BENZENEDICARBOXYLICACID

Naphthalinate

o-Benzenedicarboxylate

PHTHALICACID

Alizarinate

Phthalinate

Naphthalinic acid

o-benzenedicarboxylic acid

o-Carboxybenzoate

o-dicarboxybenzene

Orthophthalic acid

XNGIFLGASWRNHJ-UHFFFAOYSA-N

Acide phtalique

Alizarinic acid

Kyselina ftalova

Phthalinic acid

phthals

Pathalic acid

phthalic acid

o-Carboxybenzoic acid

Pathalc acd

phthalsäure

ortho-phthalic acid

4kww

AC1L1AJQ

AC1Q1HCJ

Phthalate standard for IC

Phthalic acid, analytical standard

o-phthalic acid

1,2-benzenedicarboxylic acid

3,4-benzenedicarboxylic acid

CHEMBL1045

PHTHALIC ACID, ACS

SCHEMBL1808

Sunftal 20

Acide phtalique [French]

Kyselina ftalova [Czech]

s164

ACMC-209qya

NSC5348

6O7F7IX66E

H2983

HMDB02107

P0287

WLN: QVR BVQ

ZINC90750

benzene-1,2-dicarboxylic acid

DB02746

Phthalic acid, ~99%

RP22870

bmse000391

C01606

CCRIS 1446

HMS3039E17

HMS3604J03

HSDB 1339

Phthalic acid, European Pharmacopoeia (EP) Reference Standard

UNII-6O7F7IX66E

AK116685

BBL023724

DTXSID8021484

LS-1890

NSC 5348

NSC-5348

OR025173

OR183112

OR253495

OR331083

SBB058481

STL168879

benzene-1,2-dioic acid

CHEBI:29069

DSSTox_CID_1484

Phthalic acid, United States Pharmacopeia (USP) Reference Standard

AB1002491

AC-14464

AJ-10847

AN-20569

AN-24158

ANW-39200

BP-21159

DSSTox_GSID_21484

KB-59631

SC-67693

SC-74953

BDBM50080272

DSSTox_RID_76178

MFCD00002467

PHTHALIC ACID (CARBOXYL-13C)

AI3-02409

RTR-027988

ST24031536

ST50192167

AKOS000118898

I01-7091

J-523870

Phthalic acid, 99.5%

Phthalic acid, reagent grade, 98%

Z57127456

BRN 0608199

FT-0622644

MLS002152931

SMR001224528

88-99-3

1,2-Propylene glycol, bis(isooctyl phthalate)

Tox21_200915

3B1-008717

F3110-2832

CAS-88-99-3

4401-64-3

MCULE-4747891013

NCGC00090869-01

NCGC00090869-02

NCGC00258469-01

Phthalic acid, ACS reagent, >=99.5%

EINECS 201-873-2

Phthalic acid, SAJ special grade, >=99.0%

Phthalic acid, SAJ first grade, >=99.0%

Phthalic acid, Vetec(TM) reagent grade, 98%

1,2-Benzenedicarboxylic acid, 1-methyl-1,2-ethanediyl diisooctyl ester

MolPort-000-690-820

21176-EP2269988A2

21176-EP2270008A1

21176-EP2275413A1

21176-EP2284165A1

21176-EP2284178A2

21176-EP2284179A2

21176-EP2287156A1

21176-EP2292597A1

21176-EP2292617A1

21176-EP2295406A1

21176-EP2295438A1

21176-EP2298731A1

21176-EP2301924A1

21176-EP2301940A1

21176-EP2305219A1

21176-EP2305248A1

21176-EP2305663A1

21176-EP2305672A1

21176-EP2311807A1

21176-EP2311815A1

21176-EP2311824A1

21176-EP2314295A1

21176-EP2371805A1

21176-EP2374780A1

21176-EP2374781A1

21176-EP2374895A1

AB-131/40237186

827-27-0 (mono-hydrochloride salt)

10197-71-4 (hydrochloride salt)

877-24-7 (mono-potassium salt)

29801-94-3 (potassium salt)

15968-01-1 (di-hydrochloride salt)

4409-98-7 (di-potassium salt)

5793-85-1 (mono-calcium salt)

15656-86-7 (mono-barium salt)

33227-10-0 (mono-Ru salt)

4-09-00-03167 (Beilstein Handbook Reference)

Phthalic acid, ACS, 99.5% min. 100g

Phthalic acid, puriss. p.a., >=99.5% (T)

6838-85-3 (mono-lead(2+) salt)

InChI=1/C8H6O4/c9-7(10)5-3-1-2-4-6(5)8(11)12/h1-4H,(H,9,10)(H,11,12

The Henry's Law constant for phthalic acid is estimated as 2X10-11 atm-cu m/mole(SRC) derived from its vapor pressure, 6.36X10-7 mm Hg(1), and water solubility, 6965 mg/L(2). This Henry's Law constant indicates that phthalic acid is expected to be essentially nonvolatile from water surfaces(3). Phthalic acid's Henry's Law constant indicates that volatilization from moist soil surfaces will not occur(SRC). Phthalic acid is not expected to volatilize from dry soil surfaces(SRC) based upon its vapor pressure(1).
Literature: (1) Daubert TE, Danner RP; Physical And Thermodynamic Properties of Pure Chemicals: Data Compilation, Supplement 1 (1991) (2) Yalkowsky SH, He Y; Handbook of Aqueous Solubility Data. CRC Press LLC, Boca Raton, FL. p. 456 (2003) (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990)

The Koc values were determined for an acidic forest soil (Podzol, 4.85% organic carbon, pH 2.8), an agricultural soil (Alfisol, 1.25% organic carbon, pH 6.7) and a sublimnic soil (sediment from Lake Constance, Germany, 1.58% organic carbon, pH 7.1) as 31, 2 and 2, respectively(1). According to a classification scheme(2), these Koc values suggest that phthalic acid is expected to have very high mobility in soil. Phthalic acid adsorbs strongly to aluminum and iron oxides via a surface ligand exchange reaction(3). Adsorptivity is sensitive to pH; for aluminum oxide the fraction absorbed is >0.8 below pH 6 and falls below 0.1 above pH 7.5(3).
Literature: (1) Von Oepen B et al; Chemosphere 22: 285-304 (1991) (2) Swann RL et al; Res Rev 85: 23 (1983) (3) Ainsworth CC et al; pp 125-44 in Sorption and Degradation of Pesticides in Soil Sci Soc Spec Publ 32 (1993)

Isobutylcarbinol

isopentylalcohol

Isopentylalkohol

ISOAMYLALCOHOL

Isopentanol

Alcool isoamylique

Fuseloel

Isoamylol

Isobutyl carbinol

Isopentyl alcohol

PHTQWCKDNZKARW-UHFFFAOYSA-N

Amylowy alkohol

Fermentation amyl alcohol

Iso-amylalkohol

Isoamyl alcohol

Isoamyl alkohol

isoamyl-alcohol

Alcool amilico

Primary isoamyl alcohol

3-methylbutanoI

3-Methylbutanol

Fusel Oil

AC1Q7CHF

Iso-amyl alcohol

potato-spirit oil

ACMC-1ADLL

Huile de fusel

i-Amyl Alcohol

Isoamyl alcohol, primary

3-Methylbutanol, analytical standard

DEM9NIT1J4

3-methyl butanol

3-methyl-Butanol

3-Metil-butanolo

AC1L1L9D

AC1Q1PG0

ISOAMYL ALCOHOL, ACS

Alcool isoamylique [French]

isopentan-1-ol

UNII-DEM9NIT1J4

Alcool amilico [Italian]

Amylowy alkohol [Polish]

Iso-amylalkohol [German]

Isoamyl alcohol (natural)

KSC175S7D

1-Hydroxy-3-Methylbutane

7340AF

Isoamyl alkohol [Czech]

NATURAL ISOAMYL ALCOHOL - TECHNICAL GRADE

NSC1029

NSC7905

CTK0H5971

HMDB06007

HSDB 605

I0289

Isoamyl alcohol (primary and secondary)

NATURAL ISOAMYL ALCOHOL P & F

QSPL 002

3-methylbutane-1-ol

CHEMBL372396

DB02296

Isopentyl alcohol (8CI)

2-Methyl-4-butanol

3-methyl 1-butanol

3-Methyl-1-butanol

3-Methylbutan-1-ol

C07328

CCRIS 8806

ZINC896830

DTXSID3025469

FEMA Number 2057

Jsp001579

LP092178

LS-2837

NSC 1029

NSC-1029

NSC-7905

OR034211

OR210114

STL282718

UNII-2NK7O363Q6 component PHTQWCKDNZKARW-UHFFFAOYSA-N

ZB015111

3-Metil-butanolo [Italian]

Butanol, 3-methyl-

CHEBI:15837

DSSTox_CID_5469

3-Methyl-1-butanol, analytical standard

AN-22920

ANW-18132

DSSTox_GSID_25469

Isoamyl alcohol (3-methyl butanol)

KB-70935

3-Methyl-Butan-1-Ol

DSSTox_RID_77799

LMFA05000108

Magnesium bis(3-methylbutan-1-olate)

Methyl-3-butan-1-ol

MFCD00002934

ZINC00896830

AI3-15288

Isoamyl alcohol, >=98%, FG

RTR-003692

TR-003692

3-METHYL-1-BUTANOL, REAG

AKOS000118739

FEMA No. 2057

FT-0616032

TRA-0206228

1-Butanol, 3-methyl-

3-Methyl-1-butanol, mixture of isomers

Butan-1-ol, 3-methyl

I14-14690

Z955123582

Isoamyl alcohol, natural, >=98%, FG

Tox21_302359

WLN: Q2Y1 & 1

123-51-3

F0001-0367

3-Methyl-1-butanol, 98%

3-METHYL-BUTAN-(1)-OL

6423-06-9

MCULE-7411270401

NCGC00255329-01

CAS-123-51-3

EINECS 204-633-5

EINECS 229-179-5

3-Methyl-1-butanol, anhydrous, >=99%

3-Methyl-1-butanol, United States Pharmacopeia (USP) Reference Standard

3-Methyl-1-butanol, technical grade, 95%

3-Methylbutanol, BioReagent, for molecular biology, >=98.5%

1973-EP2281899A2

1973-EP2316937A1

3-Methyl-1-butanol, LR, >=98%

3-Methyl-1-butanol, reagent grade, 98%

MolPort-001-793-103

123-51-3 (Parent)

74374-EP2269986A1

74374-EP2308857A1

74374-EP2380568A1

3-Methyl-1-butanol, biotech. grade, >=99%

3-Methyl-1-butanol, ReagentPlus(R), >=99%

117932-EP2287147A2

117932-EP2298768A1

6423-06-9 (magnesium salt)

3-Methyl-1-butanol, ACS reagent, >=98.5%

3-Methyl-1-butanol, JIS special grade, >=98.0%

3-Methyl-1-butanol, SAJ first grade, >=96.0%

3-Methylbutanol, BioUltra, for molecular biology, >=99.0% (GC)

3-Methyl-1-butanol, p.a., 99.8%

3-Methyl-1-butanol, ACS, 98.5% min. 500ml

3-Methylbutanol, puriss. p.a., ACS reagent, >=98.5% (GC)

3-Methylbutanol, p.a., ACS reagent, reag. ISO, reag. Ph. Eur., 98.5%

InChI=1/C5H12O/c1-5(2)3-4-6/h5-6H,3-4H2,1-2H

The Henry's Law constant for isopentanol is 1.41X10-5 atm-cu m/mol(1). Using this value for the Henry's Law constant, one can estimate that the volatilization half-life of isopentanol in a model river 1 m deep flowing at 1 m/s with a wind speed of 3 m/s is 2.55 days(2). Similarly, the half-life of isopentanol in a model lake 1 m deep with a 0.05 m/s current and a 0.5 m/s wind is 21 days(2). In view of isopentanol's relatively high vapor pressure, 2.37 mm Hg at 25 deg C(3) and moderate Henry's Law constant and low adsorptivity to soil, isopentanol would be expected to volatilize from dry and moist soil(SRC).
Literature: (1) Butler JAV et al; J Chem Soc 1935: 280-5 (1935) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. NY: McGraw-Hill Chapt 15 (1982) (3) Riddick JA et al; Organic Solvents 4th ed; pp. 221-2 NY: Wiley (1986)

The Koc for isopentanol estimated from its water solubility, 26.7 mg/L(1), using recommended regression equations are 720(2) and 679(4). However, the chemicals used in developing these equations were mainly pesticides and their structures are not similar to isopentanol. The Koc for isopentanol estimated from molecular structure is 4(3). This should be a reasonable estimate for the Koc because it is close to the experimental value for the structurally similar chemical, 1-pentanol, 1.6(6). According to a suggested classification scheme(5), the estimated Kocs based on molecular structure suggests that isopentanol is very highly mobile in soil(SRC).
Literature: (1) Riddick JA et al; Organic Solvents 4th ed; pp. 211-2 NY: Wiley (1986) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. NY: McGraw-Hill Chapt 4 (1982) (3) Meylan WM et al; Environ Sci Technol 26: 1560-7 (1992) (4) Wauchope RD et al; Rev Environ Contam Toxicol 123: 1-155 (1991) (5) Swann RL et al; Res Rev 85: 17-28 (1983) (6) Gerstl Z, Helling CS; J Environ Sci Health B22: 55-69 (1987)

Methyldisulfanylmethane

Methyldithiomethane

dimethyldisulphide

Dimethyldisulfide

methyldisulfanyl methane

Methyldisulfide

Dimethyl disulphide

WQOXQRCZOLPYPM-UHFFFAOYSA-N

Dimethyl disulfide

methyl disulphide

Disulfide dimethyl

METHYL DISULFIDE

(Methyldisulfanyl)methane

DMDS

Sulfa-hitech

Dimethyl disulfide, analytical standard

(Methyldithio)methane

(Methyldisulfanyl)methane #

Disulfide, dimethyl

AC1Q4HER

AC1Q4HEQ

1,2-Dimethyldisulfane

PubChem9665

Dimethyl disulfide, >=99%

AC1L1Z53

2,3-Dithiabutane

Dimethyl disulfide, 99%

NSC9370

UN2381

Dimethyl disulfide, 98%

HMDB05879

D0714

CTK2F3131

RP18575

CHEBI:4608

CCRIS 2939

C08371

BDBM233038

Methyl disulfide (8CI)

WLN: 1SS1

3P8D642K5E

HSDB 6400

LS-1499

DTXSID4025117

NSC 9370

NSC-9370

OR000230

OR291634

CHEMBL1347061

Sulfa-hitech 0382

UN 2381

(1/4)x>>u paragraph signthornAoAN

(CH3S)2

UNII-3P8D642K5E

ZINC8221057

A833808

Dimethyl disulfide, >=99.0%

DSSTox_CID_5117

KB-76616

AN-22028

TL8004165

Dimethyl disulfide, >=98%, FG

DSSTox_GSID_25117

DSSTox_RID_77673

MFCD00008561

AI3-25305

TR-021489

RTR-021489

I09-0129

Q-100719

AKOS009157459

FEMA No. 3536

FT-0625135

METHYL, [(THIOMETHYL)THIO]-

Dimethyl disulfide, natural, >=98%, FG

EN300-36043

Tox21_201525

F0001-1676

624-92-0

NCGC00259075-01

NCGC00091798-02

NCGC00091798-01

MCULE-7451882535

EINECS 272-923-9

CAS-624-92-0

Dimethyl disulfide [UN2381] [Flammable liquid]

EINECS 210-871-0

Dimethyl disulfide [UN2381] [Flammable liquid]

MolPort-003-929-787

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

224638-EP2371831A1

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

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)

Tetradecane_GurudeebanSatyavani

Tetradekan

Tetradecane

Tetradecane olefine

myristyl

BGHCVCJVXZWKCC-UHFFFAOYSA-N

N-TETRADECANE

Tetradecane, analytical standard

n-Teradecane

AC1L1ZHO

Tridecane, methyl-

Tetradecane, >=99%

Tetradecane, 99%

KSC352S3D

U012

ACMC-1B07Q

C14H30

S0286

CCRIS 715

CTK2F2931

CHEMBL135488

NSC72440

Tetradecane, certified reference material, TraceCERT(R)

LTBB002873

HSDB 5728

n-TETRADECANE, 99%

DTXSID1027267

STL280540

LP005503

LP100448

AK113059

UNII-114P5I43UJ component BGHCVCJVXZWKCC-UHFFFAOYSA-N

ZINC1698519

CHEBI:41253

DSSTox_CID_7267

DSSTox_GSID_27267

CC-33172

NSC 72440

NSC-72440

AN-22062

TL8004330

ANW-34473

TRA0013192

SC-74492

03LY784Y58

DSSTox_RID_78378

LMFA11000586

MFCD00008986

C-28195

UNII-FW7807707B component BGHCVCJVXZWKCC-UHFFFAOYSA-N

ST24031875

RTR-021669

DB-054348

AI3-04240

LS-148888

TR-021669

KB-260941

UNII-03LY784Y58

Alkanes, C14-16

Alkanes, C14-30

AKOS004910010

Paraffinic hydrocarbons (C14-C30)

BRN 1733859

FT-0632717

FT-0632666

I14-99197

Tox21_303277

I14-101364

629-59-4

n-Tetradecane, 99% 25g

NCGC00257151-01

MCULE-7442374993

CAS-629-59-4

EINECS 292-448-0

EINECS 211-096-0

CH3-[CH2]12-CH3

90622-46-1

74664-93-0

MolPort-003-665-072

Tetradecane, olefine free, >=99.0% (GC)

4-01-00-00520 (Beilstein Handbook Reference)

C72FCDE9-545A-4C7D-9907-1DFACCF43A82

The Henry's Law constant for n-tetradecane is estimated as 11.9 atm-cu m/mole(SRC) derived from its vapor pressure, 0.015 mm Hg(1), and water solubility, 0.00033 mg/L(2). This Henry's Law constant indicates that n-tetradecane is expected to volatilize rapidly 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 4 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 5.6 days(SRC). However, volatilization from water surfaces is expected to be attenuated by adsorption to suspended solids and sediment in the water column. The estimated volatilization half-life from a model pond is 28 months if adsorption is considered(4). n-Tetradecane's estimated Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). n-Tetradecane is not expected to volatilize from dry soil surfaces based upon its vapor pressure(SRC).
Literature: (1) Haynes WM, ed; CRC Handbook of Chemistry and Physics. 95th ed. Boca Raton, FL: CRC Press LLC, p. 15-21 (2014) (2) Coates M et al; Environ Sci Technol 19: 628-32 (1985) (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (4) US EPA; EXAMS II Computer Simulation (1987)

In water, 3.3X10-4 mg/L at 25 deg C
Literature: Coates M et al; Environ Sci Technol 19: 628-32 (1985)
Literature: #Very soluble in ether; soluble in carbon tetrachloride
Literature: Haynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-498
Literature: #Soluble in alcohol
Literature: Lewis, R.J. Sr.; Hawley's Condensed Chemical Dictionary 15th Edition. John Wiley & Sons, Inc. New York, NY 2007., p. 1218

Using a structure estimation method based on molecular connectivity indices(1), the Koc of n-tetradecane can be estimated to be 16,000(SRC). According to a classification scheme(2), this estimated Koc value suggests that n-tetradecane is expected to be immobile in soil. Laboratory soil column elution experiments showed that the percent of n-tetradecane adsorbed to three different native soil types ranged from 2.2-5.98%(3).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.11. Nov, 2012. Available from, as of Nov 11, 2015: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 23 (1983) (3) Kanatharana P, Grob RL; J Environ Sci Health A18: 59-77 (1983)

HEPTADECANE

Heptadekan

NDJKXXJCMXVBJW-UHFFFAOYSA-N

Normal-heptadecane

Heptadecane, analytical standard

n-Heptadecane

AC1L1ZIF

AC1Q2W2X

Hexadecane, methyl-

H7C0J39XUM

Heptadecane, 99%

M762

C17H36

UNII-H7C0J39XUM

S0289

CTK2F2995

UNII-J3N6X3YK96 component NDJKXXJCMXVBJW-UHFFFAOYSA-N

ARONIS020486

UNII-CI87N1IM01 component NDJKXXJCMXVBJW-UHFFFAOYSA-N

LTBB002875

n-HEPTADECANE, 99%

HSDB 8347

C01816

CHEMBL3185332

LP002411

DTXSID7047061

NSC172782

STL355860

ZINC8217397

CHEBI:16148

TL8004342

CC-32773

DSSTox_GSID_47061

ANW-42115

AN-22067

LS-74180

C-28208

MFCD00009002

LMFA11000003

UNII-FW7807707B component NDJKXXJCMXVBJW-UHFFFAOYSA-N

DSSTox_CID_27061

DSSTox_RID_82078

KB-110287

DB-054356

RTR-021679

AI3-36898

NSC-172782

TR-021679

NSC 172782

AKOS000487450

BRN 1738898

FT-0626894

TRA-0205485

I14-57459

I14-19384

Tox21_302278

629-78-7

n-Heptadecane, 99% 25g

NCGC00256101-01

MCULE-3718944215

EINECS 211-108-4

CAS-629-78-7

CH3-[CH2]15-CH3

MolPort-002-351-156

Heptadecane, purum, >=98.0% (GC)

4-01-00-00548 (Beilstein Handbook Reference)

43B472DE-3A6B-4855-8457-9D679B0D1C87

InChI=1/C17H36/c1-3-5-7-9-11-13-15-17-16-14-12-10-8-6-4-2/h3-17H2,1-2H

The Henry's Law constant for heptadecane is estimated as 3.1X10-2 atm-cu m/mole(SRC) derived from its vapor pressure, 2.28X10-4 mm Hg(1), and water solubility, 2.3X10-3 mg/L(2). This Henry's Law constant indicates that heptadecane 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)(4) is estimated as 1.6 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)(4) is estimated as 6.2 days(SRC). However, volatilization from water surfaces is expected to be attenuated by adsorption to suspended solids and sediment in the water column. The estimated volatilization half-life from a model pond is greater than 2 years if adsorption is considered(5). Heptadecane's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Heptadecane is not expected to volatilize from dry soil surfaces(SRC) based upon its vapor pressure(1).
Literature: (1) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989) (2) WakehamSG et al; Canadian J Fish Aquat Sci 40: 304-21 (1983) (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (4) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 14, 2016: http://www2.epa.gov/tsca-screening-tools (5) US EPA; EXAMS II Computer Simulation (1987)

In water, 2.3X10-3 mg/L at 25 deg C
Literature: Wakeham SG ET al; Canadian J Fish Aqua Sci 40: 304-21 (1983)
Literature: #Insoluble in water
Literature: Haynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-388
Literature: #Slightly soluble in ethanol, carbon tetrachloride; soluble in ethyl ether
Literature: Haynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-288

The Koc of heptadecane is 2.5X10+5(1). According to a classification scheme(2), this Koc value suggests that heptadecane is expected to be immobile in soil.
Literature: (1) Wakeham SG et al; Canadian J Fish Aqua Sc 40: 304-21 (1983) (2) Swann RL et al; Res Rev 85: 17-28 (1983)