acetic acid

ethanoic acid

64-19-7

Acetic acid glacial

Ethylic acid

Vinegar acid

Glacial acetic acid

Acetic acid, glacial

Methanecarboxylic acid

Acetasol

Essigsaeure

Acide acetique

Pyroligneous acid

Vinegar

Azijnzuur

Aceticum acidum

Acido acetico

Octowy kwas

Aci-jel

HOAc

ethoic acid

Kyselina octova

Orthoacetic acid

AcOH

Azijnzuur [Dutch]

Ethanoic acid monomer

Acetic

Essigsaeure [German]

Caswell No. 003

Otic Tridesilon

Octowy kwas [Polish]

Acetic acid (natural)

Acide acetique [French]

Acido acetico [Italian]

FEMA No. 2006

Kyselina octova [Czech]

MeCOOH

Acetic acid-17O2

Otic Domeboro

Acidum aceticum glaciale

Acidum aceticum

CH3-COOH

acetic acid-

CH3CO2H

UN2789

UN2790

EPA Pesticide Chemical Code 044001

NSC 132953

NSC-132953

NSC-406306

BRN 0506007

Acetic acid, diluted

INS NO.260

Acetic acid [JAN]

DTXSID5024394

MeCO2H

CHEBI:15366

AI3-02394

CH3COOH

INS-260

Q40Q9N063P

E-260

10.Methanecarboxylic acid

CHEMBL539

NSC-111201

NSC-112209

NSC-115870

NSC-127175

Acetic acid-2-13C,d4

INS No. 260

DTXCID304394

E 260

Acetic-13C2 acid (8CI,9CI)

Ethanoat

Shotgun

MFCD00036152

Acetic acid, of a concentration of more than 10 per cent, by weight, of acetic acid

285977-76-6

68475-71-8

C2:0

acetyl alcohol

Orlex

Vosol

ACETIC-1-13C-2-D3 ACID-1 H (D)

WLN: QV1

ACETIC ACID (MART.)

ACETIC ACID [MART.]

Acetic acid, >=99.7%

57745-60-5

63459-47-2

FEMA Number 2006

ACETIC-13C2-2-D3 ACID, 97 ATOM % 13C, 97 ATOM % D

Acetic acid, ACS reagent, >=99.7%

ACY

HSDB 40

CCRIS 5952

79562-15-5

methane carboxylic acid

EINECS 200-580-7

Acetic acid 0.25% in plastic container

Essigsaure

Ethylate

acetic aicd

acetic-acid

Glacial acetate

acetic cid

actic acid

UNII-Q40Q9N063P

acetic -acid

Distilled vinegar

Methanecarboxylate

Acetic acid, glacial [USP:JAN]

Acetasol (TN)

Acetic acid,glacial

Carboxymethyl radical

for LC-MS

Vinegar (Salt/Mix)

HOOCCH3

546-67-8

Acetic acid LC/MS Grade

ACETIC ACID [II]

ACETIC ACID [MI]

Acetic acid, ACS reagent

bmse000191

bmse000817

bmse000857

Otic Domeboro (Salt/Mix)

EC 200-580-7

Acetic acid (JP17/NF)

ACETIC ACID [FHFI]

ACETIC ACID [INCI]

Acetic Acid [for LC-MS]

ACETIC ACID [VANDF]

NCIOpen2_000659

NCIOpen2_000682

Acetic acid, glacial (USP)

4-02-00-00094 (Beilstein Handbook Reference)

77671-22-8

Glacial acetic acid (JP17)

UN 2790 (Salt/Mix)

ACETIC ACID [WHO-DD]

ACETIC ACID [WHO-IP]

ACETICUM ACIDUM [HPUS]

GTPL1058

Acetic Acid Glacial HPLC Grade

Acetic acid, analytical standard

Acetic acid, Glacial USP grade

Acetic acid, puriss., >=80%

Acetic acid, 99.8%, anhydrous

Acetic acid, AR, >=99.8%

Acetic acid, LR, >=99.5%

DTXSID001043500

Acetic acid, extra pure, 99.8%

Acetic acid, 99.5-100.0%

Acetic acid, Glacial, ACS Reagent

STR00276

Acetic acid, puriss., 99-100%

Tox21_301453

Acetic acid, glacial, >=99.85%

BDBM50074329

FA 2:0

LMFA01010002

NSC132953

NSC406306

STL264240

Acetic acid, for HPLC, >=99.8%

AKOS000268789

ACIDUM ACETICUM [WHO-IP LATIN]

DB03166

MCULE-8295936189

UN 2789

Acetic acid, >=99.5%, FCC, FG

Acetic acid, natural, >=99.5%, FG

Acetic acid, ReagentPlus(R), >=99%

CAS-64-19-7

USEPA/OPP Pesticide Code: 044001

Acetic acid, USP, 99.5-100.5%

NCGC00255303-01

Acetic acid 1000 microg/mL in Methanol

Acetic acid, SAJ first grade, >=99.0%

DB-085748

Acetic acid 1000 microg/mL in Acetonitrile

Acetic acid, >=99.99% trace metals basis

Acetic acid, JIS special grade, >=99.7%

Acetic acid, purified by double-distillation

NS00002089

Acetic acid, UV HPLC spectroscopic, 99.9%

EN300-18074

Acetic acid, Vetec(TM) reagent grade, >=99%

Bifido Selective Supplement B, for microbiology

C00033

D00010

ORLEX HC COMPONENT ACETIC ACID, GLACIAL

Q47512

VOSOL HC COMPONENT ACETIC ACID, GLACIAL

Acetic acid, glacial, electronic grade, 99.7%

TRIDESILON COMPONENT ACETIC ACID, GLACIAL

A834671

ACETASOL HC COMPONENT ACETIC ACID, GLACIAL

Acetic acid, >=99.7%, SAJ super special grade

ACETIC ACID, GLACIAL COMPONENT OF BOROFAIR

ACETIC ACID, GLACIAL COMPONENT OF ORLEX HC

ACETIC ACID, GLACIAL COMPONENT OF VOSOL HC

SR-01000944354

ACETIC ACID, GLACIAL COMPONENT OF TRIDESILON

SR-01000944354-1

ACETIC ACID, GLACIAL COMPONENT OF ACETASOL HC

Glacial acetic acid, meets USP testing specifications

InChI=1/C2H4O2/c1-2(3)4/h1H3,(H,3,4

Acetic acid, >=99.7%, suitable for amino acid analysis

Acetic acid, >=99.7%, for titration in non-aqueous medium

Acetic acid, for luminescence, BioUltra, >=99.5% (GC)

Acetic acid, p.a., ACS reagent, reag. ISO, reag. Ph. Eur., 99.8%

Acetic acid, semiconductor grade MOS PURANAL(TM) (Honeywell 17926)

Glacial acetic acid, United States Pharmacopeia (USP) Reference Standard

Acetic acid, puriss. p.a., ACS reagent, reag. ISO, reag. Ph. Eur., >=99.8%

Glacial Acetic Acid, Pharmaceutical Secondary Standard; Certified Reference Material

158461-04-2

2887-46-9

Acetic acid, puriss., meets analytical specification of Ph. Eur., BP, USP, FCC, 99.8-100.5%

The Henry's Law constant for acetic acid has been experimentally determined to be 1.43X10-7 atm-cu m/mole at 25 deg C(1). This Henry's Law constant indicates that acetic acid is expected to be essentially nonvolatile from water surfaces(2). Acetic acid's Henry's Law constant indicates that volatilization from moist soil surfaces is not expected to be an important fate process(SRC). Acetic acid is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 15.7 mm Hg at 25 deg C(3).
Literature: (1) Johnson BJ et al; J Atmos Chem 24: 113-119 (1996) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals: Data Compilation. Design Inst Phys Prop Data, Amer Inst Chem Eng. New York, NY: Hemisphere Pub Corp (1989)

A log Koc of 0.00 (Koc = 1), which was derived from experimental measurements, has been reported for acetic acid(1,2). According to a classification scheme(3), this Koc value suggests that acetic acid is expected to have very high mobility in soil. No detectable sorption was measured for acetic acid using the OECD Guideline 106 method employing an acidic forest soil, pH 2.8, an agricultural soil, pH 6.7, and a lake sediment, pH 7.1(4). Adsorption of acetic acid to 3 nearshore marine sediments collected from three different locations resulted in Kd values of 0.65 (Koc = 228), 0.085 (Koc = 6.5) and 0.046 (Koc = 27) using clastic mud (3.5% organic carbon, pH 7.0), muddy sand (1.3% organic carbon, pH 7.7), and carbonate sand (0.17% organic carbon, pH 8.1), respectively(5). The pKa of acetic acid is 4.76(6), indicating that this compound will exist partially 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(7).
Literature: (1) Schuurmann G et al; Environ Sci Technol 40: 7005-7011 (Supplemental material) (2006) (2) Meylan WM et al; Environ Sci Technol 26: 1560-7 (1992) (3) Swann RL et al; Res Rev 85: 17-28 (1983) (4) Von Oepen B et al; Chemosphere 22: 285-304 (1991) (5) Sansone JF et al; Geochimica et Cosmochimica Acta 51: 1889-1896 (1987) (6) Serjeant EP, Dempsey B; Ionisation Constants of Organic Acids in Aqueous Solution. IUPAC Chemical Data Series No. 23. New York, NY: Pergamon Press, p. 989 (1979) (7) Doucette WJ; pp. 141-188 in Handbook of Property Estimation Methods for Chemicals. Boethling RS, Mackay D, eds. Boca Raton, FL: Lewis Publ (2000)
Literature: #In 24 hr aqueous adsorption studies using montmorillonite and kaolinite clay adsorbents, 2.4-30.4% of added acetic acid was observed to be in the adsorbed phase(1). In adsorption studies using the adsorbent hydroxyapatite (a mineral which occurs in the environment as a result of the diagenesis of skeletal apatite), only 5% of added acetic acid (in aqueous solution, pH 8.0) became adsorbed to the hydroxyapatite(2). Acetic acid has been noted to leach from biological disposal areas(3).
Literature: (1) Hemphill L, Swanson WS; Proc of the 18th Industrial Waste Conf, Eng Bull Purdue Univ, Lafayette IN 18: 204-17 (1964) (2) Gordon AS, Millero FJ; Microb Ecol 11: 289-98 (1985) (3) Abrams EF et al; Identification of Organic Compounds in Effluents from Industrial Sources. USEPA-560/3-75-002 p. 3 (1975)

2,3-PENTANEDIONE

pentane-2,3-dione

600-14-6

Acetylpropionyl

Acetyl propionyl

2,3-Pentadione

Acetylpropionyl (VAN)

FEMA No. 2841

2,3-pentane-dione

Pentan-2,3-dione

ethyl methyl diketone

K4WBE45SCM

CH3C(O)C(O)C2H5

CHEBI:52774

NSC-7613

MFCD00009313

Acetyl propionyl (natural)

2,3-pentandione

CCRIS 2946

NSC 7613

EINECS 209-984-8

UNII-K4WBE45SCM

BRN 1699638

2,3,-pentanedione

23-PENTANEDIONE

2,3-Pentanedione, 97%

4-01-00-03660 (Beilstein Handbook Reference)

Acetylpropionyl; NSC 7613

SCHEMBL106990

CHEMBL192809

DTXSID6051435

BDBM22765

FEMA 2841

HSDB 8326

2,3-PENTANEDIONE [FCC]

AMY4046

NSC7613

2,3-PENTANEDIONE [FHFI]

2,3-Pentanedione, analytical standard

AKOS009156847

CS-W013714

HY-W012998

MCULE-3065014067

2,3-Pentanedione, >=96%, FCC, FG

PD164983

2,3-Pentanedione, natural, >=96%, FG

DB-003231

NS00013104

P0051

EN300-39756

Q-100694

Q19903182

InChI=1/C5H8O2/c1-3-5(7)4(2)6/h3H2,1-2H

The Henry's Law constant for 2,3-pentanedione is estimated as 3.95X10-5 atm-cu m/mole(SRC) derived from its vapor pressure, 20 mm Hg(1), and water solubility, 6.67X10+4 mg/L(2). This Henry's Law constant indicates that 2,3-pentanedione is expected to volatilize from water surfaces(3). 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)(3) is estimated as 16 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)(3) is estimated as 11 days(SRC). 2,3-Pentanedione's estimated Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). The potential for volatilization of 2,3-pentanedione from dry soil surfaces may exist based upon its vapor pressure(1).
Literature: (1) US Occupational Safety & Health Administration; Chemical Sampling Information. 2,3-Pentanedione. Available from, as of June 9, 2016 https://www.osha.gov/dts/chemicalsampling/data/CH_260240.html (2) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of June 9, 2016: http://www2.epa.gov/tsca-screening-tools (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990)

Using a structure estimation method based on molecular connectivity indices(1), the Koc of 2,3-pentanedione can be estimated to be 1(SRC). According to a classification scheme(2), this estimated Koc value suggests that 2,3-pentanedione is expected to have very high mobility in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of June 9, 2016: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 17-28 (1983)

2,3-butanedione

diacetyl

biacetyl

Butane-2,3-dione

431-03-8

dimethylglyoxal

Butanedione

dimethyl diketone

2,3-diketobutane

Dimethyl glyoxal

2,3-Butadione

2,3-dioxobutane

butadione

Glyoxal, dimethyl-

2,3-butandione

Diacetyl (natural)

FEMA No. 2370

Butan-2,3-dione

CCRIS 827

HSDB 297

NSC 8750

MFCD00008756

UN2346

2,3-Butanedione-13C2

AI3-03313

K324J5K4HM

DTXSID6021583

CHEBI:16583

NSC-8750

2.3-butanedione

EINECS 207-069-8

BRN 0605398

UNII-K324J5K4HM

butane 2

butane-2

Biacetyl; BDM

2,3 butandione

Buta-2,3-dione

DIACETYL [FHFI]

DIACETYL [HSDB]

DIACETYL [FCC]

Butanedione [UN2346] [Flammable liquid]

DIACETYL [MI]

Lopac-D-3634

Butanedione [UN2346]

2,3-Butanedione, 97%

Lopac0_000387

4-01-00-03644 (Beilstein Handbook Reference)

Diacetyl, natural, >=95%

WLN: 1VV1

(CH3CO)2

CHEMBL365809

DTXCID701583

SGCUT00113

2,3-Butanedione (8CI,9CI)

BDBM22725

NSC8750

HMS3261M15

to_000005

Tox21_201218

Tox21_500387

LMFA12000012

2,3-Butanedione, analytical standard

AKOS000118816

Diacetyl 1000 microg/mL in Methanol

CCG-204481

LP00387

MCULE-5742661187

SDCCGSBI-0050374.P002

NCGC00015336-01

NCGC00015336-02

NCGC00015336-03

NCGC00015336-04

NCGC00015336-05

NCGC00015336-06

NCGC00015336-07

NCGC00090746-01

NCGC00090746-02

NCGC00090746-03

NCGC00258770-01

NCGC00261072-01

CAS-431-03-8

DB-003226

B0682

Butanedione [UN2346] [Flammable liquid]

EU-0100387

NS00003558

EN300-19494

C00741

D 3634

W18292

A826155

Q408916

SR-01000075811

InChI=1/C4H6O2/c1-3(5)4(2)6/h1-2H

SR-01000075811-1

DEE64962-0BD5-454C-8BDA-FDBD33C47181

F0001-1188

BUO

The Henry's Law constant for diacetyl is 1.33X10-5 atm-cu m/mole(1). This Henry's Law constant indicates that diacetyl 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 2.7 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 22 days(SRC). Diacetyl's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Diacetyl is expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 56.8 mm Hg(3).
Literature: (1) Betterton EA; Atmos Environ 25A:1473-7 (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) Boublik T et al; The vapor pressures of pure substances. Vol. 17. Amsterdam, Netherlands: Elsevier Sci. Publ (1984)

The Koc of diacetyl is estimated as 1(SRC), using a log Kow of -1.34(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that diacetyl is expected to have very mobility in soil.
Literature: (1) Hansch C et al; Exploring QSAR. Hydrophobic, Electronic, and Steric Constants. ACS Prof Ref Book. Heller SR, consult. ed., Washington, DC: Amer Chem Soc p. 9 (1995) (2) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of May 31, 2016: http://www2.epa.gov/tsca-screening-tools (3) Swann RL et al; Res Rev 85: 17-28 (1983)

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)