215376
Acénaphtène
99%
Synonyme(s) :
1,8-éthylènenaphthalène
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About This Item
Formule empirique (notation de Hill):
C12H10
Numéro CAS:
Poids moléculaire :
154.21
Numéro Beilstein :
386081
Numéro CE :
Numéro MDL:
Code UNSPSC :
12352100
ID de substance PubChem :
Nomenclature NACRES :
NA.22
Produits recommandés
Densité de vapeur
5.32 (vs air)
Pression de vapeur
10 mmHg ( 131 °C)
Pureté
99%
Forme
solid
Point d'ébullition
279 °C (lit.)
Pf
90-94 °C (lit.)
Solubilité
chloroform: soluble 5%, clear, colorless to faintly yellow
Chaîne SMILES
C1Cc2cccc3cccc1c23
InChI
1S/C12H10/c1-3-9-4-2-6-11-8-7-10(5-1)12(9)11/h1-6H,7-8H2
Clé InChI
CWRYPZZKDGJXCA-UHFFFAOYSA-N
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Catégories apparentées
Description générale
Acenaphthene is a polycyclic aromatic hydrocarbon used as a building block in the synthesis of polymers and resins.
Bacterial oxidation of acenaphthene by Beijerinckia sp. and Beijerinckia sp. strain B8/36 has been reported. Acenapthene forms 1:1:1 inclusion compound by complexing with inclusion compound of β-cyclodextrin and alcohol. Kinetics of the atmospherically important gas-phase reactions of acenaphthene with OH and NO3 radicals, O3 and N2O5 has been investigated at 296 ± 2K.
Bacterial oxidation of acenaphthene by Beijerinckia sp. and Beijerinckia sp. strain B8/36 has been reported. Acenapthene forms 1:1:1 inclusion compound by complexing with inclusion compound of β-cyclodextrin and alcohol. Kinetics of the atmospherically important gas-phase reactions of acenaphthene with OH and NO3 radicals, O3 and N2O5 has been investigated at 296 ± 2K.
Application
- Optimization of Acenaphthene Production: A research article demonstrated the use of high-efficiency HILIC capillary columns for slurry packing at 2100 bar, showcasing an advanced technique that could optimize the synthesis and purification of complex polycyclic aromatic hydrocarbons like acenaphthene, essential for enhancing productivity and purity in chemical processes (Anderson et al., 2024).
- Environmental Impact Assessment: A study investigated the relationship between polycyclic aromatic hydrocarbons (PAHs) and reactive oxygen species in PM2.5 emissions, providing a critical evaluation of the environmental impacts of compounds like acenaphthene in industrial regions, thus informing pollution control and environmental safety strategies (Xu et al., 2024).
- Advances in Organic Semiconductor Materials: Research focused on the synthesis and properties of pyrene-bridged acenaphthenes, contributing to the development of novel organic semiconductor materials, which are crucial for electronic and photonic applications, thus broadening the utility of acenaphthene in high-tech industries (Polkaehn et al., 2023).
- Bioassays for Organic Pollutants: Researchers developed bioassays for organic pollutants, including acenaphthene, using chemical activity-based loading of artificial sediments. This approach offers a new method to assess ecological risks associated with organic contaminants, while also optimizing the derivation of predicted no-effect concentrations (PNECs) for polycyclic aromatic hydrocarbons, critical for regulatory compliance and environmental health. (Abel et al., 2024), (Sun et al., 2023).
Mention d'avertissement
Warning
Mentions de danger
Conseils de prudence
Classification des risques
Aquatic Acute 1 - Aquatic Chronic 1
Code de la classe de stockage
11 - Combustible Solids
Classe de danger pour l'eau (WGK)
WGK 3
Point d'éclair (°F)
257.0 °F - closed cup
Point d'éclair (°C)
125.0 °C - closed cup
Équipement de protection individuelle
dust mask type N95 (US), Eyeshields, Gloves
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Les clients ont également consulté
Alexander K Lemmens et al.
Physical chemistry chemical physics : PCCP, 21(7), 3414-3422 (2018-11-01)
In this work we report on the experimental and theoretical investigations of the progressional complexation of the polycyclic aromatic hydrocarbon (PAH) acenaphthene with itself and with water. In the interstellar medium, PAH complexes are an important link between molecular gas
Kinetics of the reactions of acenaphthene and acenaphthylene and structurally-related aromatic compounds with OH and NO3 radicals, N2O5 and O3 at 296?2 K.
Atkinson R and Aschmann SM.
International Journal of Chemical Kinetics, 20(7), 513-539 (1988)
Room-temperature phosphorescence from 1: 1: 1 inclusion compounds of. beta.-cyclodextrin with brominated alcohols and acenaphthene.
Hamai S.
Journal of the American Chemical Society, 111(11), 3954-3957 (1989)
M J Schocken et al.
Applied and environmental microbiology, 48(1), 10-16 (1984-07-01)
A Beijerinckia sp. and a mutant strain, Beijerinckia sp. strain B8/36, were shown to cooxidize the polycyclic aromatic hydrocarbons acenaphthene and acenaphthylene. Both organisms oxidized acenaphthene to the same spectrum of metabolites, which included 1-acenaphthenol, 1-acenaphthenone, 1,2-acenaphthenediol, acenaphthenequinone, and a
Willian G Birolli et al.
Marine pollution bulletin, 129(2), 525-533 (2017-10-23)
The biodegradation of polycyclic aromatic hydrocarbons (PAHs) by marine-derived fungi was reported in this work. Marine-derived fungi (Trichoderma harzianum CBMAI 1677, Cladosporium sp. CBMAI 1237, Aspergillus sydowii CBMAI 935, Penicillium citrinum CBMAI 1186 and Mucor racemosus CBMAI 847) biodegraded anthracene
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