methanethiol

METHYL MERCAPTAN

Methylmercaptan

Mercaptomethane

74-93-1

Methyl sulfhydrate

Thiomethanol

Methanthiol

Thiomethyl alcohol

Metilmercaptano

Methvtiolo

Methylmercaptaan

Mercaptan methylique

Methaanthiol

Thiomethane

RCRA waste number U153

FEMA No. 2716

Methanethiole

CH3SH

methyl-mercaptan

Methyl thioalcohol

MeSH

UN 1064

2X8406WW9I

Methaanthiol [Dutch]

Methanthiol [German]

Methvtiolo [Italian]

Methylmercaptaan [Dutch]

Metilmercaptano [Italian]

Metilmercaptano [Spanish]

SCH 54292

Methyl mercaptan (natural)

Mercaptan methylique [French]

HSDB 813

EINECS 200-822-1

UN1064

RCRA waste no. U153

BRN 1696840

methylsulfanyl

methane thiol

methyl sulfides

methyl thiol

methyl-thiol

UNII-2X8406WW9I

(methyl)sulfane

Methylthioalcohol

a methyl thioether

sulfonium methylide

Methanethiol, purum

Methanethiol, 98.0%

METHANETHIOL [MI]

EC 200-822-1

Methanethiol, >=98.0%

4-01-00-01273 (Beilstein Handbook Reference)

METHYL MERCAPTAN [FHFI]

METHYL MERCAPTAN [HSDB]

DTXSID5026382

CHEBI:16007

CHEBI:86315

DTXSID10168842

DTXSID60992376

InChI=1/CH4S/c1-2/h2H,1H

NSC229573

AKOS009157032

NSC-229573

Methyl mercaptan [UN1064] [Poison gas]

NS00020025

C00409

Q409309

17719-48-1

Z22

The Henry's Law constant for methyl mercaptan is estimated as 0.0031 atm-cu m/mole(SRC) derived from its vapor pressure, 1,510 mm Hg(1), and water solubility, 15,400 mg/L(2). This Henry's Law constant indicates that methyl mercaptan 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 0.8 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 2.8 days(SRC). Methyl mercaptan's Henry's Law constant indicates that volatilization from moist soil surfaces is expected to occur(SRC). Methyl mercaptan is expected to volatilize rapidly from dry soil surfaces based upon its vapor pressure and because it is a gas a temperatures above 6 deg C(SRC). However, gaseous methyl mercaptan gas has been found to strongly adsorb to moist and dry soil surfaces suggesting that adsorption might be an environmental sink for methyl mercaptan(4). Therefore, the importance of volatilization from soil surfaces may be attenuated by adsorption(SRC).
Literature: (1) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989) (2) Hine J, Mookerjee PK; J Org Chem 40: 292-8 (1975) (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (4) Smith KA et al; Soil Sci 116: 313-9 (1973)

Using a structure estimation method based on molecular connectivity indices(1), the Koc of methyl mercaptan can be estimated to be 13(SRC). According to a classification scheme(2), this estimated Koc value suggests that methyl mercaptan is expected to have very high mobility in soil. Gaseous methyl mercaptan has been observed to partition to soils(3). For example, when gaseous methyl mercaptan was passed over six air-dried and moist (50% field capacity) soils, 2.4-32.1 mg/g and 2.2-21.4 mg/g of methyl mercaptan rapidly adsorbed to the dry and moist soils, respectively(3). Neither the capacity or rate of sorption was correlated to soil pH, organic matter content, or clay content; sterile controls ruled out the involvement of microorganisms(3); it was suggested that adsorption to soil surfaces might be an environmental sink for gaseous methyl mercaptan(3).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Jan, 2011. Available from, as of July 19, 2012: http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm (2) Swann RL et al; Res Rev 85: 17-28 (1983) (3) Smith KA et al; Soil Sci 116: 313-9 (1973)

dimethyl sulfide

Methyl sulfide

75-18-3

Methane, thiobis-

dimethyl sulphide

dimethylsulfide

Methyl thioether

Dimethylsulphide

2-Thiapropane

Dimethyl thioether

Methyl sulphide

METHYLSULFANYLMETHANE

Methylthiomethane

Dimethylsulfid

(Methylsulfanyl)methane

Methyl monosulfide

Dimethyl monosulfide

Thiobismethane

2-Thiopropane

Methanethiomethane

Thiobis(methane)

Exact-S

Sulfure de methyle

Dimethyl sulfide (natural)

dimethylsulfane

FEMA No. 2746

Methylthiomethyl radical

MFCD00008562

Methane, 1,1'-thiobis-

[SMe2]

QS3J7O7L3U

CHEBI:17437

(CH3)2S

31533-72-9

methylsulfide

Dimethylsulfid [Czech]

Sulfure de methyle [French]

HSDB 356

EINECS 200-846-2

UN1164

UNII-QS3J7O7L3U

BRN 1696847

Methylsulphide

Thiopropane

Thiobis-methane

di-methylsulfide

AI3-25274

Dimethyl sulfane

Sulfide, methyl-

(methylthio)methane

Me2S

REDUCED-DMSO

SMe2

Dimethyl sulfide, 98%

reduced dimethyl sulfoxide

(Methylsulfanyl)methane #

Dimethyl sulfide [UN1164] [Flammable liquid]

Dimethyl sulfoxide(Reduced)

EC 200-846-2

(Me)2S

Dimethyl sulfide, >=99%

4-01-00-01275 (Beilstein Handbook Reference)

CHEMBL15580

DIMETHYL SULFIDE [MI]

METHYL SULFIDE [FHFI]

DIMETHYL SULFIDE [FCC]

DIMETHYL SULFIDE [HSDB]

DTXSID9026398

S(CH3)2

Dimethyl sulfide, >=99%, FCC

Dimethyl sulfide, analytical standard

STL481894

Dimethyl sulfide, >=95.0% (GC)

AKOS009031411

MCULE-4525381422

UN 1164

Dimethyl sulfide, anhydrous, >=99.0%

InChI=1/C2H6S/c1-3-2/h1-2H

M0431

NS00005000

NS00124710

Dimethyl sulfide, puriss., >=99.0% (GC)

C00580

Dimethyl sulfide, natural, >=99%, FCC, FG

Dimethyl sulfide [UN1164] [Flammable liquid]

A838342

Dimethyl sulfide, redistilled, >=99%, FCC, FG

Q423133

Q-100810

The Henry's Law constant for dimethyl sulfide has been measured as 1.61X10-3 atm-cu m/mole(1). This Henry's Law constant indicates that dimethyl sulfide 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 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 3 days(SRC). Dimethyl sulfides's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). The potential for volatilization of dimethyl sulfide from dry soil surfaces may exist(SRC) based upon a vapor pressure of 502 mm Hg(3).
Literature: (1) Gaffney, JS et al; Env Sci Tech 21: 519-23 (1987) (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. Vol 4. Design Inst Phys Prop Data, Amer Inst Chem Eng, NY, NY: Hemisphere Pub Corp (1989)

The Koc of dimethyl sulfide is estimated as 6.3(SRC), using a water solubility of 22,000 mg/L(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that dimethyl sulfide is expected to have very high mobility in soil.
Literature: (1) Suzuki T; J Comp-Aided Molec Des 5: 149-66 (1991) (2) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.0. Jan, 2009. Available from http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm as of Oct 1, 2009. (3) Swann RL et al; Res Rev 85: 17-28 (1983)
Literature: #Air-dried, unsterilized moist, and sterilized moist soils exposed to air initially containing 500 ppm dimethyl sulfide adsorbed an avg of 32, 308, and 10 ug dimethyl sulfide/g soil, respectively, in 15 days(1). Time required for complete sorption of dimethyl sulfide by moist soil from air initially containing 100 ppm dimethyl sulfide: soil 1 (Weller) - 1st exposure 150 min, 2nd exposure 100 min, 3rd exposure 95 min; soil 2 (Harps) - 1st exposure 45 min, 2nd exposure 24 min, 3rd exposure 19 min(1). These data suggest that moist soils have a greater tendency to adsorb dimethyl sulfide than dry soils, and that microbial activity in moist soils may be responsible for greater adsorption(1). When natural gas containing 0.5 pounds of dimethyl sulfide per million cubic feet of gas was passed through a bed of pulverized, dry, montmorillonite clay, dimethyl sulfide exhibited a fast breakthrough (2 hours) and a fast build-up rate in effluent gas (85% of influent concn 4 hours after breakthrough), suggesting that dimethyl sulfide does not adsorb to dry soils(2).
Literature: (1) Bremner JM, Banwart WL; Soil Biol Biochem 8: 79-83 (1976) (2) Williams RP; Oper Sect Proc - Am Gas Assoc pp. T29-T37 (1976)

NONANOIC ACID

Pelargonic acid

112-05-0

n-Nonanoic acid

Nonoic acid

Nonylic acid

Pelargic acid

1-Octanecarboxylic acid

n-Nonylic acid

n-Nonoic acid

Pelargon

Nonanoate

Cirrasol 185A

Hexacid C-9

Emfac 1202

68937-75-7

1-nonanoic acid

FEMA No. 2784

Nonansaeure

Pelargonsaeure

pergonic acid

MFCD00004433

nonoate

NSC 62787

Nonanoic Acid Anion

CHEBI:29019

CH3-[CH2]7-COOH

DTXSID3021641

97SEH7577T

pergonate

n-nonanoate

NSC-62787

1-nonanoate

C9:0

1-octanecarboxylate

Pelargon [Russian]

DTXCID901641

1-Octanecarboxyic acid

CAS-112-05-0

NSC-65450

NSC-65455

HSDB 5554

EINECS 203-931-2

EPA Pesticide Chemical Code 217500

BRN 1752351

n-Pelargonate

UNII-97SEH7577T

AI3-04164

n-Nonylate

n-Nonoate

?Nonanoic acid

n-pelargonic acid

KNA

EINECS 273-086-2

Acid C9

GRANTRICO

THINEX

Nonanoic acid, 96%

3sz1

Emery's L-114

Nonanoic acid, ?99%

Emery 1202

Emery 1203

octane-1-carboxylic acid

Nonanoic acid, >=97%

bmse000499

EC 203-931-2

EC 273-086-2

WLN: QV8

NCIOpen2_000142

NCIOpen2_000179

NCIOpen2_001763

NCIOpen2_002882

NCIOpen2_003483

NONANOIC ACID [FCC]

SCHEMBL21966

Emery 1202 (Salt/Mix)

NONANOIC ACID [FHFI]

NONANOIC ACID [HSDB]

PELARGONIC ACID [MI]

4-02-00-01018 (Beilstein Handbook Reference)

MLS001066339

PELARGONIC ACID [INCI]

CHEMBL108436

Nonanoic acid, >=96%, FG

QSPL 030

HMS2269L08

Nonanoic acid, analytical standard

HY-N7057

Nonanoic acid, natural, 98%, FG

NSC62787

Tox21_202426

Tox21_300022

BBL027459

BDBM50556776

FA 9:0

LMFA01010009

s4949

STL372710

AKOS000118981

NONANOIC ACID MFC9 H18 O2

CCG-231471

MCULE-4736597375

NCGC00164328-01

NCGC00164328-02

NCGC00164328-03

NCGC00253958-01

NCGC00259975-01

BP-27910

SMR000112203

VS-08541

CS-0076036

N0288

NS00009752

P0952

EN300-19260

C01601

A802476

Q369777

Q-201488

F0001-2447

Z104473336

F57B4D17-8824-403B-AE1B-FA425608BB39

InChI=1/C9H18O2/c1-2-3-4-5-6-7-8-9(10)11/h2-8H2,1H3,(H,10,11

A pKa of 4.95(1) indicates nonanoic 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). Nonanoic acid is not expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 1.65X10-3 mm Hg(3).
Literature: (1) Dean JA; Handbook of Organic Chemistry, NY, NY: McGraw-Hill, Inc p. 8-45 (1987) (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) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals: Data Compilation. Design Inst Phys Prop Data, Amer Inst Chem Eng., Washington, DC: Taylor & Francis, Vol 4 (1995)

The Koc of undissociated nonanoic acid is estimated as 1,700 for the free acid(SRC), using a log Kow of 3.42(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that undissociated nonanoic acid is expected to have low mobility in soil. The pKa of nonanoic acid is 4.95(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) Dean JA; Handbook of Organic Chemistry, NY, NY: McGraw-Hill, Inc p. 8-45 (1987) (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)

stearic acid

Octadecanoic acid

57-11-4

n-Octadecanoic acid

Stearophanic acid

Cetylacetic acid

1-Heptadecanecarboxylic acid

Pearl stearic

Stearex Beads

Octadecansaeure

Stearinsaeure

Vanicol

Hydrofol Acid 150

Century 1240

Glycon DP

Glycon TP

Industrene R

Stearate

Formula 300

Hydrofol 1895

Hystrene 7018

Hystrene 9718

Glycon S-80

Glycon S-90

octadecoic acid

Tegostearic 254

Tegostearic 255

Tegostearic 272

Hystrene 80

Humko Industrene R

Hydrofol acid 1655

Hydrofol acid 1855

Hystrene S-97

Hystrene T-70

Industrene 5016

Dar-chem 14

Emersol 120

Emersol 132

Hystrene 4516

Hystrene 5016

Groco 54

Groco 55

Groco 55L

Groco 58

Groco 59

Glycon S-70

Industrene 8718

Industrene 9018

Emersol 150

Kam 1000

Barolub FTA

FEMA No. 3035

Acidum stearinicul

C18:0

Caswell No. 801D

Oktadekansaeure

HY-Phi 1199

HY-Phi 1205

HY-Phi 1303

HY-Phi 1401

acide stearique

Kam 2000

Kam 3000

Steric acid

Century 1210

acide octadecanoique

Stearic acid, pure

PD 185

NAA 173

CCRIS 2305

Stearic acid 50

HSDB 2000

Emersol 153NF

Dervacid 3155

Purified stearic acid

Adeka sa 300

Century 1220

Century 1230

Emersol 6349

Hydrofol Acid 150 (VAN)

NSC 25956

Lunac S 40

Hydrofol Acid 1895

Prifac 2918

Promulsin

EPA Pesticide Chemical Code 079082

Vis-Plus

AI3-00909

UNII-4ELV7Z65AP

EINECS 200-313-4

n-Octadecylic acid

4ELV7Z65AP

NSC-25956

Pristerene 4900

Hystrene S 97

Hystrene T 70

Stearic Acid Cherry

Edenor C18

Edenor ST 1

Sunfat 18S

BRN 0608585

Emersol 153

Selosol 920

Stearic acid (TN)

Hystrene 9718NF

Kortacid 1895

Lunac 30

CH3-[CH2]16-COOH

DTXSID8021642

Loxiol G 20

CHEBI:28842

Lunac S 20

Lunac S 30

Lunac S 90

Lunac S 90KC

Hystrene 9718NFFG

MFCD00002752

NSC-261168

CHEMBL46403

17FA

DTXCID301642

EC 200-313-4

4-02-00-01206 (Beilstein Handbook Reference)

NSC25956

FA 18:0

NCGC00091596-02

STEARIC ACID (II)

STEARIC ACID [II]

400JB9103-88

A 1760

68937-76-8

STEARIC ACID (MART.)

STEARIC ACID [MART.]

STEARIC ACID (USP-RS)

STEARIC ACID [USP-RS]

CH3-(CH2)16-COOH

Oktadekansaure

Stearicacid

Lunac

STEARIC ACID (EP MONOGRAPH)

STEARIC ACID [EP MONOGRAPH]

CAS-57-11-4

Isostearic acid EX

Haimaric MKH(R)

Prisorine 3501

Prisorine 3502

Prisorine 3508

Emersol 871

Emersol 875

Emery 875D

Emery 871

Unimac 5680

C-Lube 10

Stearic acid [JAN:NF]

octadecansaure

Stearinsaure

Stearophanate

Stearex

Tsubaki

n-Octadecanoate

Bassinic acid

Lactaric acid

Talgic acid

Doctor Plus

Edenor htict-n

1hmr

1hmt

4fnn

Kiri stearic acid

Obeo Baby Bubble

Jinhwagwangsu Hair

Lunac YA

Palmitostearic acid

Stearic acid 70

Stearic acid, CP

Sterene 60b

Sterene 60r

EINECS 250-178-0

F 3 (lubricant)

Industrene 4518

Jinhwagwangsu Bubble

Nonsoul SK 1

Pristerene 4904

Pristerene 4910

Pristerene 4916

Pristerene 4963

Pristerene 4981

Pristerene 9429

Pristerene 9559

Pristerine 4989

CELOZOLE

fatty acid 18:0

Sterene 460

Industrene 5016K

Radiacid 0427

Edenor ST 20

Serfax MT 90

Stearic acid_ravikumar

Unister NAA 180

Century 1224

NORSOREX AP

Edenor HT-JG 60

Stearic acid (8CI)

Stearic acid, puriss.

Hyfac 410

Hyfac 420

Hyfac 421

Hyfac 422

Hystrene 7018 FG

Lunac S 50

Lunac S 98

Prifac 5905

3v2p

875D

1-Heptadecanecarboxylate

Industrene 7018 FG

AFCO-Chem B 65

Heptadecanecarboxylic acid

Edenor C 18/98

Octadecanoic acid (9CI)

Stearic acid, >=98%

SCHEMBL659

Hystrene 9718 NF FG

bmse000485

STEARIC ACID [MI]

Emery 400 (Salt/Mix)

NEO-FAT 18S

STEARIC ACID [DSC]

STEARIC ACID [JAN]

Stearic acid (JP15/NF)

Stearic acid (JP17/NF)

Emersol 110 (Salt/Mix)

STEARIC ACID [FHFI]

STEARIC ACID [HSDB]

STEARIC ACID [INCI]

NOPCOCERA LU 6418

Stearic acid (reagent grade)

STEARIC ACID [VANDF]

WLN: QV17

STEARIC ACID [WHO-DD]

GTPL3377

WO 2

UNII-X33R8U0062

CELLBN FIRST CARE CLEANSER

NAA 180

Nonsoul SN 1 (*Sodium salt*)

SNA-2000 (*Sodium salt*)

Stearic acid, analytical standard

VLZ 200

S 30C

PURIFIED STEARIC ACID [NF]

Stearic acid, reagent grade, 95%

HY-B2219

ZENOL POWERFULX RECOVERYCREAM

Tox21_111154

Tox21_201887

Tox21_300562

BBL012224

BDBM50240485

LMFA01010018

s5733

SA 200

Stearic acid, >=95%, FCC, FG

STL163565

AKOS005716958

Tox21_111154_1

CCG-267314

DB03193

FA 1655

MCULE-5127577640

NSC 261168

X33R8U0062

NCGC00091596-01

NCGC00091596-03

NCGC00091596-04

NCGC00091596-05

NCGC00254456-01

NCGC00259436-01

E570

VS-03242

Stearic acid, puriss., >=98.5% (GC)

Stearic acid, SAJ first grade, >=90.0%

CS-0021598

G 270

NS00010335

S 300

S0163

EN300-19730

Stearic acid, SAJ special grade, >=95.0%

Stearic acid, Vetec(TM) reagent grade, 94%

C01530

D00119

EC 250-178-0

F70008

Stearic acid 50, tested according to Ph.Eur.

Q209685

SR-01000944717

STEARIC ACID (CONSTITUENT OF SAW PALMETTO)

Melting Point Standard 69-71C, analytical standard

SR-01000944717-1

Stearic acid, Grade I, >=98.5% (capillary GC)

Stearic acid, SAJ first grade, >=90.0%, powder

F0001-1489

STEARIC ACID (CONSTITUENT OF SAW PALMETTO) [DSC]

Stearic acid, certified reference material, TraceCERT(R)

Z104474964

CD7993EA-AD14-452A-A907-33376CC98790

Stearic acid, European Pharmacopoeia (EP) Reference Standard

Stearic acid, United States Pharmacopeia (USP) Reference Standard

Stearic Acid, Pharmaceutical Secondary Standard; Certified Reference Material

18639-67-3

InChI=1/C18H36O2/c1-2-3-4-5-6-7-8-9-10-11-12-13-14-15-16-17-18(19)20/h2-17H2,1H3,(H,19,20

An estimated pKa of 4.7(1) indicates stearic 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). Stearic acid is not expected to volatilize from dry soil surfaces(SRC) based upon an estimated vapor pressure of 4.3X10-8 mm Hg at 25 deg C(3).
Literature: (1) SPARC; pKa/property server. Ver 3. Jan, 2006. Available at http://ibmlc2.chem.uga.edu/sparc/ as of Mar 5, 2008. (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) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals: Data Domination. Design Inst Phys Prop Data, Amer Inst Chem Eng. NY, NY: Hemisphere Pub. Corp 4 Vol (1989)

The Koc of undissociated stearic acid is estimated as 710,000(SRC), using a log Kow of 8.23(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that undissociated stearic acid is expected to be immobile in soil. The estimated pKa of stearic acid is 4.75(4), indicating that this compound will exist almost entirely in the 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). However, the adsorption of stearate, the anion of stearic acid, was determined using relatively nonpolar marine sediment sand surfaces: anoxic clastic mud from Cape Lookout Bight, NC (3.5 g/g organic carbon, clay), fine carbonate beach sand from Kahana Stream, Oahu, HI (1.3 g/g organic carbon, fine sand and silty clay), and a fine carbonate sand from Waimanalo Beach, Oahu, HI (0.17 g/g organic carbon, fine-very fein sand)(6) Stearate exhibited Kds of 210, 140 and 36, respectively; overall averaging 99% adsorption(6).
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) SPARC; pKa/property server. Ver 3. Jan, 2006. Available at http://ibmlc2.chem.uga.edu/sparc/ as of Mar 5, 2008. (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) (6) Sansone FJ et al; Geochimica et Cosmochimica Acta 51: 1889-96 (1987)