Results for:
Species: Pseudomonas brassicacearum

1-methyl-3-propan-2-ylbenzene

Mass-Spectra

Compound Details

Synonymous names
M-CYMENE
535-77-3
1-Isopropyl-3-methylbenzene
3-Isopropyltoluene
m-Isopropyltoluene
m-Cymol
m-Methylisopropylbenzene
beta-Cymene
1-Methyl-3-isopropylbenzene
Benzene, 1-methyl-3-(1-methylethyl)-
1-Methyl-3-(1-methylethyl)benzene
1-methyl-3-propan-2-ylbenzene
meta-cymene
NSC 73975
HSDB 3428
.beta.-Cymene
EINECS 208-617-9
3-Methyl-1-isopropylbenzene
UNII-10ZH8R921S
BRN 1851357
10ZH8R921S
NSC-73975
CYMENE, M-
1-Methyl-3-(1-methylethyl)-benzene
DTXSID2060206
4-05-00-01058 (Beilstein Handbook Reference)
m-cymene [UN2046] [Flammable liquid]
m-Cymene, 99%
3-Methylisopropylbenzene
m-cymene [UN2046] [Flammable liquid]
M-CYMENE [HSDB]
M-CYMENE [MI]
m-Mentha-1,3,5-triene
m-Cymene, analytical standard
1-Methyl-3-isopropyl benzene
DTXCID9041449
1-methyl-3-(propan-2-yl)benzene
NSC73975
MFCD00008891
1-methyl-3-(1-methylethyl) benzene
AKOS005110997
MCULE-5480201967
1-Methyl-3-(1-methylethyl)benzene, 9CI
C0798
CS-0331846
NS00020834
T71023
Q27251197
Microorganism:

Yes

IUPAC name1-methyl-3-propan-2-ylbenzene
SMILESCC1=CC(=CC=C1)C(C)C
InchiInChI=1S/C10H14/c1-8(2)10-6-4-5-9(3)7-10/h4-8H,1-3H3
FormulaC10H14
PubChem ID10812
Molweight134.22
LogP4
Atoms10
Bonds1
H-bond Acceptor0
H-bond Donor0
Chemical Classificationaromatic compounds alkylbenzenes benzenoids
Supernatural-IDSN0426791

mVOC Specific Details

Boiling Point
DegreeReference
175 deg CHaynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 94th Edition. CRC Press LLC, Boca Raton: FL 2013-2014, p. 3-334
Volatilization
The Henry's Law constant for m-cymene is estimated as 7.15X10-3 atm-cu m/mole(SRC) derived from its vapor pressure, 1.72 mm Hg(1), and water solubility, 42.5 mg/L(2). This Henry's Law constant indicates that m-cymene 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 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)(3) is estimated as 4.6 days(SRC). m-Cymene's estimated Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). The potential for volatilization of m-cymene from dry soil surfaces may exist 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) Lun R et al; J Chem Eng Data 42: 951-53 (1997) (3) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990)
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of m-cymene can be estimated to be 1120(SRC). According to a classification scheme(2), this estimated Koc value suggests that m-cymene is expected to have low mobility in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Jan, 2011. Available from, as of Nov 6, 2013: http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
1.72 mm Hg at 25 deg CDaubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaHypoxylon AnthochroumNAMacías-Rubalcava et al. 2018
EukaryotaHypoxylon Anthochroumnaendophytic in Bursera lancifoliaUlloa-Benítez et al. 2016
ProkaryotaPseudomonas Brassicacearumreduces mycelium growth and sclerotia germination of Sclerotinia sclerotiorum USB-F593; lyses red blood cellsrhizosphere of bean plants, southern ItalyGiorgio et al. 2015
EukaryotaFusarium GraminearumBallot et al. 2023
EukaryotaKluyveromyces MarxianusJi et al. 2024
EukaryotaSaccharomyces CerevisiaeJi et al. 2024
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaHypoxylon Anthochroumrice medium (RM, 300g of rice and 300ml of water)SPME, GC-MSyes
EukaryotaHypoxylon AnthochroumPDA/WA + 500 mg l^-1 ChloramphenicolSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
EukaryotaFusarium Graminearumtryptone soy (TS medium; Carl Roth, Karlsruhe, Germany)GC-QQQ-MSno
EukaryotaKluyveromyces MarxianusSauce Meat during StorageSPME–GC–MSno
EukaryotaSaccharomyces CerevisiaeSauce Meat during StorageSPME–GC–MSno


4-methyltetradecane

Compound Details

Synonymous names
4-Methyltetradecane
25117-24-2
4-methyl-tetradecane
Tetradecane, 4-methyl-
4-Methyltetradecane #
DTXSID60334272
CHEBI:183309
DB-046629
Q67879616
Microorganism:

Yes

IUPAC name4-methyltetradecane
SMILESCCCCCCCCCCC(C)CCC
InchiInChI=1S/C15H32/c1-4-6-7-8-9-10-11-12-14-15(3)13-5-2/h15H,4-14H2,1-3H3
FormulaC15H32
PubChem ID520179
Molweight212.41
LogP8.1
Atoms15
Bonds11
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID183309
Supernatural-IDSN0155154

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaStreptomyces Philanthiantifungal activity against Aspergillus parasiticus TISTR 3276 and Aspergillus flavus PSRDC-4NABoukaew and Prasertsan 2020
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaStreptomyces Philanthisterile wheat seedsGC-MSno
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno


3,6-dimethyldecane

Compound Details

Synonymous names
3,6-Dimethyldecane
Decane, 3,6-dimethyl-
17312-53-7
3,6-dimethyl-Decane
DTXSID2058625
CHEBI:229429
Microorganism:

Yes

IUPAC name3,6-dimethyldecane
SMILESCCCCC(C)CCC(C)CC
InchiInChI=1S/C12H26/c1-5-7-8-12(4)10-9-11(3)6-2/h11-12H,5-10H2,1-4H3
FormulaC12H26
PubChem ID519395
Molweight170.33
LogP6.1
Atoms12
Bonds7
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID229429

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno


4,7-dimethylundecane

Compound Details

Synonymous names
4,7-Dimethylundecane
Undecane, 4,7-dimethyl-
17301-32-5
4,7-dimethy-lundecane
4,7-Dimethylundecane #
Undecane,4,7-dimethyl-
DTXSID50333996
CHEBI:140568
LMFA11000693
NS00096003
Microorganism:

Yes

IUPAC name4,7-dimethylundecane
SMILESCCCCC(C)CCC(C)CCC
InchiInChI=1S/C13H28/c1-5-7-9-13(4)11-10-12(3)8-6-2/h12-13H,5-11H2,1-4H3
FormulaC13H28
PubChem ID519389
Molweight184.36
LogP6.7
Atoms13
Bonds8
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID140568
Supernatural-IDSN0143769

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas TolaasiinanaLo Cantore et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas TolaasiiKBSPME-GCno


2-bromododecane

Compound Details

Synonymous names
2-Bromododecane
13187-99-0
Dodecane, 2-bromo-
2-Bromo dodecane
2-bromo-dodecane
EINECS 236-142-7
SCHEMBL1001129
DTXSID40927848
NSC97571
NSC 97571
NSC-97571
AKOS009156715
2-Bromododecane, technical grade, 85%
NS00051664
J-006076
Microorganism:

Yes

IUPAC name2-bromododecane
SMILESCCCCCCCCCCC(C)Br
InchiInChI=1S/C12H25Br/c1-3-4-5-6-7-8-9-10-11-12(2)13/h12H,3-11H2,1-2H3
FormulaC12H25Br
PubChem ID98299
Molweight249.23
LogP6.5
Atoms13
Bonds9
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
EukaryotaKluyveromyces MarxianusJi et al. 2024
EukaryotaSaccharomyces CerevisiaeJi et al. 2024
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
EukaryotaKluyveromyces MarxianusSauce Meat during StorageSPME–GC–MSno
EukaryotaSaccharomyces CerevisiaeSauce Meat during StorageSPME–GC–MSno


2,6,11-trimethyldodecane

Mass-Spectra

Compound Details

Synonymous names
2,6,11-TRIMETHYLDODECANE
31295-56-4
Dodecane, 2,6,11-trimethyl-
2,6,11-trimethyl dodecane
DTXSID60865591
CHEBI:132283
4-Methyl-2-pyrimidinecarboxylicacid
2,6,11-TETRAMETHYLDODECANE
LMFA11000682
NS00096197
Microorganism:

Yes

IUPAC name2,6,11-trimethyldodecane
SMILESCC(C)CCCCC(C)CCCC(C)C
InchiInChI=1S/C15H32/c1-13(2)9-6-7-11-15(5)12-8-10-14(3)4/h13-15H,6-12H2,1-5H3
FormulaC15H32
PubChem ID35768
Molweight212.41
LogP7.5
Atoms15
Bonds9
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID132283
Supernatural-IDSN0091291

mVOC Specific Details

Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaKlebsiella PneumoniaeNARees et al. 2017
ProkaryotaBacillus Amyloliquefaciens0rhizosphere soils of watermelon plantsWu et al. 2019
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaKlebsiella PneumoniaeNARees et al. 2016a
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaKlebsiella PneumoniaeLBSPME / GCxGC-TOFMSno
ProkaryotaBacillus Amyloliquefaciensmodified Murashige-Skoog (MS) culture mediumSPME-GC-MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaKlebsiella PneumoniaeLB GCxGC-TOF-MSno


1-iodododecane

Mass-Spectra

Compound Details

Synonymous names
1-IODODODECANE
4292-19-7
Dodecyl iodide
n-Dodecyl iodide
Lauryl iodide
Dodecane, 1-iodo-
DTXSID1049302
C12H25I
iodododecane
iodo-dodecane
1-iodo-dodecane
NSC 9285
EINECS 224-293-1
MFCD00001088
1-Iodododecane, 98%
SCHEMBL337211
CHEMBL3181940
DTXCID3029158
GCDPERPXPREHJF-UHFFFAOYSA-
NSC9285
NSC-9285
STR02749
Tox21_202834
AKOS009158472
s12219
NCGC00260380-01
CAS-4292-19-7
CS-0197229
I0511
NS00031263
1-Iodododecane (stabilized with Copper chip)
EN300-83276
A826068
2-PIPERAZIN-1-YL-THIAZOLE-5-CARBOXYLICACIDMETHYLESTER
InChI=1/C12H25I/c1-2-3-4-5-6-7-8-9-10-11-12-13/h2-12H2,1H3
Microorganism:

Yes

IUPAC name1-iodododecane
SMILESCCCCCCCCCCCCI
InchiInChI=1S/C12H25I/c1-2-3-4-5-6-7-8-9-10-11-12-13/h2-12H2,1H3
FormulaC12H25I
PubChem ID20282
Molweight296.23
LogP7.4
Atoms13
Bonds10
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
EukaryotaSaccharomyces CerevisiaeNANAHarris et al. 2021
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
EukaryotaSaccharomyces Cerevisiaemalt extract brothHS-SPME with GC-MSno


Triacontane

Mass-Spectra

Compound Details

Synonymous names
TRIACONTANE
n-Triacontane
638-68-6
CHEBI:31006
UNII-47A73V7096
EINECS 211-349-5
NSC 158661
NSC-158661
47A73V7096
DTXSID0060935
HSDB 8360
MFCD00009410
Triacontane, analytical standard
CH3-(CH2)28-CH3
CH3-[CH2]28-CH3
Triacontane; NSC 158661; n-Triacontane
Triacontane, 98%
n-Triacontane 100 microg/mL in Hexane
CHEMBL1482375
DTXCID9044110
LMFA11000588
N-C-30
NSC158661
STL564700
AKOS024257521
MCULE-1742110241
NCGC00165977-01
AS-48050
DB-054569
CS-0204888
NS00010795
T0594
F17598
Q151058
A387C655-6236-4AC5-80E3-45EDC0B765D1
Microorganism:

Yes

IUPAC nametriacontane
SMILESCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
InchiInChI=1S/C30H62/c1-3-5-7-9-11-13-15-17-19-21-23-25-27-29-30-28-26-24-22-20-18-16-14-12-10-8-6-4-2/h3-30H2,1-2H3
FormulaC30H62
PubChem ID12535
Molweight422.8
LogP15.8
Atoms30
Bonds27
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID31006
Supernatural-IDSN0178166

mVOC Specific Details

Boiling Point
DegreeReference
451 °C peer reviewed
Volatilization
The Henry's Law constant for triacontane is estimated as 1530 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that triacontane 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 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)(2) is estimated as 8.1 days(SRC). However, volatilization from water surfaces is expected to be attenuated by adsorption to suspended solids and sediment in the water column. The volatilization half-life from a model pond is greater than 2 years when adsorption is considered(3). Triacontane's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Triacontane is not expected to volatilize from dry soil surfaces(SRC) based upon an extrapolated vapor pressure of 2.73X10-11 mm Hg at 25 deg C(4).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 21, 2016: http://www2.epa.gov/tsca-screening-tools (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) US EPA; EXAMS II Computer Simulation (1987) (4) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989)
Solubility
In water, 5.04X10-11 mg/L at 25 deg C (est)
Literature: US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 10, 2016: http://www2.epa.gov/tsca-screening-tools
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. 3-514
Literature: #Soluble in ether; slightly soluble in ethanol; very soluble in benzene
Literature: Haynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-514
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of triacontane can be estimated to be 2.4X10+8(SRC). According to a classification scheme(2), this estimated Koc value suggests that triacontane is expected to be immobile in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 21, 2016: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
2.73X10-11 mm Hg at 25 deg C (extrapolated)Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989)
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
EukaryotaAntrodia CinnamomeananaLu et al. 2014
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
EukaryotaAntrodia CinnamomeaPDAGC/MSyes


Hentriacontane

Mass-Spectra

Compound Details

Synonymous names
HENTRIACONTANE
n-Hentriacontane
630-04-6
Untriacontane
n-Hentriacontanone
6SDG640HL3
CHEBI:5659
Hentriacontane; Untriacontane; n-Hentriacontane
UNII-6SDG640HL3
Hentriacontan
n-Hentriacontane 100 microg/mL in Hexane
CHEMBL257490
DTXSID0075443
HSDB 8361
CH3-[CH2]29-CH3
Hentriacontane, analytical standard
HY-N9971
LMFA11000573
MFCD00048745
N-C-31
STL564734
AKOS015843210
LS-15322
CS-0227064
H0012
NS00010791
C08376
T72739
Q151082
441529E2-C629-4003-A2DD-9134C4C1801B
Microorganism:

Yes

IUPAC namehentriacontane
SMILESCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
InchiInChI=1S/C31H64/c1-3-5-7-9-11-13-15-17-19-21-23-25-27-29-31-30-28-26-24-22-20-18-16-14-12-10-8-6-4-2/h3-31H2,1-2H3
FormulaC31H64
PubChem ID12410
Molweight436.8
LogP16.4
Atoms31
Bonds28
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID5659
Supernatural-IDSN0155539

mVOC Specific Details

Boiling Point
DegreeReference
438 deg CHaynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-288
Volatilization
The Henry's Law constant for hentriacontane is estimated as 2040 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that hentriacontane 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 6.1 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 8.3 days(SRC). However, volatilization from water surfaces is expected to be attenuated by adsorption to suspended solids and sediment in the water column. The volatilization half-life from a model pond is greater than 2 years when adsorption is considered(3). Hentriacontane's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Hentriacontane is not expected to volatilize from dry soil surfaces(SRC) based upon an extrapolated vapor pressure of 1.40X10-11 mm Hg at 25 deg C(4).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 21, 2016: http://www2.epa.gov/tsca-screening-tools (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) US EPA; EXAMS II Computer Simulation (1987) (4) Zwolinski BJ, Wilhoit RC; Handbook of Vapor Pressures and Heats of Vaporization of Hydrocarbons and Related Compounds. API44-TRC101. College Station, TX: Thermodynamcs Research Center (1971)
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of hentriacontane can be estimated to be 4.3X10+8(SRC). According to a classification scheme(2), this estimated Koc value suggests that hentriacontane is expected to be immobile in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 10, 2016: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
1.40X10-11 mm Hg at 25 deg C (Extrapolated)Zwolinski BJ, Wilhoit RC; Handbook of Vapor Pressures and Heats of Vaporizaton of Hydrocarbons and Related Compounds. API44-TRC101. College Station,TX: Thermodynamcs Research Center (1971)
MS-Links
MS-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno


Octacosane

Mass-Spectra

Compound Details

Synonymous names
OCTACOSANE
n-Octacosane
630-02-4
Octacosane, n-
CCRIS 680
UNII-VFF49836P8
VFF49836P8
NSC 5549
NSC-5549
EINECS 211-125-7
AI3-52615
DTXSID6058639
CHEBI:32943
HSDB 8358
CH3-[CH2]26-CH3
MFCD00009355
n-Octacosane 1000 microg/mL in Methanol
Octacosane 1000 microg/mL in Dichloromethane
NSC 5549; n-Octacosane
Octacosane, analytical standard
CH3-(CH2)26-CH3
n-Octcosane
Octacosane, 99%
DTXCID4032326
NSC5549
LMFA11000580
STL453125
AKOS015902504
HY-W272217
MCULE-9551476105
DB-054367
CS-0317451
NS00010789
O0002
D91782
Q3348776
Analytical Reagent, inverted exclamation markY97.0%(GC)
E66BE919-93E8-4101-AB46-9612FE796394
Microorganism:

Yes

IUPAC nameoctacosane
SMILESCCCCCCCCCCCCCCCCCCCCCCCCCCCC
InchiInChI=1S/C28H58/c1-3-5-7-9-11-13-15-17-19-21-23-25-27-28-26-24-22-20-18-16-14-12-10-8-6-4-2/h3-28H2,1-2H3
FormulaC28H58
PubChem ID12408
Molweight394.8
LogP14.8
Atoms28
Bonds25
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID32943
Supernatural-IDSN0483945

mVOC Specific Details

Boiling Point
DegreeReference
432 °C peer reviewed
Volatilization
The Henry's Law constant for octacosane is estimated as 870 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that octacosane 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 5.8 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)(2) is estimated as 7.9 days(SRC). However, volatilization from water surfaces is expected to be attenuated by adsorption to suspended solids and sediment in the water column. The volatilization half-life from a model pond is greater than 2 years when adsorption is considered(3). Octacosane's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). Octacosane is not expected to volatilize from dry soil surfaces(SRC) based upon an extrapolated vapor pressure of 1.60X10-9 mm Hg at 25 deg C(4).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 22, 2016: http://www2.epa.gov/tsca-screening-tools (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) US EPA; EXAMS II Computer Simulation (1987) (4) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989)
Solubility
In water, 5.6X10-10 mg/L at 25 deg C (est)
Literature: US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 10, 2016: http://www2.epa.gov/tsca-screening-tools
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. 3-424
Literature: #Miscible with acetone, soluble in benzene, chloroform
Literature: Haynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-424
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of octacosane can be estimated to be 7.1X10+7(SRC). According to a classification scheme(2), this estimated Koc value suggests that octacosane is expected to be immobile in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 22, 2016: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 17-28 (1983)
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas TaiwanensisPlant growth promotionrhizosphereJishma et al. 2017
EukaryotaCandida AlbicansNAKarami et al. 2017
ProkaryotaEscherichia ColiNAKarami et al. 2017
ProkaryotaStaphylococcus AureusNAKarami et al. 2017
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas TaiwanensisMR-VP brothGS-MSno
EukaryotaCandida AlbicansMueller Hinton broth (MB), tryptic soy broth (TSB)SPME, DVB/CAR/PDMS, GC-MSno
ProkaryotaEscherichia ColiMueller Hinton broth (MB), tryptic soy broth (TSB)SPME, DVB/CAR/PDMS, GC-MSno
ProkaryotaStaphylococcus AureusMueller Hinton broth (MB), tryptic soy broth (TSB)SPME, DVB/CAR/PDMS, GC-MSno
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno


Pentacosane

Mass-Spectra

Compound Details

Synonymous names
PENTACOSANE
n-Pentacosane
629-99-2
N-PENTACOSANE-D52
UNII-BON9H94Y8V
BON9H94Y8V
121578-13-0
EINECS 211-123-6
NSC 158663
NSC-158663
AI3-36478
DTXSID2060882
CHEBI:32938
HSDB 8355
MFCD00009353
Pentacosane, analytical standard
CH3-(CH2)23-CH3
CH3-[CH2]23-CH3
Pentacosane, 99%
DTXCID7043584
HY-N7494
LMFA11000582
NSC158663
AKOS015843190
LS-15134
Pentacosane; NSC 158663; n-Pentacosane
DB-054365
CS-0130240
NS00010787
P0139
D91907
Q151007
2A4605C9-A088-458C-AD58-AA987FF6C408
Microorganism:

Yes

IUPAC namepentacosane
SMILESCCCCCCCCCCCCCCCCCCCCCCCCC
InchiInChI=1S/C25H52/c1-3-5-7-9-11-13-15-17-19-21-23-25-24-22-20-18-16-14-12-10-8-6-4-2/h3-25H2,1-2H3
FormulaC25H52
PubChem ID12406
Molweight352.7
LogP13.1
Atoms25
Bonds22
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID32938
Supernatural-IDSN0452900

mVOC Specific Details

Boiling Point
DegreeReference
401.9 °C peer reviewed
Volatilization
The Henry's Law constant for pentacosane is estimated as 370 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that pentacosane 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)(3) is estimated as 1.9 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 7.4 days(SRC). However, adsorption to sediment and suspended solids is expected to attenuate volatilization(SRC). The estimated volatilization half-life from a model pond is greater than 2 years if adsorption is considered(4). Pentacosane is not expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 1.51X10-6 mm Hg(5).
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) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 17, 2016: http://www2.epa.gov/tsca-screening-tools (4) US EPA; EXAMS II Computer Simulation (1987) (5) Perry RH, Green D; Perry's Chemical Handbook. Physical and Chemical Data 6th ed., New York, NY: McGraw Hill (1984)
Solubility
In water, 2.046X10-8 mg/L at 25 deg C (est)
Literature: US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 17, 2016: http://www2.epa.gov/tsca-screening-tools
Literature: #Soluble in benzene, chloroform
Literature: Haynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-436
Soil Adsorption
The Koc of pentacosane is estimated as 1.2X10+7(SRC), using an estimated log Kow of 12.62(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that pentacosane is expected to be immobile in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 17, 2016: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
1.51X10-6 mm Hg at 25 deg C (extrapolated)Perry RH, Green D; Perry's Chemical Handbook. Physical and Chemical Data 6th ed., New York, NY: McGraw Hill (1984)
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaPleurotus OstreatusAgriculture Research Center, Giza, EgyptHamad et al. 2022
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanablack pepper rootSheoran et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaPleurotus OstreatusGC-MSno
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaLuria Bertani AgarSolvent extraction with hexane, GC/MSno


Henicosane

Mass-Spectra

Compound Details

Synonymous names
HENEICOSANE
n-Heneicosane
Henicosane
629-94-7
UNII-I93S5U5DMP
I93S5U5DMP
EINECS 211-118-9
AI3-36479
DTXSID9047097
CHEBI:32931
HSDB 8351
CH3-[CH2]19-CH3
MFCD00009346
Eicosane, methyl-
CH3-(CH2)19-CH3
henicosan
Henicosane #
Heneicosane, 98%
Heneicosane; n-Heneicosane
Heneicosane, analytical standard
DTXCID7027097
LMFA11000572
AKOS015902468
HY-W089845
MCULE-3230962872
AS-56310
DB-054362
CS-0132444
H0367
NS00012510
D90848
Q150955
FD8EC3D3-E6A2-47B6-9E26-13A115192857
(S)-(-)-2,2'-Bis(diphenylphosphino)-5,5',6,6',7,7',8,8'-octahydro-1,1'-binaphthyl (R)-H8-BINAP
Microorganism:

Yes

IUPAC namehenicosane
SMILESCCCCCCCCCCCCCCCCCCCCC
InchiInChI=1S/C21H44/c1-3-5-7-9-11-13-15-17-19-21-20-18-16-14-12-10-8-6-4-2/h3-21H2,1-2H3
FormulaC21H44
PubChem ID12403
Molweight296.6
LogP11
Atoms21
Bonds18
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID32931
Supernatural-IDSN0090118

mVOC Specific Details

Boiling Point
DegreeReference
359 °C peer reviewed
Volatilization
The Henry's Law constant for heneicosane is estimated as 120 atm-cu m/mole(SRC), based upon its vapor pressure, 8.73X10-8 mm Hg(1), and water solubility, 2.9X10-8 mg/L(2). This Henry's Law constant indicates that heneicosane may 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 1.8 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 6.8 days(SRC). However, adsorption to soil is expected to attenuate volatilization(SRC). The estimated volatilization half-life from a model pond is greater than 2 years if adsorption is considered(4). Heneicosane is not expected to volatilize from dry soil surfaces(SRC) based upon its vapor pressure.
Literature: (1) Perry RH, Green D; Perry's Chemical Handbook. Physical and Chemical Data. 6th ed., New York, NY: McGraw Hill (1984) (2) Coates M et al; Env Sci Tech 19: 628-32 (1985) (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)
Solubility
In water, 2.9X10-8 mg/L at 25 deg C (extrapolated)
Literature: Coates M et al; Environ Sci Technol 19: 628-32 (1985)
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. 3-288
Literature: #Slightly soluble in ethanol; soluble in petroleum 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
Soil Adsorption
The Koc of heneicosane is estimated as 1.1X10+6(SRC), using an estimated log Kow of 10.65(1) and a regression-derived equation(2). According to a classification scheme(3), this estimated Koc value suggests that heneicosane is expected to be immobile in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 15, 2016: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
8.73X10-5 mm Hg at 25 deg C (extrapolated)Perry RH, Green D; Perry's Chemical Handbook. Physical and Chemical Data 6th ed., New York, NY: McGraw Hill (1984)
MS-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas FluorescensAntifungalrhizosphereJishma et al. 2017
ProkaryotaPseudomonas RhodesiaeAntifungalrhizosphereJishma et al. 2017
ProkaryotaStreptomyces Philanthiantifungal activity against Aspergillus parasiticus TISTR 3276 and Aspergillus flavus PSRDC-4NABoukaew and Prasertsan 2020
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanablack pepper rootSheoran et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas FluorescensMR-VP brothGS-MSno
ProkaryotaPseudomonas RhodesiaeMR-VP brothGS-MSno
ProkaryotaStreptomyces Philanthisterile wheat seedsGC-MSyes
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaLuria Bertani AgarSolvent extraction with hexane, GC/MSno


Pentadecane

Mass-Spectra

Compound Details

Synonymous names
Pentadecane
N-PENTADECANE
629-62-9
Pentadekan
Pentadecane, n-
HSDB 5729
EINECS 211-098-1
NSC 172781
UNII-16H6K2S8M2
BRN 1698194
DTXSID6027268
CHEBI:28897
16H6K2S8M2
MFCD00008990
NSC-172781
DTXCID107268
EC 211-098-1
CH3-[CH2]13-CH3
4-01-00-00529 (Beilstein Handbook Reference)
n-Pentadecane 100 microg/mL in Acetonitrile
Pentadecane, analytical standard
CH3-(CH2)13-CH3
Pentadecane; NSC 172781; n-Pentadecane
pentadecan
dipentylfumarate
Medicinal Plant
1-Penfadecane,(S)
PENTADECANE (N)
Pentadecane, >=99%
PENTADECANE [INCI]
ghl.PD_Mitscher_leg0.43
N-PENTADECANE [HSDB]
CH3(CH2)13CH3
CHEMBL1234557
UNII: 16H6K2S8M2
Pentadecane_Ramanathan &Gurudeeban
Pentadecane, >=98.0% (GC)
Tox21_300535
LMFA11000006
NSC172781
STL280516
AKOS015902386
MCULE-1292711626
NCGC00164185-01
NCGC00164185-02
NCGC00254392-01
CAS-629-62-9
LS-14458
NS00003105
P0606
C08388
D97801
Q150831
896D4B7E-BF33-4D54-82CE-7360D88E8DC8
Microorganism:

Yes

IUPAC namepentadecane
SMILESCCCCCCCCCCCCCCC
InchiInChI=1S/C15H32/c1-3-5-7-9-11-13-15-14-12-10-8-6-4-2/h3-15H2,1-2H3
FormulaC15H32
PubChem ID12391
Molweight212.41
LogP7.7
Atoms15
Bonds12
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID28897
Supernatural-IDSN0446675

mVOC Specific Details

Boiling Point
DegreeReference
270.6 °C peer reviewed
Volatilization
The Henry's Law constant for n-pentadecane is estimated as 34.4 atm-cu m/mole(SRC) derived from its vapor pressure, 0.00492 mm Hg(1), and water solubility, 4X10-5 mg/L(2). This Henry's Law constant indicates that n-pentadecane 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 5.8 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 30 months if adsorption is considered(4). n-Pentadecane's estimated Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). n-Pentadecane is not expected to volatilize from dry soil surfaces based upon its vapor pressure(SRC).
Literature: (1) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Dhemicals: Data Compilation. Design Institute for Physical Property Data, American Institute of Chemical Engineers. Washington, DC: Taylor & Francis, (1994) (2) Yalkowsky SH et al; Handbook of Aqueous Solubility Data. 2nd ed., Boca Raton, FL: CRC Press, p. 1081 (2010) (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)
Solubility
In water, 4.0X10-5 mg/L at 25 deg C
Literature: Yalkowsky, S.H., He, Yan, Jain, P. Handbook of Aqueous Solubility Data Second Edition. CRC Press, Boca Raton, FL 2010, p. 806
Literature: #Very soluble in ethyl ether, ethanol
Literature: Haynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-436
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of n-pentadecane can be estimated to be 29,200(SRC). According to a classification scheme(2), this estimated Koc value suggests that n-pentadecane is expected to be immobile in soil. In a study conducted to mimic a spill of 1.27 L/sq-m, n-pentadecane (present in JP-4 jet fuel) was transported to a depth of 50 cm; at the end of the study (134 days), it was still detected(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) Ross WD et al; Environmental Fate and Biological Consequences of Chemicals Related to Air Force Activities. NTIS AD-A121 288/5. Dayton,OH: Monsanto Research Corp. pp. 173 (1982)
Vapor Pressure
PressureReference
4.92X10-3 mm Hg at 25 deg CDaubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Dhemicals: Data Compilation. Design Institute for Physical Property Data, American Institute of Chemical Engineers. Washington, DC: Taylor & Francis (1994)
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas FluorescensPlant growth promotionrhizosphereJishma et al. 2017
ProkaryotaPseudomonas PutidaPlant growth promotion and ISRrhizosphereJishma et al. 2017
ProkaryotaPseudomonas TaiwanensisPlant growth promotionrhizosphereJishma et al. 2017
EukaryotaCandida AlbicansNAKarami et al. 2017
ProkaryotaEscherichia ColiNAKarami et al. 2017
ProkaryotaStaphylococcus AureusNAKarami et al. 2017
ProkaryotaBacillus Velezensismaize seedMassawe et al. 2018
ProkaryotaPseudomonas AeruginosaLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaStreptomyces Philanthiantifungal activity against Aspergillus parasiticus TISTR 3276 and Aspergillus flavus PSRDC-4NABoukaew and Prasertsan 2020
ProkaryotaErwinia Amylovoraenhances Arabidopsis thaliana shoot and root growthbacterial collection of the LabParmagnani et al. 2023
EukaryotaFusarium Graminearumn/aNABusko et al. 2014
ProkaryotaPseudomonas Fluorescensn/aNAFernando et al. 2005
ProkaryotaPseudomonas Corrugatan/aNAFernando et al. 2005
ProkaryotaPseudomonas Chlororaphisn/aNAFernando et al. 2005
ProkaryotaPseudomonas Aurantiacan/aNAFernando et al. 2005
EukaryotaTrichoderma Harzianumn/aNAZhang et al. 2014
ProkaryotaBurkholderia Saccharin/aNABlom et al. 2011
ProkaryotaSerratia Entomophilan/aNABlom et al. 2011
ProkaryotaAzospirillum Brasilensepromotion of performance of Chlorella sorokiniana Shihculture collection DSMZ 1843Amavizca et al. 2017
ProkaryotaBacillus Pumiluspromotion of performance of Chlorella sorokiniana ShihNAAmavizca et al. 2017
ProkaryotaEscherichia Colipromotion of performance of Chlorella sorokiniana ShihNAAmavizca et al. 2017
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Simiaenarhizosphere of a soybean field in the province of Rajasthan, IndiaVaishnav et al. 2016
ProkaryotaLentilactobacillus BuchneriNANASquara et al. 2022
ProkaryotaLacticaseibacillus ParacaseiNANASquara et al. 2022
EukaryotaWickerhamomyces AnomalusNANAShi et al. 2022
ProkaryotaLactiplantibacillus PlantarumChen et al. 2023
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas FluorescensMR-VP brothGS-MSno
ProkaryotaPseudomonas PutidaNBGS-MSno
ProkaryotaPseudomonas TaiwanensisMR-VP brothGS-MSno
EukaryotaCandida AlbicansMueller Hinton broth (MB), tryptic soy broth (TSB)SPME, DVB/CAR/PDMS, GC-MSno
ProkaryotaEscherichia ColiMueller Hinton broth (MB), tryptic soy broth (TSB)SPME, DVB/CAR/PDMS, GC-MSno
ProkaryotaStaphylococcus AureusMueller Hinton broth (MB), tryptic soy broth (TSB)SPME, DVB/CAR/PDMS, GC-MSno
ProkaryotaBacillus VelezensisMinimal salt mediumSPME, GC-MSno
ProkaryotaPseudomonas AeruginosaTSB mediaHS-SPME/GC-MSno
ProkaryotaStreptomyces Philanthisterile wheat seedsGC-MSno
ProkaryotaErwinia AmylovoraSBSE/GC-MSno
EukaryotaFusarium Graminearumyeast extract sucrose agarSPME/GC-MSno
ProkaryotaPseudomonas Fluorescensn/an/ano
ProkaryotaPseudomonas Corrugatan/an/ano
ProkaryotaPseudomonas Chlororaphisn/an/ano
ProkaryotaPseudomonas Aurantiacan/an/ano
EukaryotaTrichoderma HarzianumMinimal mediaSPME/GC-MSno
ProkaryotaBurkholderia SacchariLB, MSHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia Entomophilan/aHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaAzospirillum BrasilenseTSASPME-GCno
ProkaryotaBacillus PumilusTSASPME-GCno
ProkaryotaEscherichia ColiTSASPME-GCno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas SimiaeNutrient broth; King's B agarGC/MSno
ProkaryotaLentilactobacillus Buchnerimaize silageHS-SPME coupled with GC-TOF MSno
ProkaryotaLacticaseibacillus Paracaseimaize silageHS-SPME coupled with GC-TOF MSno
EukaryotaWickerhamomyces Anomalusmedium consisted of glucose (20 g/l), peptone (5 g/l), agar (20 g/l) and amoxicillin (1 g/l)SPME with GC-MSno
EukaryotaWickerhamomyces Anomalussolid-state fermentation starter culture DaquSPME coupled with GC-MSno
ProkaryotaLactiplantibacillus Plantarumfermentation of ginkgo kernel juiceGC-IMSno


Heptacosane

Mass-Spectra

Compound Details

Synonymous names
HEPTACOSANE
593-49-7
n-Heptacosane
VP371W2GJS
Heptacosane; n-Heptacosane
UNII-VP371W2GJS
EINECS 209-792-4
n-Heptacosane 100 microg/mL in Hexane
AI3-36283
QSPL 047
QSPL 073
Heptacosane, analytical standard
DTXSID6058637
CHEBI:32941
HSDB 8357
CH3-[CH2]25-CH3
Heptacosane, >=98.0% (GC)
LMFA11000574
MFCD00009862
AKOS016013111
LS-15223
CS-0314668
H0017
NS00010782
C16045
Q151028
4557DE11-D8CE-461B-BBA4-5A5BBDA1A670
Microorganism:

Yes

IUPAC nameheptacosane
SMILESCCCCCCCCCCCCCCCCCCCCCCCCCCC
InchiInChI=1S/C27H56/c1-3-5-7-9-11-13-15-17-19-21-23-25-27-26-24-22-20-18-16-14-12-10-8-6-4-2/h3-27H2,1-2H3
FormulaC27H56
PubChem ID11636
Molweight380.7
LogP14.2
Atoms27
Bonds24
H-bond Acceptor0
H-bond Donor0
Chemical Classificationalkanes saturated hydrocarbons
CHEBI-ID32941
Supernatural-IDSN0027414

mVOC Specific Details

Boiling Point
DegreeReference
442 deg CHaynes, W.M. (ed.). CRC Handbook of Chemistry and Physics. 95th Edition. CRC Press LLC, Boca Raton: FL 2014-2015, p. 3-288
Volatilization
The Henry's Law constant for heptacosane is estimated as 655 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that heptacosane 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 5.7 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 7.7 days(SRC). Heptacosane's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). The volatilization half-life from a model pond is greater than 2 years when adsorption is considered. Heptacosane is not expected to volatilize from dry soil surfaces(SRC) based upon an extrapolated vapor pressure of 2.81X10-7 mm Hg at 25 deg C(3).
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 8, 2016: http://www2.epa.gov/tsca-screening-tools (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Perry RH, Green D; Perry's Chemical Handbook. Physical and Chemical data. 6th ed., New York, NY: McGraw-Hill (1984)
Solubility
In water, 2.8X10-9 mg/L at 25 deg C (est)
Literature: US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 10, 2016: http://www2.epa.gov/tsca-screening-tools
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. 3-288
Literature: #Insoluble in ethanol; slightly soluble in 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
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of heptacosane can be estimated to be 3.9X10+7(SRC). According to a classification scheme(2), this estimated Koc value suggests that heptacosane is expected to be immobile in soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 8, 2016: http://www2.epa.gov/tsca-screening-tools (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
2.8X10-9 mg/L at 25 deg C (extrapolated)Perry RH, Green D; Perry's Chemical Handbook. Physical and Chemical data. New York, NY: McGraw-Hill 6th ed (1984)
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas RhodesiaePlant growth promotion and ISRrhizosphereJishma et al. 2017
ProkaryotaPseudomonas RhodesiaeAntifungalrhizosphereJishma et al. 2017
EukaryotaTuber Mesentericumn/aFortywoodland of the Basilicata regionMauriello et al. 2004
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaStaphylococcus AureusWang et al. 2023
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas RhodesiaeNBGS-MSno
ProkaryotaPseudomonas RhodesiaeMR-VP brothGS-MSno
EukaryotaTuber Mesentericumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaStaphylococcus Aureusraw Shiyang chickenHS-GC-IMS/HS-SPME-GC-MSno


Acetic Acid

Mass-Spectra

Compound Details

Synonymous names
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%
Microorganism:

Yes

IUPAC nameacetic acid
SMILESCC(=O)O
InchiInChI=1S/C2H4O2/c1-2(3)4/h1H3,(H,3,4)
FormulaC2H4O2
PubChem ID176
Molweight60.05
LogP-0.2
Atoms4
Bonds0
H-bond Acceptor2
H-bond Donor1
Chemical Classificationacids organic acids
CHEBI-ID15366
Supernatural-IDSN0314461

mVOC Specific Details

Boiling Point
DegreeReference
117.9 °C peer reviewed
Volatilization
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)
Soil Adsorption
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)
Vapor Pressure
PressureReference
15.7 mm Hg at 25 deg C /Extrapolated/Daubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
MS-MS Spectrum 2640 - LC-ESI-QQ (API3000, Applied Biosystems) 50V Negative
MS-MS Spectrum 2637 - LC-ESI-QQ (API3000, Applied Biosystems) 20V Negative
MS-MS Spectrum 2638 - LC-ESI-QQ (API3000, Applied Biosystems) 30V Negative
MS-MS Spectrum 179743
MS-MS Spectrum 182077
MS-MS Spectrum 182078
MS-MS Spectrum 71 - Quattro_QQQ 40V Positive delivery=Flow_Injection analyzer=Triple_Quad
MS-MS Spectrum 179744
MS-MS Spectrum 70 - Quattro_QQQ 25V Positive delivery=Flow_Injection analyzer=Triple_Quad
MS-MS Spectrum 2636 - LC-ESI-QQ (API3000, Applied Biosystems) 10V Negative
MS-MS Spectrum 179742
MS-MS Spectrum 69 - Quattro_QQQ 10V Positive delivery=Flow_Injection analyzer=Triple_Quad
MS-MS Spectrum 182076
MS-MS Spectrum 2635 - EI-B (HITACHI M-80B) Positive
MS-MS Spectrum 2639 - LC-ESI-QQ (API3000, Applied Biosystems) 40V Negative
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas AeruginosaNANAZhu et al. 2010
ProkaryotaStaphylococcus AureusNANAZhu et al. 2010
ProkaryotaBurkholderia CepaciaNANAThorn et al. 2011
ProkaryotaBurkholderia CepaciaNANADryahina et al. 2016
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAThorn et al. 2011
ProkaryotaNeisseria MeningitidisNANAAllardyce et al. 2006
ProkaryotaNeisseria MeningitidisNANAScotter et al. 2006
ProkaryotaProteus MirabilisNANAThorn et al. 2011
ProkaryotaPseudomonas AeruginosaNANAAllardyce et al. 2006
ProkaryotaPseudomonas AeruginosaNANADryahina et al. 2016
ProkaryotaStaphylococcus AureusNANAAllardyce et al. 2006
ProkaryotaStaphylococcus AureusNANAThorn et al. 2011
ProkaryotaStaphylococcus AureusNANADryahina et al. 2016
ProkaryotaStenotrophomonas MaltophiliaNANADryahina et al. 2016
ProkaryotaStreptococcus PneumoniaeNANAAllardyce et al. 2006
ProkaryotaEscherichia ColiNANAFitzgerald et al. 2021
ProkaryotaStaphylococcus AureusNANAFitzgerald et al. 2021
ProkaryotaKlebsiella PneumoniaeNANARees et al. 2016a
ProkaryotaPseudomonas AeruginosaNANABean et al. 2012
ProkaryotaPseudomonas AeruginosaNANADavis et al. 2020
EukaryotaAspergillus FumigatusNANABazemore et al. 2012
ProkaryotaEscherichia ColiNANABoots et al. 2014
ProkaryotaHaemophilus InfluenzaeNANAFilipiak et al. 2012
ProkaryotaStaphylococcus AureusNANAFilipiak et al. 2012
ProkaryotaStreptococcus PneumoniaeNANAFilipiak et al. 2012
ProkaryotaStaphylococcus EpidermidisNATimm et al. 2018
EukaryotaTrichoderma Harzianum0NALi et al. 2018
EukaryotaTrichoderma Virens0NALi et al. 2018
EukaryotaTrichoderma HarzianumNALi et al. 2018
EukaryotaTrichoderma VirensNALi et al. 2018
ProkaryotaPseudomonas Sp.antifungal activity against Thielaviopsis ethacetica mycelial growthBrazilian Biorenewables National Laboratory – LNBR/CNPEM Microorganism Collection, Campinas, SP; isolatedfrom soil and roots of highly productive sugarcane-producing regions; BrazilFreitas et al. 2022
ProkaryotaArthrobacter Nicotinovoransstimulate growth in Arabidopsis thaliana seedlings depending on inoculum concentrationavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaErwinia Persicinaavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaStaphylococcus AureusLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaEscherichia ColiLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaStaphylococcus Epidermidisstrains were provided by Prof. O'Gara at NUI GalwayFitzgerald et al. 2020
EukaryotaMortierella Alpina/globalpinaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaMortierella Angustaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaMortierella Bainieriisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaLinnemannia Exiguaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaLinnemannia Gamsiiisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaMortierella Gemmiferaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaPodila Horticolaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaPodila Humilis/verticilataisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaLinnemannia Hyalinaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaEntomortierella Parvisporaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaMortierella Pseudozygosporaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaMortierella Solitariaisolate from different types of soil in AustriaTelagathoti et al. 2021
EukaryotaMortierella Zonataisolate from different types of soil in AustriaTelagathoti et al. 2021
ProkaryotaStaphylococcus AureusAmerican Type Culture CollectionJenkins and Bean 2020
ProkaryotaBacillus VelezensisNARiu et al. 2022
ProkaryotaEscherichia ColiSwedish Institute for Communicable Disease Control (SMI), Stockholm, SwedenSousa et al. 2023
ProkaryotaBacillus Subtilispromote biomass production of Arabidopsis thalianarhizosphere of Haloxylon ammodendronHe et al. 2023
ProkaryotaBurkholderia Tropican/aNATenorio-Salgado et al. 2013
ProkaryotaBacillus Sp.Highly attractive to Mexican fruit flies.NASchulz and Dickschat 2007
ProkaryotaStaphylococcus Sp.Highly attractive to Mexican fruit flies.NASchulz and Dickschat 2007
ProkaryotaClostridium Sp.n/aNAStotzky and Schenck 1976
ProkaryotaVeillonella Sp.Reduction of heat resistant spores, prevention of spore formation of Salmonella typhimurium, Salmonella enteritidis, Escherichia coli, Pseudomonas aeroginosa, Clostridium perfringenes and Clostridium difficile.NAHinton and Hume 1995
ProkaryotaBacteroides FragilisReduction of heat resistant spores, prevention of spore formation of Salmonella typhimurium, Salmonella enteritidis, Escherichia coli, Pseudomonas aeroginosa, Clostridium perfringenes and Clostridium difficile.NAHinton and Hume 1995
EukaryotaPenicillium Aurantiogriseumn/aNABörjesson et al. 1990
ProkaryotaBacteroides Biviusn/aNAWiggins et al. 1985
ProkaryotaBacteroides Distasonisn/aNAWiggins et al. 1985
ProkaryotaBacteroides Ovatusn/aNAWiggins et al. 1985
ProkaryotaBacteroides Thetaiotaomicronn/aNAWiggins et al. 1985
ProkaryotaBacteroides Vulgatusn/aNAWiggins et al. 1985
ProkaryotaClostridium Cadaverumn/aNAWiggins et al. 1985
ProkaryotaClostridium Histolyticumn/aNAWiggins et al. 1985
ProkaryotaClostridium Tertiumn/aNAWiggins et al. 1985
ProkaryotaClostridium Bifermentansn/aNAWiggins et al. 1985
ProkaryotaClostridium Fallaxn/aNAWiggins et al. 1985
ProkaryotaClostridium Butyricumn/aNAWiggins et al. 1985
ProkaryotaClostridium Sporogenesn/aNAWiggins et al. 1985
ProkaryotaLactobacillus Casein/aNATracey and Britz 1989
ProkaryotaLactobacillus Plantarumn/aNATracey and Britz 1989
ProkaryotaPediococcus Damnosusn/aNATracey and Britz 1989
ProkaryotaLeuconostoc Cremorisn/aNATracey and Britz 1989
ProkaryotaLeuconostoc Dextranicumn/aNATracey and Britz 1989
ProkaryotaLactococcus Lactisn/aNATracey and Britz 1989
ProkaryotaOenococcus Oenin/aNATracey and Britz 1989
ProkaryotaPorphyromonas Gingivalisn/aNAKurita-Ochiai et al. 1995
ProkaryotaPrevotella Loescheiin/aNAKurita-Ochiai et al. 1995
ProkaryotaPrevotella Intermedian/aNAKurita-Ochiai et al. 1995
ProkaryotaFusobacterium Nucleatumn/aNAKurita-Ochiai et al. 1995
ProkaryotaActinobacillus Actinomycetemcomitansn/aNAKurita-Ochiai et al. 1995
ProkaryotaCapnocytophaga Ochracean/aNAKurita-Ochiai et al. 1995
ProkaryotaEscherichia Colin/aNABunge et al. 2008
ProkaryotaShigella Flexnerin/aNABunge et al. 2008
ProkaryotaSalmonella Enterican/aNABunge et al. 2008
EukaryotaCandida Tropicalisn/aNABunge et al. 2008
ProkaryotaSerratia Sp.n/aNABruce et al. 2004
EukaryotaSaccharomyces Cerevisiaen/aNABruce et al. 2004
EukaryotaTuber Excavatumn/aFortywoodland of the Basilicata regionMauriello et al. 2004
EukaryotaTuber Aestivumn/aAgricultural Centre of Castilla and León Community (Monasterio de la Santa Espina, Valladolid, Spain) and Navaleno (Soria, Spain).Diaz et al. 2003
EukaryotaTuber Melanosporumn/aAgricultural Centre of Castilla and León Community (Monasterio de la Santa Espina, Valladolid, Spain) and Navaleno (Soria, Spain).Diaz et al. 2003
EukaryotaMuscodor Albusn/aNACorcuff et al. 2011
ProkaryotaKlebsiella Pneumoniaen/aNAJulak et al. 2003
ProkaryotaStaphylococcus Aureusn/aNAJulak et al. 2003
ProkaryotaAzospirillum Brasilensepromotion of performance of Chlorella sorokiniana Shihculture collection DSMZ 1843Amavizca et al. 2017
ProkaryotaBacillus Pumiluspromotion of performance of Chlorella sorokiniana ShihNAAmavizca et al. 2017
ProkaryotaAcinetobacter Baumanniiclinical exudatesJulak et al. 2003
ProkaryotaActinomyces Europaeusclinical exudatesJulak et al. 2003
ProkaryotaActinomyces Naeslundiiclinical exudatesJulak et al. 2003
ProkaryotaBacteroides Capillosusclinical exudatesJulak et al. 2003
ProkaryotaBacteroides Pyogenesclinical exudatesJulak et al. 2003
ProkaryotaClostridium Difficileclinical exudatesJulak et al. 2003
ProkaryotaClostridium Perfringensclinical exudatesJulak et al. 2003
ProkaryotaClostridium Ramosumclinical exudatesJulak et al. 2003
ProkaryotaClostridium Septicumclinical exudatesJulak et al. 2003
ProkaryotaEnterococcus Faecalisclinical exudatesJulak et al. 2003
ProkaryotaEubacterium Lentumclinical exudatesJulak et al. 2003
ProkaryotaFusobacterium Simiaeclinical exudatesJulak et al. 2003
ProkaryotaFusobacterium Necrophorumclinical exudatesJulak et al. 2003
ProkaryotaLactobacillus Acidophilusclinical exudatesJulak et al. 2003
ProkaryotaNocardia Sp.clinical exudatesJulak et al. 2003
ProkaryotaPeptostreptococcus Anaerobiusclinical exudatesJulak et al. 2003
ProkaryotaPeptostreptococcus Asaccharolyticusclinical exudatesJulak et al. 2003
ProkaryotaPeptostreptococcus Prevotiiclinical exudatesJulak et al. 2003
ProkaryotaPropionibacterium Acnesclinical exudatesJulak et al. 2003
ProkaryotaPropionibacterium Propionicumclinical exudatesJulak et al. 2003
ProkaryotaProteus Mirabilisclinical exudatesJulak et al. 2003
ProkaryotaStaphylococcus Epidermidisclinical exudatesJulak et al. 2003
ProkaryotaStreptococcus Agalactiaeclinical exudatesJulak et al. 2003
ProkaryotaStreptococcus Pyogenesclinical exudatesJulak et al. 2003
ProkaryotaStreptococcus Viridansclinical exudatesJulak et al. 2003
EukaryotaCandida Albicansclinical exudatesJulak et al. 2003
ProkaryotaStreptococcus Uberismilk of cowsHettinga et al. 2008
ProkaryotaStreptococcus Dysgalactiaemilk of cowsHettinga et al. 2008
ProkaryotaStreptococcus PneumoniaeclinicPreti et al. 2009
ProkaryotaHaemophilus InfluenzaeclinicPreti et al. 2009
EukaryotaSaccharomyces Cerevisiaegrape vineBecher et al. 2012
EukaryotaPenicillium CamembertiNALarsen 1998
EukaryotaPenicillium CaseifulvumNALarsen 1998
ProkaryotaArthrobacter Agilisnarhizosphere of maize plantsVelázquez-Becerra et al. 2011
ProkaryotaPseudomonas Brassicacearumreduces mycelium growth and sclerotia germination of Sclerotinia sclerotiorum USB-F593; lyses red blood cellsrhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Simiaenarhizosphere of a soybean field in the province of Rajasthan, IndiaVaishnav et al. 2016
ProkaryotaLactobacillus RhamnosusnaDomiati cheesePogačić et al. 2016
ProkaryotaLentilactobacillus BuchneriNANASquara et al. 2022
ProkaryotaLacticaseibacillus ParacaseiNANASquara et al. 2022
EukaryotaZygosaccharomyces RouxiiNANAPei et al. 2022
ProkaryotaSerratia Sp.NANAAlmeida et al. 2022
EukaryotaAureobasidium PullulansNANAMozūraitis et al. 2022
EukaryotaCryptococcus WieringaeNANAMozūraitis et al. 2022
EukaryotaHanseniaspora UvarumNANAMozūraitis et al. 2022
EukaryotaPichia KudriavzeviiNANAMozūraitis et al. 2022
EukaryotaPichia FermentansNANAMozūraitis et al. 2022
EukaryotaPichia MembranifaciensNANAMozūraitis et al. 2022
EukaryotaSaccharomyces ParadoxusNANAMozūraitis et al. 2022
EukaryotaTorulaspora DelbrueckiiNANAMozūraitis et al. 2022
EukaryotaPichia AnomalaNANAMozūraitis et al. 2022
EukaryotaMetschnikowia PulcherrimaNANAMozūraitis et al. 2022
ProkaryotaStaphylococcus EquorumNANAToral et al. 2021
ProkaryotaBacillus AtrophaeusNANAToral et al. 2021
ProkaryotaPeribacillus Sp.NANAToral et al. 2021
ProkaryotaBacillus VelezensisNANAToral et al. 2021
EukaryotaWickerhamomyces AnomalusNANAShi et al. 2022
ProkaryotaBacillus SubtilisNANALee et al. 2023
ProkaryotaAcetobacter IndonesiensisNANATran et al. 2022
EukaryotaLentinula EdodesGeng et al. 2024
ProkaryotaLactiplantibacillus PlantarumChen et al. 2023
ProkaryotaLactobacillus PlantarumZhang et al. 2023
ProkaryotaBacillus ThuringiensisKoilybayeva et al. 2023
ProkaryotaBacillus ToyonensisKoilybayeva et al. 2023
ProkaryotaBacillus AcidiproducensKoilybayeva et al. 2023
ProkaryotaBacillus CereusKoilybayeva et al. 2023
ProkaryotaBacillus SafensisKoilybayeva et al. 2023
ProkaryotaLactobacillus PlantarumMa et al. 2023
EukaryotaAspergillus FlavusKate et al. 2023
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas AeruginosaTSBSESI-MSno
ProkaryotaStaphylococcus AureusTSBSESI-MSno
ProkaryotaBurkholderia CepaciaTYESIFT-MSno
ProkaryotaBurkholderia CepaciaNBSIFT-MSno
ProkaryotaBurkholderia CepaciaMHBSIFT-MSno
ProkaryotaBurkholderia CepaciaBHISIFT-MSno
ProkaryotaEscherichia Colihuman bloodSIFT-MSno
ProkaryotaEscherichia ColiBacT/ALERT FASIFT-MSno
ProkaryotaEscherichia ColiTYESIFT-MSno
ProkaryotaNeisseria Meningitidishuman bloodSIFT-MSno
ProkaryotaProteus MirabilisTYESIFT-MSno
ProkaryotaPseudomonas Aeruginosahuman bloodSIFT-MSno
ProkaryotaPseudomonas AeruginosaNBSIFT-MSno
ProkaryotaPseudomonas AeruginosaBHISIFT-MSno
ProkaryotaPseudomonas AeruginosaMHBSIFT-MSno
ProkaryotaStaphylococcus Aureushuman bloodSIFT-MSno
ProkaryotaStaphylococcus AureusTYESIFT-MSno
ProkaryotaStaphylococcus AureusMHBSIFT-MSno
ProkaryotaStaphylococcus AureusNBSIFT-MSno
ProkaryotaStaphylococcus AureusBHISIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaMHBSIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaBHISIFT-MSno
ProkaryotaStenotrophomonas MaltophiliaNBSIFT-MSno
ProkaryotaStreptococcus Pneumoniaehuman bloodSIFT-MSno
ProkaryotaEscherichia ColiBHISPME/GC-MSno
ProkaryotaEscherichia ColiTSBSPME/GC-MSno
ProkaryotaEscherichia ColiLBSPME/GC-MSno
ProkaryotaStaphylococcus AureusBHISPME/GC-MSno
ProkaryotaStaphylococcus AureusTSBSPME/GC-MSno
ProkaryotaStaphylococcus AureusLBSPME/GC-MSno
ProkaryotaKlebsiella Pneumoniaehuman bloodSPME/GCxGC-MSno
ProkaryotaPseudomonas Aeruginosalysogeny brothSPME/GCxGC-MSno
ProkaryotaPseudomonas AeruginosaLB brothSPME/GCxGC-MSno
EukaryotaAspergillus FumigatusSDA + ElastinTD/GC-MSno
ProkaryotaEscherichia ColiMueller–HintonTD/GC-MSno
ProkaryotaHaemophilus InfluenzaeTryptic soya supp. factors X&VTD/GC-MSno
ProkaryotaStaphylococcus Aureustryptic soy brothTD/GC-MSno
ProkaryotaStreptococcus PneumoniaeTryptic soyaTD/GC-MSno
ProkaryotaStaphylococcus EpidermidisTSASPME, GC-MSno
EukaryotaTrichoderma HarzianumPDA plateSPME-GC-MSno
EukaryotaTrichoderma VirensPDA plateSPME-GC-MSno
EukaryotaTrichoderma Harzianumpotato dextrose agarSPME, GC-MSno
EukaryotaTrichoderma Virenspotato dextrose agarSPME, GC-MSno
ProkaryotaPseudomonas Sp.LB mediaHS-SPME/GC-MSno
ProkaryotaPseudomonas Sp.LB media, DYGS mediaHS-SPME/GC-MSno
ProkaryotaArthrobacter NicotinovoransLB mediaSPME/GC-MSno
ProkaryotaErwinia PersicinaLB mediaSPME/GC-MSno
ProkaryotaStaphylococcus AureusTSB mediaHS-SPME/GC-MSno
ProkaryotaEscherichia ColiTSB mediaHS-SPME/GC-MSno
ProkaryotaStaphylococcus EpidermidisTSB mediaHS-SPME/GC-MSno
EukaryotaMortierella Alpina/globalpinaPD agarPTR-ToF-MSno
EukaryotaMortierella AngustaPD agarPTR-ToF-MSno
EukaryotaMortierella BainieriPD agarPTR-ToF-MSno
EukaryotaLinnemannia ExiguaPD agarPTR-ToF-MSno
EukaryotaLinnemannia GamsiiPD agarPTR-ToF-MSno
EukaryotaMortierella GemmiferaPD agarPTR-ToF-MSno
EukaryotaPodila HorticolaPD agarPTR-ToF-MSno
EukaryotaPodila Humilis/verticilataPD agarPTR-ToF-MSno
EukaryotaLinnemannia HyalinaPD agarPTR-ToF-MSno
EukaryotaEntomortierella ParvisporaPD agarPTR-ToF-MSno
EukaryotaMortierella PseudozygosporaPD agarPTR-ToF-MSno
EukaryotaMortierella SolitariaPD agarPTR-ToF-MSno
EukaryotaMortierella ZonataPD agarPTR-ToF-MSno
ProkaryotaStaphylococcus AureusBHI media, TSB mediaHS-SPME/GC×GC-TOFMSno
ProkaryotaBacillus VelezensisTSA mediaSPME/GC-MSno
ProkaryotaEscherichia Colirocket lysateHS-SPME/GC-MSno
ProkaryotaBacillus Subtilis1/2 MS mediaSPME/GC-MSno
ProkaryotaBurkholderia TropicaPotato dextrose agarHeadspace trapping/ GC-MSno
ProkaryotaBacillus Sp.n/an/ano
ProkaryotaStaphylococcus Sp.n/an/ano
ProkaryotaClostridium Sp.n/an/ano
ProkaryotaVeillonella Sp.n/an/ano
ProkaryotaBacteroides Fragilisn/an/ano
EukaryotaPenicillium Aurantiogriseumn/an/ano
ProkaryotaBacteroides Biviusn/an/ano
ProkaryotaBacteroides Distasonisn/an/ano
ProkaryotaBacteroides Ovatusn/an/ano
ProkaryotaBacteroides Thetaiotaomicronn/an/ano
ProkaryotaBacteroides Vulgatusn/an/ano
ProkaryotaClostridium Cadaverumn/an/ano
ProkaryotaClostridium Histolyticumn/an/ano
ProkaryotaClostridium Tertiumn/an/ano
ProkaryotaClostridium Bifermentansn/an/ano
ProkaryotaClostridium Fallaxn/an/ano
ProkaryotaClostridium Butyricumn/an/ano
ProkaryotaClostridium Sporogenesn/an/ano
ProkaryotaLactobacillus Casein/an/ano
ProkaryotaLactobacillus Plantarumn/an/ano
ProkaryotaPediococcus Damnosusn/an/ano
ProkaryotaLeuconostoc Cremorisn/an/ano
ProkaryotaLeuconostoc Dextranicumn/an/ano
ProkaryotaLactococcus Lactisn/an/ano
ProkaryotaOenococcus Oenin/an/ano
ProkaryotaPorphyromonas Gingivalisn/an/ano
ProkaryotaPrevotella Loescheiin/an/ano
ProkaryotaPrevotella Intermedian/an/ano
ProkaryotaFusobacterium Nucleatumn/an/ano
ProkaryotaActinobacillus Actinomycetemcomitansn/an/ano
ProkaryotaCapnocytophaga Ochracean/an/ano
ProkaryotaEscherichia Colin/an/ano
ProkaryotaShigella Flexnerin/an/ano
ProkaryotaSalmonella Enterican/an/ano
EukaryotaCandida Tropicalisn/an/ano
ProkaryotaSerratia Sp.n/an/ano
EukaryotaSaccharomyces Cerevisiaen/an/ano
EukaryotaTuber Excavatumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
EukaryotaTuber Aestivumn/an/ano
EukaryotaTuber Melanosporumn/an/ano
EukaryotaMuscodor Albusn/aHeadspace sampler/GC-MSno
ProkaryotaKlebsiella PneumoniaeVF (peptone, NaCl) and VL broth (casein hydrolysate, yeast extract, beef extract, cysteine, glucose, NaCl)HS-SPME/GC-MS no
ProkaryotaStaphylococcus AureusVF (peptone, NaCl) and VL broth (casein hydrolysate, yeast extract, beef extract, cysteine, glucose, NaCl)HS-SPME/GC-MS no
ProkaryotaAzospirillum BrasilenseTSASPME-GCno
ProkaryotaBacillus PumilusTSASPME-GCno
ProkaryotaAcinetobacter Baumanniipeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaActinomyces Europaeuspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaActinomyces Naeslundiipeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaBacteroides Capillosuspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaBacteroides Pyogenespeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaClostridium Difficilepeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaClostridium Perfringenspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaClostridium Ramosumpeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaClostridium Septicumpeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaEnterococcus Faecalispeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaEubacterium Lentumpeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaFusobacterium Simiaepeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaFusobacterium Necrophorumpeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaLactobacillus Acidophiluspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaNocardia Sp.peptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaPeptostreptococcus Anaerobiuspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaPeptostreptococcus Asaccharolyticuspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaPeptostreptococcus Prevotiipeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaPropionibacterium Acnespeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaPropionibacterium Propionicumpeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaProteus Mirabilispeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaStaphylococcus Epidermidispeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaStreptococcus Agalactiaepeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaStreptococcus Pyogenespeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaStreptococcus Viridanspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
EukaryotaCandida Albicanspeptone/casein hydrolysate, yeast extract, beef extract, glucoseGC-FID FSOT NUKOLyes
ProkaryotaStreptococcus UberisGCMS DSQno
ProkaryotaStreptococcus DysgalactiaeGCMS DSQno
ProkaryotaStreptococcus PneumoniaeBlood agar/chocolate blood agaHS-SPME/GC-MS no
ProkaryotaHaemophilus InfluenzaeBlood agar/chocolate blood agaHS-SPME/GC-MS no
EukaryotaSaccharomyces Cerevisiaesynthetic minimal mediumGC-MS, EIyes
EukaryotaPenicillium Camembertino
EukaryotaPenicillium Caseifulvumno
ProkaryotaArthrobacter AgilisLB medium/NA mediumSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas SimiaeNutrient broth; King's B agarGC/MSno
ProkaryotaLactobacillus Rhamnosuscurd-based broth mediumGC/MSyes
ProkaryotaLentilactobacillus Buchnerimaize silageHS-SPME coupled with GC-TOF MSno
ProkaryotaLacticaseibacillus Paracaseimaize silageHS-SPME coupled with GC-TOF MSno
EukaryotaZygosaccharomyces RouxiiYPD mediumGC-MSno
ProkaryotaSerratia Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
EukaryotaAureobasidium PullulansYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaCryptococcus WieringaeYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaHanseniaspora UvarumYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaPichia KudriavzeviiYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaPichia FermentansYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaPichia MembranifaciensYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaSaccharomyces ParadoxusYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaTorulaspora DelbrueckiiYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaPichia AnomalaYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaMetschnikowia PulcherrimaYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
ProkaryotaStaphylococcus EquorumMOLPHS-SPME-GC/MSno
ProkaryotaStaphylococcus EquorumSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaStaphylococcus Equorumtryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaBacillus AtrophaeusMOLPHS-SPME-GC/MSno
ProkaryotaBacillus AtrophaeusSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaBacillus Atrophaeustryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaPeribacillus Sp.MOLPHS-SPME-GC/MSno
ProkaryotaPeribacillus Sp.Schaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaPeribacillus Sp.tryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaBacillus VelezensisMOLPHS-SPME-GC/MSno
ProkaryotaBacillus VelezensisSchaeffer’s growth (SG) mediumHS-SPME-GC/MSno
ProkaryotaBacillus Velezensistryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
EukaryotaWickerhamomyces Anomalusmedium consisted of glucose (20 g/l), peptone (5 g/l), agar (20 g/l) and amoxicillin (1 g/l)SPME with GC-MSno
EukaryotaWickerhamomyces Anomalussolid-state fermentation starter culture DaquSPME coupled with GC-MSno
ProkaryotaBacillus SubtilisTryptone soy broth (TSB)HPLCno
ProkaryotaAcetobacter Indonesiensissugared green and black teaHS-SPME-GC/MSno
EukaryotaLentinula EdodesJiuqu (traditional wheat Qu)GC-IMSno
ProkaryotaLactiplantibacillus Plantarumfermentation of ginkgo kernel juiceGC-IMSno
ProkaryotaLactobacillus PlantarumHabanero pepperGC–IMSno
ProkaryotaBacillus Thuringiensisbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
ProkaryotaBacillus Toyonensisbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
ProkaryotaBacillus Acidiproducensbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
ProkaryotaBacillus Cereusbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
ProkaryotaBacillus Safensisbacteriological agar (BA, 15 g/L), gelatin peptone (GP, 5 g/L), and meat extract (ME, 3 g/L)GC–MSno
ProkaryotaLactobacillus Plantarumtuna cooking liquidHS-SPME-GC/MSno
EukaryotaAspergillus Flavusinoculated potato samplesGC-MSno


Undec-1-ene

Mass-Spectra

Compound Details

Synonymous names
1-UNDECENE
821-95-4
Undec-1-ene
n-1-Undecene
1-Hendecene
Undecene
alpha-Undecene
alpha-Undecylene
alpha-Nonylethylene
Undecene-1
CCRIS 5720
HSDB 1090
.alpha.-Undecene
EINECS 212-483-7
NSC 73983
UNII-1446756A8F
NSC-73983
1446756A8F
DTXSID5061168
CHEBI:77444
MFCD00008956
Hendecene
68526-57-8
1-Undecene, 97%
N-NONYLETHYLENE
?1-UNDECENE
.ALPHA.-UNDECYLENE
1-UNDECENE [HSDB]
3,4-dichlorophenethylalcohol
.ALPHA.-NONYLETHYLENE
DTXCID0048268
NSC73983
EINECS 271-214-1
LMFA11000332
STL453737
AKOS009156849
MCULE-8437878932
LS-14020
DB-056580
NS00038169
U0025
U0052
D92764
EC 271-214-1
Q14745306
Microorganism:

Yes

IUPAC nameundec-1-ene
SMILESCCCCCCCCCC=C
InchiInChI=1S/C11H22/c1-3-5-7-9-11-10-8-6-4-2/h3H,1,4-11H2,2H3
FormulaC11H22
PubChem ID13190
Molweight154.29
LogP6.2
Atoms11
Bonds8
H-bond Acceptor0
H-bond Donor0
Chemical Classificationunsaturated hydrocarbons alkenes
CHEBI-ID77444
Supernatural-IDSN0062300

mVOC Specific Details

Boiling Point
DegreeReference
192.7 °C peer reviewed
Volatilization
The Henry's Law constant for 1-undecene is estimated as 1.48 atm-cu m/mole(SRC) using a fragment constant estimation method(1). This Henry's Law constant indicates that 1-undecene 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 1 hr(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 5 days(SRC). However, the volatilization half-life does not take into account the effects of adsorption. This is apparent from the results of two EXAMS model runs, one in which the effect of adsorption was considered, yielding an estimated half-life of 21 days in a model pond 2 m deep, and one in which the effect of adsorption was ignored, yielding an estimated half-life of 42 hrs in a model pond 2 m deep(3). 1-Undecene's Henry's Law constant(1) indicates that volatilization from moist soil surfaces may occur(SRC). 1-Undecene is not expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 0.493 mm Hg(4).
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) USEPA; EXAMS II Computer Simulation (1987) (4) Daubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals: Data Compilation. Design Inst Phys Prop Data, Amer Inst Chem Eng NY, NY: Hemisphere Pub Corp 5 Vol (1989)
Solubility
Sol in ether, chloroform, ligroin; insol in water
Literature: Lide, D.R. (ed.). CRC Handbook of Chemistry and Physics. 79th ed. Boca Raton, FL: CRC Press Inc., 1998-1999., p. 3-327
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc for 1-undecene can be estimated to be about 3180(SRC). According to a classification scheme(2), this estimated Koc value suggests that 1-undecene is expected to have slight mobility in soil.
Literature: (1) Meylan WM et al; Environ Sci Technol 26: 1560-67 (1992) (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
0.493 mm Hg @ 25 deg CDaubert, T.E., R.P. Danner. Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, D.C.: Taylor and Francis, 1989.
MS-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas AeruginosaNANAAhmed et al. 2023
ProkaryotaAcinetobacter BaumanniiNANAGao et al. 2016
ProkaryotaPseudomonas AeruginosaNANAFitzgerald et al. 2021
ProkaryotaPseudomonas AeruginosaNANAZechman et al. 1986
ProkaryotaPseudomonas AeruginosaNANANeerincx et al. 2016
ProkaryotaPseudomonas AeruginosaNANABoots et al. 2014
ProkaryotaPseudomonas AeruginosaNANALawal et al. 2018a
ProkaryotaPseudomonas AeruginosaNANANA
ProkaryotaPseudomonas PutidaNANANA
ProkaryotaPseudomonas FluorescensNANANA
ProkaryotaPseudomonas AeruginosaNANAFilipiak et al. 2012
ProkaryotaShewanella PutrefaciensNANANA
ProkaryotaStenotrophomonas MaltophiliaNANANA
ProkaryotaPseudomonas AeruginosaNANAJünger et al. 2012
ProkaryotaPseudomonas AeruginosaNALawal et al. 2018
EukaryotaPythium OligandrumN/APythium oligandrum GAQ1 strain was isolated from soil from a field where infected ginger was growing in Laiwu district, Jinan City, Shandong Province, China. China General Microbiological Culture Collection Center (CGMCC) deposit number No. 17470.Sheikh et al. 2023
ProkaryotaPseudomonas AeruginosaNATimm et al. 2018
ProkaryotaPseudomonas Fluorescensantibacterial activity against growth of Ralstonia solanacearumPlant Bacteriology Lab, Division of Plant Pathology, Indian Council of Agricultural Research - Indian Agricultural Research Institute, New DelhiKashyap et al. 2022
ProkaryotaPseudomonas Sp.antifungal activity against Thielaviopsis ethacetica mycelial growthBrazilian Biorenewables National Laboratory – LNBR/CNPEM Microorganism Collection, Campinas, SP; isolatedfrom soil and roots of highly productive sugarcane-producing regions; BrazilFreitas et al. 2022
ProkaryotaPseudomonas Aeruginosastimulate growth in Arabidopsis thaliana seedlings depending on inoculum concentrationavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaBacillus Sp.stimulate growth in Arabidopsis thaliana seedlings depending on inoculum concentrationavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaAneurinibacillus Aneurinilyticusstimulate growth in Arabidopsis thaliana seedlings depending on inoculum concentrationavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaPseudomonas Palleronianaavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaArthrobacter Nicotinovoransstimulate growth in Arabidopsis thaliana seedlings depending on inoculum concentrationavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaPantoea Vagansstimulate growth in Arabidopsis thaliana seedlings depending on inoculum concentrationavocado trees (Persea americana) rhizosphereGamboa-Becerra et al. 2022
ProkaryotaPseudomonas Azotoformansstimulate growth of Solanum tuberosumisolate from Irish potato soilsHeenan-Daly et al. 2021
ProkaryotaPseudomonas AeruginosaLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaBacillus Amyloliquefaciensn/aNALee et al. 2012
ProkaryotaBacillus Subtilisn/aNALee et al. 2012
ProkaryotaPaenibacillus Polymyxan/aNALee et al. 2012
ProkaryotaPseudomonas Sp.n/aNASchulz and Dickschat 2007
ProkaryotaShewanella Sp.n/aNASchulz and Dickschat 2007
ProkaryotaPseudomonas Fluorescensn/aNAFernando et al. 2005
ProkaryotaPseudomonas Corrugatan/aNAFernando et al. 2005
ProkaryotaPseudomonas Chlororaphisn/aNAFernando et al. 2005
ProkaryotaPseudomonas Aurantiacan/aNAFernando et al. 2005
EukaryotaTuber Mesentericumn/aFortywoodland of the Basilicata regionMauriello et al. 2004
ProkaryotaBurkholderia Andropogonisn/aNABlom et al. 2011
ProkaryotaBurkholderia Anthinan/aNABlom et al. 2011
ProkaryotaBurkholderia Caledonican/aNABlom et al. 2011
ProkaryotaBurkholderia Caribensisn/aNABlom et al. 2011
ProkaryotaBurkholderia Caryophyllin/aNABlom et al. 2011
ProkaryotaBurkholderia Cepacian/aNABlom et al. 2011
ProkaryotaBurkholderia Fungorumn/aNABlom et al. 2011
ProkaryotaBurkholderia Gladiolin/aNABlom et al. 2011
ProkaryotaBurkholderia Glathein/aNABlom et al. 2011
ProkaryotaBurkholderia Glumaen/aNABlom et al. 2011
ProkaryotaBurkholderia Graminisn/aNABlom et al. 2011
ProkaryotaBurkholderia Latan/aNABlom et al. 2011
ProkaryotaBurkholderia Phenaziniumn/aNABlom et al. 2011
ProkaryotaBurkholderia Phenoliruptrixn/aNABlom et al. 2011
ProkaryotaBurkholderia Phytofirmansn/aNABlom et al. 2011
ProkaryotaBurkholderia Pyrrocinian/aNABlom et al. 2011
ProkaryotaBurkholderia Saccharin/aNABlom et al. 2011
ProkaryotaBurkholderia Terricolan/aNABlom et al. 2011
ProkaryotaBurkholderia Thailandensisn/aNABlom et al. 2011
ProkaryotaCellulomonas Udan/aNABlom et al. 2011
ProkaryotaChromobacterium Violaceumn/aNABlom et al. 2011
ProkaryotaEscherichia Colin/aNABlom et al. 2011
ProkaryotaLimnobacter Thiooxidansn/aNABlom et al. 2011
ProkaryotaPseudomonas Aeruginosan/aNABlom et al. 2011
ProkaryotaPseudomonas Fluorescensn/aNABlom et al. 2011
ProkaryotaPseudomonas Putidan/aNABlom et al. 2011
ProkaryotaSerratia Plymuthican/aNABlom et al. 2011
ProkaryotaKlebsiella Pneumoniaen/aNAElgaali et al. 2002
ProkaryotaShewanella PutrefaciensAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaCitrobacter FreundiiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterobacter AerogenesAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterobacter CloacaeAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEscherichia ColiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaShigella SonneiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaAcinetobacter JohnsoniiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaPseudomonas FluorescensAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaLactobacillus LactisAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaStreptococcus ThermophilusAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaPseudomonas FluorescensNACheng et al. 2016
ProkaryotaPseudomonas PutidananaSchöller et al. 1997
ProkaryotaPseudomonas Fluorescensnasoil, water, plantsSchöller et al. 1997
ProkaryotaPseudomonas Aeruginosanasoil, water, skin floraSchöller et al. 1997
ProkaryotaPseudomonas TolaasiinanaLo Cantore et al. 2015
ProkaryotaPseudomonas Brassicacearumlyses red blood cellsrhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidalyses red blood cellsrhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Vranovensisinhibits the mycelial growth of P. infestans and changes its sporulation behaviorrhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Veroniiinhibits the mycelial growth of P. infestans and changes its sporulation behaviorrhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Chlororaphisinhibits the mycelial growth of P. infestans and changes its sporulation behaviorrhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Fluorescensinhibits the mycelial growth of P. infestans and changes its sporulation behaviorrhizosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas Frederiksbergensisinhibits the mycelial growth of P. infestans and changes its sporulation behaviorphyllosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas AeruginosananaBriard et al. 2016
ProkaryotaPseudomonas Chlororaphisinhibits nematode developmentRhizosphere of maize, Kiev region, UkrainePopova et al. 2014
ProkaryotaPseudomonas Putidanablack pepper rootSheoran et al. 2015
ProkaryotaPseudomonas Putidapositive influence of the plant root growth and protection against soil-borne pathogensNASheoran et al. 2015
ProkaryotaPseudomonas Aeruginosacan be used as biomarker for detection of this bacteriaNAYusuf et al. 2015
ProkaryotaBurkholderia CepaciaRhizosphereBlom et al. 2011
ProkaryotaPseudomonas Trivialisn/aNAKai et al. 2007
ProkaryotaPseudomonas Fluorescensn/aNAKai et al. 2007
ProkaryotaPseudomonas Fragin/aNAErcolini et al. 2009
ProkaryotaPseudomonas AeruginosaclinicPreti et al. 2009
ProkaryotaLentilactobacillus BuchneriNANASquara et al. 2022
EukaryotaSaccharomyces CerevisiaeNANAHarris et al. 2021
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas AeruginosaNBTD/GC-MSno
ProkaryotaAcinetobacter BaumanniiBacT/ALERT SASPME/GC-MSno
ProkaryotaPseudomonas AeruginosaTSBSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaBHISPME/GC-MSno
ProkaryotaPseudomonas AeruginosaLBSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaTSBTD/GC-MSno
ProkaryotaPseudomonas AeruginosaBrain Heart InfusionTD/GC-MSno
ProkaryotaPseudomonas AeruginosaMueller–HintonTD/GC-MSno
ProkaryotaPseudomonas AeruginosaASMTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas Putidatrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas Fluorescenstrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatryptic soy brothTD/GC-MSno
ProkaryotaShewanella Putrefacienstrypticase soy agarTD/GC-MSno
ProkaryotaStenotrophomonas Maltophiliatrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas AeruginosaColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaPseudomonas AeruginosaLevine EMB agar (LEA) (Fluka Analytical, UK)GC-MSno
EukaryotaPythium OligandrumV8 juice agarSPME/GC-MS/MSno
ProkaryotaPseudomonas AeruginosaMOPS glucoseSPME, GC-MSyes
ProkaryotaPseudomonas FluorescensLB agarGC-MSno
ProkaryotaPseudomonas Sp.LB media, DYGS media, ANGLE mediaHS-SPME/GC-MSyes
ProkaryotaPseudomonas AeruginosaLB mediaSPME/GC-MSno
ProkaryotaBacillus Sp.LB mediaSPME/GC-MSno
ProkaryotaAneurinibacillus AneurinilyticusLB mediaSPME/GC-MSno
ProkaryotaPseudomonas PalleronianaLB mediaSPME/GC-MSno
ProkaryotaArthrobacter NicotinovoransLB mediaSPME/GC-MSno
ProkaryotaPantoea VagansLB mediaSPME/GC-MSno
ProkaryotaPseudomonas AzotoformansTSB media, MR-VP (Methyl Red-Vogos Proskeur) media, M+S (Murashige and Skoog) mediaSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaTSB mediaHS-SPME/GC-MSno
ProkaryotaBacillus AmyloliquefaciensTryptic soy agarSPME coupled with GC-MSno
ProkaryotaBacillus SubtilisTryptic soy agarSPME coupled with GC-MSno
ProkaryotaPaenibacillus PolymyxaTryptic soy agarSPME coupled with GC-MSno
ProkaryotaPseudomonas Sp.n/an/ano
ProkaryotaShewanella Sp.n/an/ano
ProkaryotaPseudomonas Fluorescensn/an/ano
ProkaryotaPseudomonas Corrugatan/an/ano
ProkaryotaPseudomonas Chlororaphisn/an/ano
ProkaryotaPseudomonas Aurantiacan/an/ano
EukaryotaTuber Mesentericumn/amicroextraction-gas chromatography-mass spectrometry analysis (SPME-GC-MS)no
ProkaryotaBurkholderia AndropogonisLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia AnthinaLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CaledonicaAngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CaribensisAngle and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CaryophylliLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CepaciaAngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia FungorumLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GladioliLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GlatheiLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GlumaeLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GraminisMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia LataLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia LataMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhenaziniumLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhenoliruptrixLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhytofirmansLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PyrrociniaLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia SacchariLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia TerricolaLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia ThailandensisLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaCellulomonas UdaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaChromobacterium ViolaceumMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaEscherichia ColiLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaLimnobacter ThiooxidansLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas Aeruginosa LB, MR-VP, MS and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas FluorescensLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas PutidaLB, MS and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia PlymuthicaLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaKlebsiella PneumoniaeTS brothHS-SPME/GC-MS no
ProkaryotaShewanella PutrefaciensTS brothGC-MS Super Qno
ProkaryotaCitrobacter FreundiiTS brothGC-MS SPMEyes
ProkaryotaEnterobacter AerogenesTS brothGC-MS SPMEyes
ProkaryotaEnterobacter CloacaeTS brothGC-MS SPMEyes
ProkaryotaEscherichia ColiTS brothGC-MS SPMEyes
ProkaryotaShigella SonneiTS brothGC-MS SPMEyes
ProkaryotaAcinetobacter JohnsoniiTS brothGC-MS SPMEyes
ProkaryotaPseudomonas FluorescensTS brothGC-MS SPMEyes
ProkaryotaShewanella PutrefaciensTS brothGC-MS SPMEyes
ProkaryotaLactobacillus LactisTS brothGC-MS SPMEyes
ProkaryotaStreptococcus ThermophilusTS brothGC-MS SPMEyes
ProkaryotaPseudomonas FluorescensKings B + rif,+kann; PDA GC-Q-TOF-MSno
ProkaryotaPseudomonas PutidaAB medium + 1% citrate or 0,02% citrate or 1% glucose +1% casaminoacid GC-FID,GC/MSno
ProkaryotaPseudomonas FluorescensAB medium + 1% citrateGC-FID,GC/MSno
ProkaryotaPseudomonas AeruginosaAB medium + 1% citrateGC-FID,GC/MSno
ProkaryotaPseudomonas TolaasiiKBSPME-GCno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas VranovensisLB mediumGC/MSyes
ProkaryotaPseudomonas VeroniiLB mediumGC/MSyes
ProkaryotaPseudomonas ChlororaphisLB mediumGC/MSyes
ProkaryotaPseudomonas FluorescensLB mediumGC/MSyes
ProkaryotaPseudomonas FrederiksbergensisLB mediumGC/MSyes
ProkaryotaPseudomonas Aeruginosaminimal medium/ Brian mediumSPME-GC/MSno
ProkaryotaPseudomonas ChlororaphisLB mediumSPME-GC/MSno
ProkaryotaPseudomonas PutidaLuria Bertani AgarHeadspace GC/MSno
ProkaryotaPseudomonas PutidaTSBPropak Q adsorbent trap/GC-MSno
ProkaryotaPseudomonas Aeruginosablood agar base (TSBA)SPME/GC-MS no
ProkaryotaBurkholderia CepaciaAngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)yes
ProkaryotaPseudomonas Trivialisn/an/ano
ProkaryotaPseudomonas Fragin/an/ano
ProkaryotaPseudomonas AeruginosaBlood agar/chocolate blood agaHS-SPME/GC-MS no
ProkaryotaLentilactobacillus Buchnerimaize silageHS-SPME coupled with GC-TOF MSno
EukaryotaSaccharomyces Cerevisiaemalt extract brothHS-SPME with GC-MSno


Heptadecane

Mass-Spectra

Compound Details

Synonymous names
HEPTADECANE
n-Heptadecane
629-78-7
Heptadekan
n-Heptadecane (d36)
H7C0J39XUM
DTXSID7047061
CHEBI:16148
MFCD00009002
NSC-172782
Hexadecane, methyl-
Heptadecane, analytical standard
EINECS 211-108-4
UNII-H7C0J39XUM
NSC 172782
BRN 1738898
AI3-36898
Heptadecane purum
Normal-heptadecane
PJ8
Heptadecane, 99%
Analytical Reagent,95.0%
4-01-00-00548 (Beilstein Handbook Reference)
CHEMBL3185332
DTXCID5027061
Samarium(III)ChlorideHexahydrate
HSDB 8347
CH3-[CH2]15-CH3
Tox21_302278
LMFA11000003
NSC172782
STL355860
AKOS000487450
MCULE-3718944215
Heptadecane, purum, >=98.0% (GC)
NCGC00256101-01
AS-56326
CAS-629-78-7
DB-054356
CS-0197341
H0023
NS00012511
C01816
D97702
Heptadecane; NSC 172782; TS 7; n-Heptadecane
Q150888
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
Microorganism:

Yes

IUPAC nameheptadecane
SMILESCCCCCCCCCCCCCCCCC
InchiInChI=1S/C17H36/c1-3-5-7-9-11-13-15-17-16-14-12-10-8-6-4-2/h3-17H2,1-2H3
FormulaC17H36
PubChem ID12398
Molweight240.5
LogP8.8
Atoms17
Bonds14
H-bond Acceptor0
H-bond Donor0
Chemical Classificationsaturated hydrocarbons alkanes
CHEBI-ID16148
Supernatural-IDSN0242409

mVOC Specific Details

Boiling Point
DegreeReference
303 °C peer reviewed
Volatilization
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)
Solubility
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
Soil Adsorption
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)
Vapor Pressure
PressureReference
2.28X10-4 mm Hg at 25 deg CDaubert TE, Danner RP; Physical and Thermodynamic Properties of Pure Chemicals Data Compilation. Washington, DC: Taylor and Francis (1989)
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
EukaryotaAspergillus NigerNANACosta et al. 2016
EukaryotaCandida AlbicansNANACosta et al. 2016
EukaryotaPenicillium ChrysogenumNANACosta et al. 2016
ProkaryotaPseudomonas FluorescensPlant growth promotion and ISRrhizosphereJishma et al. 2017
ProkaryotaPseudomonas FluorescensPlant growth promotionrhizosphereJishma et al. 2017
ProkaryotaPseudomonas PutidaPlant growth promotion and ISRrhizosphereJishma et al. 2017
ProkaryotaPseudomonas RhodesiaePlant growth promotion and ISRrhizosphereJishma et al. 2017
ProkaryotaPseudomonas RhodesiaePlant growth promotionrhizosphereJishma et al. 2017
ProkaryotaPseudomonas TaiwanensisPlant growth promotionrhizosphereJishma et al. 2017
ProkaryotaStaphylococcus AureusNAKarami et al. 2017
EukaryotaFusarium CulmorumNASchmidt et al. 2018
EukaryotaAspergillus FlavusITEM collection of CNR-ISPA (Research National Council of Italy - Institute of Sciences of Food Production) in Bari, ItalyJosselin et al. 2021
EukaryotaCandida AlbicansATCC MYA-2876, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida GlabrataATCC 90030, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida TropicalisATCC 750, American Type Culture CollectionCosta et al. 2020
ProkaryotaErwinia Amylovoraenhances Arabidopsis thaliana shoot and root growthbacterial collection of the LabParmagnani et al. 2023
ProkaryotaCyanobacteria Sp.n/aNASchulz and Dickschat 2007
ProkaryotaCalothrix Parietinan/aNAHoeckelmann et al. 2004
ProkaryotaCalothrix Sp.n/aNAHoeckelmann et al. 2004
ProkaryotaPlectonema Notatumn/aNAHoeckelmann et al. 2004
ProkaryotaPlectonema Sp.n/aNAHoeckelmann et al. 2004
ProkaryotaPhormidium Sp.n/aNAHoeckelmann et al. 2004
ProkaryotaTolypothrix Distortan/aNAHoeckelmann et al. 2004
ProkaryotaRivularia Sp.n/aNAHoeckelmann et al. 2004
ProkaryotaBacillus Megateriumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidanarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Simiaenarhizosphere of a soybean field in the province of Rajasthan, IndiaVaishnav et al. 2016
ProkaryotaPseudomonas Putidanablack pepper rootSheoran et al. 2015
ProkaryotaEnterobacter Sp.NANAEtminani et al. 2022
ProkaryotaPantoea Sp.NANAEtminani et al. 2022
ProkaryotaPseudomonas Sp.NANAEtminani et al. 2022
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
EukaryotaAspergillus NigerYeast Glucose ChloramphenicolSPME/GCxGC-MSno
EukaryotaCandida AlbicansYeast Glucose ChloramphenicolSPME/GCxGC-MSno
EukaryotaPenicillium ChrysogenumYeast Glucose ChloramphenicolSPME/GCxGC-MSno
ProkaryotaPseudomonas FluorescensNBGS-MSno
ProkaryotaPseudomonas FluorescensMR-VP brothGS-MSno
ProkaryotaPseudomonas PutidaNBGS-MSno
ProkaryotaPseudomonas RhodesiaeNBGS-MSno
ProkaryotaPseudomonas RhodesiaeMR-VP brothGS-MSno
ProkaryotaPseudomonas TaiwanensisMR-VP brothGS-MSno
ProkaryotaStaphylococcus AureusMueller Hinton broth (MB), tryptic soy broth (TSB)SPME, DVB/CAR/PDMS, GC-MSno
EukaryotaFusarium CulmorumKing`s B agarUPLC-MSno
EukaryotaAspergillus FlavusSNA mediaSPME/GC-MSno
EukaryotaCandida AlbicansYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida GlabrataYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida TropicalisYGC mediaHS-SPME/GC-GC-ToFMSno
ProkaryotaErwinia AmylovoraSBSE/GC-MSno
ProkaryotaCyanobacteria Sp.n/an/ano
ProkaryotaCalothrix Parietinan/an/ano
ProkaryotaCalothrix Sp.n/an/ano
ProkaryotaPlectonema Notatumn/an/ano
ProkaryotaPlectonema Sp.n/an/ano
ProkaryotaPhormidium Sp.n/an/ano
ProkaryotaTolypothrix Distortan/an/ano
ProkaryotaRivularia Sp.n/an/ano
ProkaryotaBacillus MegateriumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas SimiaeNutrient broth; King's B agarGC/MSno
ProkaryotaPseudomonas PutidaLuria Bertani AgarSolvent extraction with dichloro methane, GC/MSno
ProkaryotaEnterobacter Sp.nutrient agar (NA)GC–MSno
ProkaryotaPantoea Sp.nutrient agar (NA)GC–MSno
ProkaryotaPseudomonas Sp.nutrient agar (NA)GC–MSno


Octadecane

Mass-Spectra

Compound Details

Synonymous names
OCTADECANE
n-Octadecane
593-45-3
Octadecan
Oktadekan
UNII-N102P6HAIU
N102P6HAIU
CCRIS 681
1-(4-Chlorophenyl)-1,3-dihydro-2H-indol-2-one
TS Paraffin TS 8
NSC 4201
NSC-4201
EINECS 209-790-3
128271-18-1
AI3-06523
DTXSID9047172
CHEBI:32926
HSDB 8348
EC 209-790-3
CACTUS NORMAL PARAFFIN TS 8
Octadecane, 99%
MFCD00009007
Octadecane, analytical standard
CH3-(CH2)16-CH3
CH3-[CH2]16-CH3
Octadecane, n-
OCTADECANE [INCI]
DTXCID7027172
NSC4201
HY-N6600
LMFA11000581
AKOS015903064
MCULE-2392852814
Octadecane, purum, >=97.0% (GC)
AS-56224
CS-0034329
NS00010781
O0003
Q150900
379E5588-B955-4C35-88E0-21E7DF38DE0E
InChI=1/C18H38/c1-3-5-7-9-11-13-15-17-18-16-14-12-10-8-6-4-2/h3-18H2,1-2H
Microorganism:

Yes

IUPAC nameoctadecane
SMILESCCCCCCCCCCCCCCCCCC
InchiInChI=1S/C18H38/c1-3-5-7-9-11-13-15-17-18-16-14-12-10-8-6-4-2/h3-18H2,1-2H3
FormulaC18H38
PubChem ID11635
Molweight254.5
LogP9.3
Atoms18
Bonds15
H-bond Acceptor0
H-bond Donor0
Chemical Classificationsaturated hydrocarbons alkanes
CHEBI-ID32926
Supernatural-IDSN0339363

mVOC Specific Details

Boiling Point
DegreeReference
316 °C peer reviewed
Volatilization
The Henry's Law constant for octadecane is estimated as 1.9X10-2 atm-cu m/mole(1) from its vapor pressure, 3.41X10-4 mm Hg(2), and water solubility, 6.0X10-3 mg/L(3). This Henry's Law constant indicates that octadecane is expected to volatilize rapidly from water surfaces(4). 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)(1) is estimated as 1.7 hours 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)(1) is estimated as 6.3 days(SRC). However, adsorption to suspended solids and sediment is expected to attenuate volatilization(SRC). The estimated volatilization half-life from a model pond is greater than 2 years if adsorption is considered(5). Octadecane has a vapor pressure of 3.41X10-4 mm Hg and exists as a liquid under environmental conditions; therefore, octadecane may volatilize from dry soil.
Literature: (1) US EPA; Estimation Program Interface (EPI) Suite. Ver. 4.1. Nov, 2012. Available from, as of Nov 9, 2016: http://www2.epa.gov/tsca-screening-tools (2) Jensen TS; PhD Thesis: Petroleum hydrocarbons: compositional changes during biodegradation and transport in unsaturated soil. Roskilde, Denmark: Ministry of the Environment and Energy, National Environmental Research (1994) (3) Yalkowsky SH, et al; Handbook of Aqueous Solubility Data. 2nd ed., Boca Raton, FL: CRC Press p. 1184 (2010) (4) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (5) US EPA; EXAMS II Computer Simulation (1987)
Soil Adsorption
The Koc of octadecane is 2.2X10+7(1). According to a classification scheme(2), this Koc value suggests that octadecane is expected to be immobile in soil.
Literature: (1) Jensen TS; PhD Thesis: Petroleum hydrocarbons: compositional changes during biodegradation and transport in unsaturated soil. Roskilde, Denmark: Ministry of the Environment and Energy, National Environmental Research (1994) (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
3.41X10-4 mm Hg at 25 deg CPerry RH, Green D; Perry's Chemical Handbook. Physical and Chemical Data. 6th ed., New York, NY: McGraw Hill (1984)
MS-Links
1D-NMR-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaEscherichia ColiNANADixon et al. 2022
ProkaryotaPseudomonas RhodesiaePlant growth promotion and ISRrhizosphereJishma et al. 2017
EukaryotaFusarium CulmorumNASchmidt et al. 2018
ProkaryotaBacillus Sp.antifungal activity against Fusarium solaniRhizosphere soil of avocadoGuevara-Avendaño et al. 2019
ProkaryotaStreptomyces Philanthiantifungal activity against Aspergillus parasiticus TISTR 3276 and Aspergillus flavus PSRDC-4NABoukaew and Prasertsan 2020
ProkaryotaStreptococcus Mutans as a biomarker for a breath test for detection of cariesNAHertel et al. 2016
ProkaryotaAzospirillum Brasilensepromotion of performance of Chlorella sorokiniana Shihculture collection DSMZ 1843Amavizca et al. 2017
ProkaryotaBacillus Pumiluspromotion of performance of Chlorella sorokiniana ShihNAAmavizca et al. 2017
ProkaryotaEscherichia Colipromotion of performance of Chlorella sorokiniana ShihNAAmavizca et al. 2017
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaSerratia Sp.NANAEtminani et al. 2022
ProkaryotaEnterobacter Sp.NANAEtminani et al. 2022
ProkaryotaPantoea Sp.NANAEtminani et al. 2022
ProkaryotaPseudomonas Sp.NANAEtminani et al. 2022
ProkaryotaAchromobacter Sp.NANAAlmeida et al. 2022
ProkaryotaBacillus SubtilisNANALee et al. 2023
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaEscherichia ColiLBTD/GC-MSno
ProkaryotaPseudomonas RhodesiaeNBGS-MSno
EukaryotaFusarium CulmorumKing`s B agarUPLC-MSno
ProkaryotaBacillus Sp.LB agarSPME-GC-MSno
ProkaryotaStreptomyces Philanthisterile wheat seedsGC-MSno
ProkaryotaStreptococcus MutansBrain-Heart-Infusion agarTenax-trap/GC-MSno
ProkaryotaAzospirillum BrasilenseTSASPME-GCno
ProkaryotaBacillus PumilusTSASPME-GCno
ProkaryotaEscherichia ColiTSASPME-GCno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaSerratia Sp.nutrient agar (NA)GC–MSno
ProkaryotaEnterobacter Sp.nutrient agar (NA)GC–MSno
ProkaryotaPantoea Sp.nutrient agar (NA)GC–MSno
ProkaryotaPseudomonas Sp.nutrient agar (NA)GC–MSno
ProkaryotaAchromobacter Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaBacillus SubtilisTryptone soy broth (TSB)HPLCno


[(Z)-dec-3-enyl] Acetate

Compound Details

Synonymous names
81634-99-3
3Z-Decenyl acetate
3-Decen-1-ol, acetate, (3Z)-
[(Z)-dec-3-enyl] acetate
(Z)-3-Decenyl acetate
(Z)-Dec-3-en-1-yl acetate
Z-3-Decen-1-yl acetate
3-Decen-1-ol, 1-acetate, (3Z)-
(Z)-3-Decen-1-olacetate
EINECS 279-789-0
cis-3-Decenyl acetate
(3Z)-Decenyl Acetate
(3Z)-3-Decenyl acetate
SCHEMBL1301438
CHEBI:179183
3-Decen-1-ol, acetate, (Z)-
DTXSID101015320
LMFA07010206
AKOS006272401
3Z-Decenyl acetate CAS 81634-99-3
NS00060305
G71307
Microorganism:

Yes

IUPAC name[(Z)-dec-3-enyl] acetate
SMILESCCCCCCC=CCCOC(=O)C
InchiInChI=1S/C12H22O2/c1-3-4-5-6-7-8-9-10-11-14-12(2)13/h8-9H,3-7,10-11H2,1-2H3/b9-8-
FormulaC12H22O2
PubChem ID5363204
Molweight198.3
LogP4.1
Atoms14
Bonds9
H-bond Acceptor2
H-bond Donor0
Chemical Classificationesters
CHEBI-ID179183

mVOC Specific Details


Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaPseudomonas Sp.antifungal activity against Thielaviopsis ethacetica mycelial growthBrazilian Biorenewables National Laboratory – LNBR/CNPEM Microorganism Collection, Campinas, SP; isolatedfrom soil and roots of highly productive sugarcane-producing regions; BrazilFreitas et al. 2022
ProkaryotaPseudomonas Brassicacearumnarhizosphere of bean plants, southern ItalyGiorgio et al. 2015
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaPseudomonas Sp.LB media, DYGS mediaHS-SPME/GC-MSno
ProkaryotaPseudomonas Sp.LB mediaHS-SPME/GC-MSno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno


Undecan-2-one

Mass-Spectra

Compound Details

Synonymous names
2-Undecanone
Undecan-2-one
Methyl nonyl ketone
112-12-9
UNDECANONE
2-Hendecanone
Methylnonylketone
Rue ketone
Ketone, methyl nonyl
Nonyl methyl ketone
METHYL N-NONYL KETONE
2-Oxoundecane
MGK Dog and Cat Repellent
FEMA No. 3093
Undecanone-(2)
Mgk dog & cat repellent
MFCD00009583
YV5DSO8CY9
53452-70-3
DTXSID2021943
CHEBI:17700
NSC4028
NSC-4028
Caswell No. 573O
2-Undecanone (natural)
BioUD
HSDB 7431
NSC 4028
EINECS 203-937-5
UNII-YV5DSO8CY9
EPA Pesticide Chemical Code 044102
BRN 1749573
Luparone
Enodyl
AI3-03081
methyl n-nonylketone
Methyl-n-nonylketone
MGK dog AMP MNK
2-Undecanone, 99%
2-Methylundecanone,(S)
UNDECANONE, 2-
MOSTIQUE EGX 101
2-UNDECANONE [FCC]
2-UNDECANONE [FHFI]
2-UNDECANONE [HSDB]
SCHEMBL117635
SCHEMBL249443
DTXCID301943
WLN: 9V1
CHEMBL1236582
FEMA 3093
METHYL NONYL KETONE [MI]
2-Undecanone, analytical standard
2-Undecanone, natural, FCC, FG
Tox21_301385
BBL011441
LMFA12000002
s3762
STL146552
2-Undecanone, >=98%, FCC, FG
AKOS005720838
CCG-266363
CS-W017685
DB08688
HY-W016969
MCULE-6858373499
NCGC00164003-01
NCGC00255160-01
CAS-112-12-9
VS-02950
DB-309480
NS00008362
U0006
C01875
EN300-170519
F17694
A802493
Q-201393
Q2024187
Z406376986
Microorganism:

Yes

IUPAC nameundecan-2-one
SMILESCCCCCCCCCC(=O)C
InchiInChI=1S/C11H22O/c1-3-4-5-6-7-8-9-10-11(2)12/h3-10H2,1-2H3
FormulaC11H22O
PubChem ID8163
Molweight170.29
LogP4.1
Atoms12
Bonds8
H-bond Acceptor1
H-bond Donor0
Chemical Classificationketones
CHEBI-ID17700
Supernatural-IDSN0199126

mVOC Specific Details

Boiling Point
DegreeReference
231.5 deg CLide, D.R., G.W.A. Milne (eds.). Handbook of Data on Organic Compounds. Volume I. 3rd ed. CRC Press, Inc. Boca Raton ,FL. 1994., p. V5: 5176
Volatilization
The Henry's Law constant for 2-undecanone is 6.36X10-5 atm-cu m/mole(1). This Henry's Law constant indicates that 2-undecanone 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 13 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 11 days(SRC). 2-Undecanone's Henry's Law constant indicates that volatilization from moist soil surfaces may occur(SRC). 2-Undecanone is not expected to volatilize from dry soil surfaces(SRC) based upon a vapor pressure of 4.1X10-2 mm Hg(3).
Literature: (1) Buttery RG et al: J Agric Food Chem 17:385-9 (1960) (2) Lyman WJ et al; Handbook of Chemical Property Estimation Methods. Washington, DC: Amer Chem Soc pp. 15-1 to 15-29 (1990) (3) Perry RH, Green D; Perry's Chemical Handbook. Physical and Chemical data. NY,NY: McGraw-Hill 6th ed (1984)
Solubility
Insoluble in water. Soluble in ethanol, ether, acetone, benzene, carbon tetrachloride, chloroform.
Literature: Lide, D.R., G.W.A. Milne (eds.). Handbook of Data on Organic Compounds. Volume I. 3rd ed. CRC Press, Inc. Boca Raton ,FL. 1994., p. V5: 5176
Literature: #In water, 20 mg/L at 25 deg C (est)
Literature: US EPA; Estimation Program Interface (EPI) Suite. Ver.3.12. Nov 30, 2004. Available from, as of Mar 3, 2006: http://www.epa.gov/oppt/exposure/pubs/episuitedl.htm
Soil Adsorption
Using a structure estimation method based on molecular connectivity indices(1), the Koc of 2-undecanone can be estimated to be 278(SRC). According to a classification scheme(2), this estimated Koc value suggests that 2-undecanone is expected to have moderate mobility in soil.
Literature: (1) Meylan WM et al; Environ Sci Technol 26: 1560-67 (1992) (2) Swann RL et al; Res Rev 85: 17-28 (1983)
Vapor Pressure
PressureReference
4.1X10-2 mm HgPerry RH, Green D; Perry's Chemical Handbook. Physical and Chemical data. NY, NY: McGraw-Hill 6th ed (1984)
MS-Links
Massbank-Links

Species emitting the compound
KingdomSpeciesBiological FunctionOrigin/HabitatReference
ProkaryotaEscherichia ColiNANAFitzgerald et al. 2021
ProkaryotaPseudomonas AeruginosaNANAFitzgerald et al. 2021
ProkaryotaPseudomonas AeruginosaNANABean et al. 2012
EukaryotaAspergillus FumigatusNANANeerincx et al. 2016
ProkaryotaKlebsiella PneumoniaeNANAZechman et al. 1986
ProkaryotaPseudomonas AeruginosaNANAZechman et al. 1986
ProkaryotaPseudomonas AeruginosaNANANA
ProkaryotaPseudomonas PutidaNANANA
ProkaryotaStenotrophomonas MaltophiliaNANANA
ProkaryotaEscherichia ColiNANAJünger et al. 2012
ProkaryotaProteus MirabilisNANAJünger et al. 2012
ProkaryotaSerratia MarcescensNANAJünger et al. 2012
ProkaryotaStreptococcus AgalactiaeNANAJünger et al. 2012
EukaryotaPythium OligandrumStrong inhibition of growth of plant pathogen Pythium myriotylum;Pythium oligandrum GAQ1 strain was isolated from soil from a field where infected ginger was growing in Laiwu district, Jinan City, Shandong Province, China. China General Microbiological Culture Collection Center (CGMCC) deposit number No. 17470.Sheikh et al. 2023
ProkaryotaCorynebacterium Accolensclinical isolateLemfack et al. 2016
ProkaryotaCorynebacterium Jeikeiumclinical isolateLemfack et al. 2016
ProkaryotaCorynebacterium Minutissimumclinical isolate,trunk of adult femaleLemfack et al. 2016
ProkaryotaCorynebacterium Striatumclinical isolateLemfack et al. 2016
ProkaryotaStaphylococcus EpidermidisNALemfack et al. 2016
ProkaryotaStaphylococcus Epidermidisclinical isolate,noseLemfack et al. 2016
ProkaryotaStaphylococcus Epidermidisclinical isolate,catheterLemfack et al. 2016
ProkaryotaStaphylococcus Haemolyticusclinical isolate,human skinLemfack et al. 2016
ProkaryotaStaphylococcus Saccharolyticusclinical isolateLemfack et al. 2016
ProkaryotaStaphylococcus Schleifericlinical isolateLemfack et al. 2016
ProkaryotaStaphylococcus Warnericlinical isolate,human skinLemfack et al. 2016
ProkaryotaEscherichia ColiChina Center of Industrial culture Collection, China General Microbiological Culture Collection CenterChen et al. 2017
ProkaryotaSalmonella EntericaChina Center of Industrial culture Collection, China General Microbiological Culture Collection CenterChen et al. 2017
ProkaryotaShigella FlexneriChina Center of Industrial culture Collection, China General Microbiological Culture Collection CenterChen et al. 2017
ProkaryotaBacillus Sp.KX395632.1Fincheira et al. 2017
ProkaryotaPseudomonas AeruginosaNATimm et al. 2018
ProkaryotaShigella SonneiChina Center of Industrial Culture collectionWang et al. 2018
ProkaryotaStaphylococcus AureusChina Center of Industrial Culture collectionWang et al. 2018
ProkaryotaVibrio ParahaemolyticusChina Center of Industrial Culture collectionWang et al. 2018
ProkaryotaBacillus Velezensistoxic effects on fungal mycelial growthmaize seedMassawe et al. 2018
ProkaryotaBacillus Sp.antifungal activity against Fusarium solaniRhizosphere soil of avocadoGuevara-Avendaño et al. 2019
ProkaryotaBacillus AmyloliquefaciensInhibition of fusarium oxysporum f.sp. Niveumrhizosphere soils of watermelon plantsWu et al. 2019
ProkaryotaPseudomonas Sp.antifungal activity against Thielaviopsis ethacetica mycelial growthBrazilian Biorenewables National Laboratory – LNBR/CNPEM Microorganism Collection, Campinas, SP; isolatedfrom soil and roots of highly productive sugarcane-producing regions; BrazilFreitas et al. 2022
ProkaryotaSerratia Fonticolastimulate growth of Solanum tuberosumisolate from Irish potato soilsHeenan-Daly et al. 2021
ProkaryotaStreptomyces Salmoniscontrol of postharvest anthracnose disease of chili caused by Colletotrichum gloeosporioides PSU-03Phitsanulok Seed Research and Development Center, Department of Agriculture, Ministry of Agriculture and Cooperatives, ThailanBoukaew et al. 2021
EukaryotaCandida AlbicansATCC MYA-2876, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida GlabrataATCC 90030, American Type Culture CollectionCosta et al. 2020
EukaryotaCandida TropicalisATCC 750, American Type Culture CollectionCosta et al. 2020
ProkaryotaPseudomonas AeruginosaLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaEscherichia ColiLeibnitz Institute DSMZ-German Collection of Microorganisms and Cell Cultures GmbHFitzgerald et al. 2020
ProkaryotaStenotrophomonas Maltophiliaantifungal effect on the growth of Alternaria alternata, Corynespora cassiicola and Stemphylium lycopersici (pathogens of tomato plants)shoots of tomato plants (Elpida F1, Enza Zaden)López et al. 2021
ProkaryotaMicrobacterium Paraoxydansantifungal effect on the growth of Alternaria alternata, Corynespora cassiicola and Stemphylium lycopersici (pathogens of tomato plants)leaves of tomato plants (Elpida F1, Enza Zaden) with symptoms of Gray leaf spotLópez et al. 2021
ProkaryotaPseudomonas Mediterraneaantifungal effect on the growth of Alternaria alternata, Corynespora cassiicola and Stemphylium lycopersici (pathogens of tomato plants)roots of tomato plants (Elpida F1, Enza Zaden) with symptoms of Gray leaf spotLópez et al. 2021
ProkaryotaBacillus Sp.antifungal effect on the growth of Alternaria alternata, Corynespora cassiicola and Stemphylium lycopersici (pathogens of tomato plants)NALópez et al. 2021
ProkaryotaBacillus Velezensisinhibite the growth of Botrytis cinerea VG1, Monilinia fructicola VG 104, Monilinia laxa VG 105, Penicillium digitatum VG 20, Penicillium expansum CECT 20140, Penicillium italicum VG 114NACalvo et al. 2020
ProkaryotaRahnella Aquatilisisolate from the rhizosphere soil of a 28-year-old Pinus massoniana in Nanning, Guangxi; stored in the typical Culture Preservation Center of ChinaKong et al. 2020
EukaryotaTrichoderma Asperellumreduce downy mildew severity on Vitis vinifera (grapevine plants)Cotxarrera et al., 2002Lazazzara et al. 2021
EukaryotaTrichoderma Atroviridereduce downy mildew severity on Vitis vinifera (grapevine plants)Pertot et al., 2008Lazazzara et al. 2021
EukaryotaTrichoderma Harzianumreduce downy mildew severity on Vitis vinifera (grapevine plants)Eladet al., 1997Lazazzara et al. 2021
ProkaryotaStaphylococcus AureusAmerican Type Culture CollectionJenkins and Bean 2020
ProkaryotaBacillus VelezensisNARiu et al. 2022
ProkaryotaEscherichia ColiSwedish Institute for Communicable Disease Control (SMI), Stockholm, SwedenSousa et al. 2023
ProkaryotaBurkholderia Pyrrociniapromote aerial and root growth in Arabidopsis thaliana seedlingsRhizosphere soil samples from roots of maize (Zea mays L.) grown in Gongju, South KoreaLuo et al. 2022
ProkaryotaSerratia Plymuthican/aNAWeise et al. 2014
ProkaryotaSerratia Proteamaculansn/aNAWeise et al. 2014
ProkaryotaPseudomonas Fluorescensn/aNAFernando et al. 2005
ProkaryotaPseudomonas Corrugatan/aNAFernando et al. 2005
ProkaryotaPseudomonas Chlororaphisn/aNAFernando et al. 2005
ProkaryotaPseudomonas Aurantiacan/aNAFernando et al. 2005
ProkaryotaBacillus SimplexReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaBacillus SubtilisReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaBacillus WeihenstephanensisReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaMicrobacterium OxydansReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaStenotrophomonas MaltophiliaReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaStreptomyces LateritiusReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaSerratia MarcescensReduction of movement or death of Panagrelleus redivivus and Bursaphelenchus xylophilus.NAGu et al. 2007
ProkaryotaSerratia Sp.n/aNABruce et al. 2004
ProkaryotaSerratia Odoriferan/aNAWeise et al. 2014
ProkaryotaSerratia Marcescensn/aNAWeise et al. 2014
EukaryotaTuber Aestivumn/aAgricultural Centre of Castilla and León Community (Monasterio de la Santa Espina, Valladolid, Spain) and Navaleno (Soria, Spain).Diaz et al. 2003
EukaryotaTuber Melanosporumn/aAgricultural Centre of Castilla and León Community (Monasterio de la Santa Espina, Valladolid, Spain) and Navaleno (Soria, Spain).Diaz et al. 2003
ProkaryotaBurkholderia Ambifarian/aBurkholderia ambifaria LMG 17828 from root, LMG 19182 from rhizosphereGroenhagen et al. 2013
ProkaryotaBurkholderia Andropogonisn/aNABlom et al. 2011
ProkaryotaBurkholderia Caribensisn/aNABlom et al. 2011
ProkaryotaBurkholderia Caryophyllin/aNABlom et al. 2011
ProkaryotaBurkholderia Cepacian/aNABlom et al. 2011
ProkaryotaBurkholderia Fungorumn/aNABlom et al. 2011
ProkaryotaBurkholderia Gladiolin/aNABlom et al. 2011
ProkaryotaBurkholderia Glathein/aNABlom et al. 2011
ProkaryotaBurkholderia Glumaen/aNABlom et al. 2011
ProkaryotaBurkholderia Graminisn/aNABlom et al. 2011
ProkaryotaBurkholderia Hospitan/aNABlom et al. 2011
ProkaryotaBurkholderia Latan/aNABlom et al. 2011
ProkaryotaBurkholderia Phenaziniumn/aNABlom et al. 2011
ProkaryotaBurkholderia Phenoliruptrixn/aNABlom et al. 2011
ProkaryotaBurkholderia Phytofirmansn/aNABlom et al. 2011
ProkaryotaBurkholderia Pyrrocinian/aNABlom et al. 2011
ProkaryotaBurkholderia Terricolan/aNABlom et al. 2011
ProkaryotaBurkholderia Tropican/aNABlom et al. 2011
ProkaryotaBurkholderia Xenovoransn/aNABlom et al. 2011
ProkaryotaChromobacterium Violaceumn/aNABlom et al. 2011
ProkaryotaEscherichia Colin/aNABlom et al. 2011
ProkaryotaPandoraea Norimbergensisn/aNABlom et al. 2011
ProkaryotaPseudomonas Fluorescensn/aNABlom et al. 2011
ProkaryotaPseudomonas Putidan/aNABlom et al. 2011
ProkaryotaSerratia Entomophilan/aNABlom et al. 2011
ProkaryotaSerratia Marcescensn/aNABlom et al. 2011
ProkaryotaSerratia Plymuthican/aNABlom et al. 2011
ProkaryotaSerratia Proteamaculansn/aNABlom et al. 2011
ProkaryotaStenotrophomonas Rhizophilan/aNABlom et al. 2011
ProkaryotaEscherichia Colin/aNAElgaali et al. 2002
ProkaryotaKlebsiella Pneumoniaen/aNAElgaali et al. 2002
EukaryotaTrichoderma Atroviriden/aNAStoppacher et al. 2010
ProkaryotaShigella SonneiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaCitrobacter FreundiiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterobacter AerogenesAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterobacter CloacaeAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEscherichia ColiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaSalmonella ParatyphiAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaPseudomonas FluorescensAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaShewanella PutrefaciensAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaBacillus CereusAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaBacillus PolymyxaAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterococcus DuransAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaEnterococcus FaeciumAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaLactobacillus LactisAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaLeuconostoc MesenteroidesAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaListeria MonocytogenesAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaStreptococcus AgalactiaeAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
ProkaryotaStreptococcus ThermophilusAmerican Type Culture Collection (ATCC), Rockville, MD or wild strains identified at the University of Kentucky Dept. of Animal Sciences Food Microbiology LaboratoryElgaali et al. 2002
EukaryotaTrichoderma VirensNACrutcher et al. 2013
EukaryotaTrichoderma ReeseiNACrutcher et al. 2013
EukaryotaFusarium SolaniNATakeuchi et al. 2012
EukaryotaAspergillus Sp.NATakeuchi et al. 2012
EukaryotaPenicillium Sp.NATakeuchi et al. 2012
ProkaryotaPseudomonas TolaasiinanaLo Cantore et al. 2015
ProkaryotaPseudomonas Brassicacearumreduces mycelium growth and sclerotia germination of Sclerotinia sclerotiorum USB-F593; lyses red blood cellsrhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaPseudomonas Putidareduces mycelium growth and sclerotia germination of Sclerotinia sclerotiorum USB-F593; lyses red blood cellsrhizosphere of bean plants, southern ItalyGiorgio et al. 2015
ProkaryotaBacillus Subtilistriggers induced systemic resistance (ISR) in ArabidopsisnaRyu et al. 2004
ProkaryotaBacillus Amyloliquefacienstriggers induced systemic resistance (ISR) in ArabidopsisnaRyu et al. 2004
ProkaryotaPseudomonas Jesseniinaphyllosphere of field-grown potato plantsHunziker et al. 2015
ProkaryotaPseudomonas AeruginosananaBriard et al. 2016
ProkaryotaPseudomonas Chlororaphisinhibits growth of Synechococcus sp. PCC 7942 and Rhizoctonia solani, kills Caenorhabditis elegansRhizosphere of maize, Kiev region, UkrainePopova et al. 2014
ProkaryotaLactobacillus RhamnosusnanaPogačić et al. 2016
EukaryotaGanoderma Lucidumnasaprophytic on deciduous treesCampos Ziegenbein et al. 2006
EukaryotaSpongiporus Leucomallellusnasaprophytic mostly on wet, old pinesCampos Ziegenbein et al. 2006
EukaryotaPleurotus EryngiinanaUsami et al. 2014
EukaryotaPleurotus CystidiosusnanaUsami et al. 2014
EukaryotaTrichoderma Atroviridenawater damaged buildings, BelgiumPolizzi et al. 2012
ProkaryotaBurkholderia CepaciaRhizosphereBlom et al. 2011
ProkaryotaXanthomonas Campestrisn/aNAWeise et al. 2012
ProkaryotaSerratia Sp.Might be involved in inhibition of fungal growth.NASchulz and Dickschat 2007
ProkaryotaStigmatella Aurantiacan/aNADickschat et al. 2005_5
ProkaryotaWautersiella FalseniiNematicidal activitycow dungXU et al. 2015
EukaryotaTuber BorchiiNoneT. melanosporum, T. borchii were collected from northern Italy (Piedmont) and T. indicum from Yunnan and Sichuan Provinces (China). Splivallo et al. 2007b
EukaryotaCryptococcus NemorosusNANALjunggren et al. 2019
ProkaryotaAchromobacter Sp.NANAAlmeida et al. 2022
ProkaryotaSerratia Sp.NANAAlmeida et al. 2022
EukaryotaAureobasidium PullulansNANAMozūraitis et al. 2022
EukaryotaCryptococcus WieringaeNANAMozūraitis et al. 2022
EukaryotaPichia KluyveriNANAMozūraitis et al. 2022
EukaryotaPichia MembranifaciensNANAMozūraitis et al. 2022
EukaryotaSaccharomyces ParadoxusNANAMozūraitis et al. 2022
EukaryotaTorulaspora DelbrueckiiNANAMozūraitis et al. 2022
ProkaryotaBacillus VelezensisNANAToral et al. 2021
ProkaryotaLactobacillus PlantarumNANAZhang et al. 2022
ProkaryotaBacillus SubtilisNANALee et al. 2023
ProkaryotaLactobacillus PlantarumMa et al. 2023
Method
KingdomSpeciesGrowth MediumApplied MethodVerification
ProkaryotaEscherichia ColiLBSPME/GC-MSno
ProkaryotaEscherichia ColiTSBSPME/GC-MSno
ProkaryotaEscherichia ColiBHISPME/GC-MSno
ProkaryotaPseudomonas AeruginosaTSBSPME/GC-MSno
ProkaryotaPseudomonas AeruginosaBHISPME/GC-MSno
ProkaryotaPseudomonas AeruginosaLBSPME/GC-MSno
ProkaryotaPseudomonas Aeruginosalysogeny brothSPME/GCxGC-MSno
EukaryotaAspergillus FumigatusSDB + chloramphenicolTD/GC-MSno
ProkaryotaKlebsiella PneumoniaeTSBTD/GC-MSno
ProkaryotaPseudomonas AeruginosaTSBTD/GC-MSno
ProkaryotaPseudomonas Aeruginosatrypticase soy agarTD/GC-MSno
ProkaryotaPseudomonas Putidatrypticase soy agarTD/GC-MSno
ProkaryotaStenotrophomonas Maltophiliatrypticase soy agarTD/GC-MSno
ProkaryotaEscherichia ColiColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaProteus MirabilisColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaSerratia MarcescensColumbia sheep bloodTD/GC-MS and MCC-IMSno
ProkaryotaStreptococcus AgalactiaeColumbia sheep bloodTD/GC-MS and MCC-IMSno
EukaryotaPythium OligandrumV8 juice agarSPME/GC-MS/MSyes
ProkaryotaCorynebacterium Accolensbrain heart infusion mediumPorapak / GC/MSno
ProkaryotaCorynebacterium Jeikeiumbrain heart infusion mediumPorapak / GC/MSno
ProkaryotaCorynebacterium Minutissimumbrain heart infusion mediumPorapak / GC/MSno
ProkaryotaCorynebacterium Striatumbrain heart infusion mediumPorapak / GC/MSno
ProkaryotaStaphylococcus Epidermidisbrain heart infusion mediumPorapak / GC/MSno
ProkaryotaStaphylococcus Haemolyticusbrain heart infusion mediumPorapak / GC/MSno
ProkaryotaStaphylococcus Saccharolyticusbrain heart infusion mediumPorapak / GC/MSno
ProkaryotaStaphylococcus Schleiferibrain heart infusion mediumPorapak / GC/MSno
ProkaryotaStaphylococcus Warneribrain heart infusion mediumPorapak / GC/MSno
ProkaryotaEscherichia ColiTrypticase Soy Broth (TSB)HS-SPME/GC-MSno
ProkaryotaSalmonella EntericaTrypticase Soy Broth (TSB)HS-SPME/GC-MSno
ProkaryotaShigella FlexneriTrypticase Soy Broth (TSB)HS-SPME/GC-MSno
ProkaryotaBacillus Sp.Plate Count agar (PCA)GC–MSyes
ProkaryotaBacillus Sp.Methyl Red & Voges Proskauer broth (MRVP-B)SPME, GC-MSyes
ProkaryotaPseudomonas AeruginosaMOPS glucose+EZSPME, GC-MSyes
ProkaryotaShigella SonneiSodium chloride brothSPME, GC-MSno
ProkaryotaStaphylococcus AureusSodium chloride brothSPME, GC-MSno
ProkaryotaVibrio ParahaemolyticusSodium chloride brothSPME, GC-MSno
ProkaryotaBacillus VelezensisMinimal salt mediumSPME, GC-MSno
ProkaryotaBacillus Sp.LB agarSPME-GC-MSno
ProkaryotaBacillus Amyloliquefaciensmodified Murashige-Skoog (MS) culture mediumSPME-GC-MSno
ProkaryotaPseudomonas Sp.LB media, DYGS mediaHS-SPME/GC-MSno
ProkaryotaSerratia FonticolaTSB media, MR-VP (Methyl Red-Vogos Proskeur) media, M+S (Murashige and Skoog) mediaSPME/GC-MSno
ProkaryotaStreptomyces SalmonisGYM agarSPME/GC-MSno
EukaryotaCandida AlbicansYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida GlabrataYGC mediaHS-SPME/GC-GC-ToFMSno
EukaryotaCandida TropicalisYGC mediaHS-SPME/GC-GC-ToFMSno
ProkaryotaPseudomonas AeruginosaTSB mediaHS-SPME/GC-MSno
ProkaryotaEscherichia ColiTSB mediaHS-SPME/GC-MSno
ProkaryotaStenotrophomonas MaltophiliaTYB mediaGC-MSno
ProkaryotaMicrobacterium ParaoxydansTYB mediaGC-MSno
ProkaryotaPseudomonas MediterraneaTYB mediaGC-MSno
ProkaryotaBacillus Sp.TYB mediaGC-MSno
ProkaryotaBacillus VelezensisMOLP mediaSPME/GC-MSyes
ProkaryotaRahnella AquatilisLB mediaHS-SPME/GC-MSyes
EukaryotaTrichoderma AsperellumPDA mediaHS-SPME/GC-MSno
EukaryotaTrichoderma AtroviridePDA mediaHS-SPME/GC-MSno
EukaryotaTrichoderma HarzianumPDA mediaHS-SPME/GC-MSno
ProkaryotaStaphylococcus AureusLB media, MHB media, TSB mediaHS-SPME/GC×GC-TOFMSno
ProkaryotaBacillus VelezensisTSA mediaSPME/GC-MSno
ProkaryotaEscherichia Colirocket lysate, spinach lysateHS-SPME/GC-MSno
ProkaryotaBurkholderia PyrrociniaNA mediaSPME/GC-MSyes
ProkaryotaSerratia PlymuthicaNBIIHeadspace trapping/ GC-MSno
ProkaryotaSerratia ProteamaculansNBIIHeadspace trapping/ GC-MSno
ProkaryotaPseudomonas Fluorescensn/an/ano
ProkaryotaPseudomonas Corrugatan/an/ano
ProkaryotaPseudomonas Chlororaphisn/an/ano
ProkaryotaPseudomonas Aurantiacan/an/ano
ProkaryotaBacillus Simplexn/an/ano
ProkaryotaBacillus Subtilisn/an/ano
ProkaryotaBacillus Weihenstephanensisn/an/ano
ProkaryotaMicrobacterium Oxydansn/an/ano
ProkaryotaStenotrophomonas Maltophilian/an/ano
ProkaryotaStreptomyces Lateritiusn/an/ano
ProkaryotaSerratia Marcescensn/an/ano
ProkaryotaSerratia Sp.n/an/ano
ProkaryotaSerratia OdoriferaNBIIHeadspace trapping/ GC-MSno
ProkaryotaSerratia MarcescensNBIIHeadspace trapping/ GC-MSno
EukaryotaTuber Aestivumn/an/ano
EukaryotaTuber Melanosporumn/an/ano
ProkaryotaBurkholderia AmbifariaLuria-Bertani medium, Malt Extractn/ano
ProkaryotaBurkholderia AndropogonisLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CaribensisLB and AngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CaryophylliMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia CepaciaMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia FungorumLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GladioliLB, MR-VP and MSHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GlatheiLB Headspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GlumaeMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia GraminisLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia HospitaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia LataMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia LataAngleHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhenaziniumLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhenoliruptrixLBHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PhytofirmansLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia PyrrociniaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia TerricolaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia TropicaLBHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaBurkholderia XenovoransLBHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaChromobacterium ViolaceumLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaEscherichia ColiMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPandoraea NorimbergensisLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas FluorescensLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaPseudomonas PutidaLB and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia EntomophilaLB and MSHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia MarcescensLB, MS, Angle and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia PlymuthicaLB, MS, Angle and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia PlymuthicaLB, MS and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaSerratia ProteamaculansLB, MS and MR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaStenotrophomonas RhizophilaLBHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)no
ProkaryotaEscherichia ColiTS brothHS-SPME/GC-MS no
ProkaryotaKlebsiella PneumoniaeTS brothHS-SPME/GC-MS no
EukaryotaTrichoderma AtroviridePotato dextrose agarHS-SPME/GC-MS no
ProkaryotaShigella SonneiTS brothGC-MS Super Qyes
ProkaryotaCitrobacter FreundiiTS brothGC-MS SPMEyes
ProkaryotaEnterobacter AerogenesTS brothGC-MS SPMEyes
ProkaryotaEnterobacter CloacaeTS brothGC-MS SPMEyes
ProkaryotaEscherichia ColiTS brothGC-MS SPMEyes
ProkaryotaSalmonella ParatyphiTS brothGC-MS SPMEyes
ProkaryotaShigella SonneiTS brothGC-MS SPMEyes
ProkaryotaPseudomonas FluorescensTS brothGC-MS SPMEyes
ProkaryotaShewanella PutrefaciensTS brothGC-MS SPMEyes
ProkaryotaBacillus CereusTS brothGC-MS SPMEyes
ProkaryotaBacillus PolymyxaTS brothGC-MS SPMEyes
ProkaryotaEnterococcus DuransTS brothGC-MS SPMEyes
ProkaryotaEnterococcus FaeciumTS brothGC-MS SPMEyes
ProkaryotaLactobacillus LactisTS brothGC-MS SPMEyes
ProkaryotaLeuconostoc MesenteroidesTS brothGC-MS SPMEyes
ProkaryotaListeria MonocytogenesTS brothGC-MS SPMEyes
ProkaryotaStreptococcus AgalactiaeTS brothGC-MS SPMEyes
ProkaryotaStreptococcus ThermophilusTS brothGC-MS SPMEyes
EukaryotaTrichoderma VirensPotato dextrose agarHS-SPME/GC-MS no
EukaryotaTrichoderma ReeseiPotato dextrose agarHS-SPME/GC-MS no
EukaryotaFusarium Solanino
EukaryotaAspergillus Sp.no
EukaryotaPenicillium Sp.no
ProkaryotaPseudomonas TolaasiiKBSPME-GCno
ProkaryotaPseudomonas BrassicacearumKing's B AgarSPME-GC/MSno
ProkaryotaPseudomonas PutidaKing's B AgarSPME-GC/MSno
ProkaryotaBacillus SubtilisMurashige and Skoog mediumcapillary GC;GC/MSyes
ProkaryotaBacillus AmyloliquefaciensMurashige and Skoog mediumcapillary GC;GC/MSyes
ProkaryotaPseudomonas JesseniiLB mediumGC/MSyes
ProkaryotaPseudomonas Aeruginosaminimal medium/ Brian mediumSPME-GC/MSno
ProkaryotaPseudomonas ChlororaphisLB mediumSPME-GC/MSno
ProkaryotaLactobacillus Rhamnosuscurd-based broth mediumGC/MSyes
EukaryotaGanoderma LucidumnaGC/MSno
EukaryotaSpongiporus LeucomallellusnaGC/MSno
EukaryotaPleurotus EryngiinaGC/MS, GC-O, AEDAno
EukaryotaPleurotus CystidiosusnaGC/MS, GC-O, AEDAno
EukaryotaTrichoderma Atroviridemalt extract agar; potato dextrose agar; water agar; yeast extract agar; Czapek agarSPME-GC/MSno
ProkaryotaBurkholderia CepaciaMR-VPHeadspace air was trapped in glass Gerstel TDS tubes and analysed by gas chromatography with mass selective detection (GC-MSD)yes
ProkaryotaXanthomonas CampestrisNBIIClosed airflow-system/GC-MS and PTR-MSno
ProkaryotaStigmatella Aurantiacan/an/ano
ProkaryotaWautersiella FalseniiLB liquidSPME-GC/MSno
EukaryotaTuber BorchiiNoneNoneyes
EukaryotaCryptococcus Nemorosusliquid YPD mediumGC-MSno
ProkaryotaAchromobacter Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
ProkaryotaSerratia Sp.LB broth supplemented with cryoprotectant solution (25 g L−1 gelatin, 50 g L−1 lactose, 10 g L−1 peptone, and 250 g L−1 glycerol)SPME with gas chromatograph (Agilent 7890A, Agilent Technologies) connected to a mass spectrometer (Pegasus® HT TOFMS, LECO Corporation)no
EukaryotaAureobasidium PullulansYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaCryptococcus WieringaeYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaPichia KluyveriYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaPichia MembranifaciensYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaSaccharomyces ParadoxusYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
EukaryotaTorulaspora DelbrueckiiYPD-agar plates (1% yeast extract, 1% peptone, 2% dextrose, 2% agar)SPME-GC-MSno
ProkaryotaBacillus VelezensisMOLPHS-SPME-GC/MSno
ProkaryotaBacillus Velezensistryptic soy agar (TSA, Panreac Applichem) mediumHS-SPME-GC/MSno
ProkaryotaLactobacillus Plantarumchickpea milkUHPLC/MSno
ProkaryotaBacillus SubtilisTryptone soy broth (TSB)HPLCno
ProkaryotaLactobacillus Plantarumtuna cooking liquidHS-SPME-GC/MSno