2-one

acetylmethylcarbinol

Dimethylketol

Acetyl methyl carbinol

2-Butanone, 3-hydroxy-

2,3-Butanolone

2-Hydroxy-3-butanone

1-Hydroxyethyl methyl ketone

Methanol, acetylmethyl-

Acetoin (natural)

gamma-Hydroxy-beta-oxobutane

3-hydroxyl-2-butanone

FEMA No. 2008

CCRIS 2918

HSDB 974

.gamma.-Hydroxy-.beta.-oxobutane

DL-Acetoin

NSC 7609

2-Acetoin

2-Butanol-3-one

AI3-03314

(+/-)-Acetoin

2-hydroxy-3-oxobutane

BG4D34CO2H

51555-24-9

DTXSID0024399

(+/-)-3-Hydroxybutan-2-one

NSC-7609

MFCD00004521

Acethoin

Butan-2-ol-3-one

EINECS 208-174-1

UN2621

UNII-BG4D34CO2H

1-Hydroxethyl methyl ketone

acetoine

BRN 0385636

acetylmethyl-

beta-oxobutane

2-Butanone, 3-hydroxy-, (R)-

b-oxobutane

Acetoin dimer

3-Oxo-2-butanol

ACETOIN MONOMER

DI-METHYLKETOL

Methanol, acetylmethyl

3-hydroxy-2-oxobutane

2-butanone, 3-hydroxy

3-hydroxy-butan-2-one

ACETOIN (DIMER)

Acetoin (~90%)

ACETOIN [FHFI]

ACETOIN [HSDB]

3-hydroxy-butane-2-one

ACETOIN [MI]

ACETOIN (MONOMER)

Acetoin, analytical standard

Butan-2-one, 3-hydroxy-

Acetoin, >=96%, natural

2-01-00-00870 (Beilstein Handbook Reference)

BUTAN-2-0L-3-ONE

DTXCID304399

ACETOIN (DIMER) [FCC]

CHEMBL3561873

CHEBI:15688

ACETOIN (MONOMER) [FCC]

NSC7609

Acetoin, natural, >=95%, FG

ACETOIN(MAY INCLUDE DIMER)

Acetoin, >=96%, FCC, FG

(S)-3-HYDROXY-2-BUTANONE

NSC89727

Tox21_302518

LMFA12000020

NSC-89727

AKOS000121293

AKOS017278202

MCULE-5374414264

UN 2621

2-Butanone, 3-hydroxy- (8CI,9CI)

Acetoin, May exist as crystalline dimer

Acetoin (may exist as crystalline dimer)

NCGC00256914-01

2-Butanone, 3-hydroxy-, (.+/-.)-

CAS-513-86-0

PD124062

3-Hydroxybutan-2-one (may include dimer)

DB-003392

H0225

NS00011932

EN300-21639

C00466

D93492

Q223083

Q-200581

Acetyl methyl carbinol [UN2621] [Flammable liquid]

2,3,5,6- TETRAMETHYL-1,4-DIOXANE-2,5-DIOL

F0001-1338

The Henry's Law constant for acetoin is estimated as 1.0X0-5 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that acetoin is expected to volatilize from water surfaces(2). Based on this Henry's Law constant, the volatilization half-life from a model river (1 m deep, flowing 1 m/sec, wind velocity of 3 m/sec)(2) is estimated as 2 days(SRC). The volatilization half-life from a model lake (1 m deep, flowing 0.05 m/sec, wind velocity of 0.5 m/sec)(2) is estimated as 28 days(SRC). Acetoin's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Acetoin is expected to volatilize from dry soil surfaces(SRC) based upon an estimated vapor pressure of 2.7 mm Hg(SRC), determined from a fragment constant method(3).
Literature: (1) Meylan WM, Howard PH; Environ Toxicol Chem 10: 1283-93 (1991) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Lyman WJ; p. 31 in Environmental Exposure From Chemicals Vol I, Neely WB, Blau GE, eds, Boca Raton, FL: CRC Press (1985)

The Koc of acetoin is estimated as 2(SRC), using a water solubility of 1.0X10+6 mg/L(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that aetoin is expected to have very high mobility in soil.
Literature: (1) Yalkowsky SH, Dannenfelser RM; The AQUASOL DATABASE of Aqueous Solubility. Ver 5. Tucson, AZ: Univ AZ, College of Pharmacy (1992) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 4-5 (1990) (3) Swann RL et al; Res Rev 85: 17-28 (1983)