18511-62-1

Basic information

• Product Name: 2-(4-FLUOROPHENYL)OXIRANE
• Synonyms: 4-FLUOROSTYRENE OXIDE;2-(4-FLUOROPHENYL)OXIRANE;2-(P-FLUOROPHENYL)OXIRANE;2-(4-Fluorophenyl)oxirane 95%
• CAS NO: 18511-62-1
• Molecular Formula: C₈H₇FO
• Molecular Weight: 138.14
• EINECS: 242-467-5
• Product Categories: Chiral Compounds;Epoxides
• Mol File: 18511-62-1.mol

Chemical Properties

• Boiling Point: 92 °C14 mm Hg(lit.)
• Flash Point: 72 °F
• Appearance: /
• Density: 1.167 g/mL at 25 °C(lit.)
• Vapor Pressure: 4.58E-05mmHg at 25°C
• Refractive Index: n20/D 1.508(lit.)
• Solubility: Difficult to mix.
• CAS DataBase Reference: 2-(4-FLUOROPHENYL)OXIRANE(CAS DataBase Reference)
• NIST Chemistry Reference: 2-(4-FLUOROPHENYL)OXIRANE(18511-62-1)
• EPA Substance Registry System: 2-(4-FLUOROPHENYL)OXIRANE(18511-62-1)

Safety Data

• Statements: 10
• Safety Statements: 16-24/25
• RIDADR: UN 1993 3/PG 2
• WGK Germany: 3
• HazardClass: 6.1
• PackingGroup: II
• Hazardous Substances Data: 18511-62-1(Hazardous Substances Data)

Usage

Uses

Used in Chemicals Industry:
2-(4-FLUOROPHENYL)OXIRANE is used as a chemical intermediate for the synthesis of various compounds, taking advantage of its reactive oxirane ring and fluorophenyl group. Its unique structure allows it to be a versatile building block in the development of new chemicals with specific properties and applications.
Used in Pharmaceutical Industry:
In the pharmaceutical industry, 2-(4-FLUOROPHENYL)OXIRANE is utilized as a key intermediate in the development of drugs targeting various medical conditions. Its unique structure can be modified to create new molecules with potential therapeutic effects.
Used in Organic Chemistry:
2-(4-FLUOROPHENYL)OXIRANE is also used in organic chemistry for various purposes, including the synthesis of complex organic molecules and the study of reaction mechanisms involving epoxides and fluorinated aromatics.
Used in Biotransformation:
2-(4-FLUOROPHENYL)OXIRANE can be employed in biotransformation processes, where biological systems, such as enzymes or whole cells, are used to convert the compound into valuable products. This approach can provide an environmentally friendly and selective method for synthesizing new molecules with potential applications in various industries.

InChI:InChI=1/C3H8N2O2.BrH/c4-1-2(5)3(6)7;/h2H,1,4-5H2,(H,6,7);1H

Upstream product

• 459-57-4 4-fluorobenzaldehyde 
• 130318-72-8 methyldiphenyltelluronium tetraphenylborate 
• 2181-44-4 trimethylsulfonium methylsulfate 
• 405-99-2 para-fluorostyrene 
• 456-04-2 2-Chloro-4'-fluoroacetophenone 
• 112022-81-8 (S)-1-methyl-3,3-diphenyl-hexahydropyrrolo[1,2-c][1,3,2]oxazaborole 
• 1073-67-2 4-vinylbenzyl chloride 
• 622-97-9 1-ethenyl-4-methylbenzene 
• 403-29-2 2-bromo-4'-fluoroacetophenone 
• 53617-32-6 2-bromo-1-(4-fluorophenyl)ethan-1-ol 
• 1774-47-6 trimethylsulfoxonium iodide 
• 2181-42-2 trimethylsulphonium iodide 
• 126534-43-8 [R]-1-chloro-2-(4-fluorophenyl)-2-ethanol 
• 61592-48-1 2-Chloro-1-(4-fluorophenyl)ethanol 

Downstream Products

• 47168-30-9 2-[2-(3,4-Dichloro-phenyl)-ethylamino]-1-(4-fluoro-phenyl)-ethanol 
• 403-41-8 1-(4-Fluorophenyl)ethanol 
• 7589-27-7 2-(4-Fluorophenyl)ethanol 
• 17951-22-3 1-(4-fluorophenyl)ethane-1,2-diol 
• 18511-62-1 (2S)-2-(4-fluorophenyl)oxirane 
• 213479-90-4 (S)-(+)-1-(4-fluorophenyl)-1,2-ethanediol 
• 179694-35-0 (R)-(-)-1-(4-fluorophenyl)-1,2-ethanediol 
• 18511-62-1 R-(-)-2-(4-fluorophenyl)oxirane 
• 866886-40-0 2-azido-2-(4-fluorophenyl)ethan-1-ol 

Relevant articles and documents

Structure-Guided Regulation in the Enantioselectivity of an Epoxide Hydrolase to Produce Enantiomeric Monosubstituted Epoxides and Vicinal Diols via Kinetic Resolution

Structure-guided microtuning of an Aspergillus usamii epoxide hydrolase was executed. One mutant, A214C/A250I, displayed a 12.6-fold enhanced enantiomeric ratio (E = 202) toward rac-styrene oxide, achieving its nearly perfect kinetic resolution at 0.8 M in pure water or 1.6 M in n-hexanol/water. Several other beneficial mutants also displayed significantly improved E values, offering promising biocatalysts to access 19 structurally diverse chiral monosubstituted epoxides (97.1 - ≥ 99% ees) and vicinal diols (56.2-98.0% eep) with high yields.

Asymmetric Epoxidation of Olefins Catalyzed by Substituted Aminobenzimidazole Manganese Complexes Derived from L-Proline

A family of manganese complexes [Mn(Rpeb)(OTf)2] (peb=1-(1-ethyl-1H-benzo[d]imidazol-2-yl)-N-((1-((1-ethyl-1H-benzo[d]imidazol-2-yl)methyl) pyrrolidin-2-yl)methyl)-N-methylmethanamine)) derived from L-proline has been synthesized and characterized, where R refers to the group at the diamine backbone. X-ray crystallographic analyses indicate that all the manganese complexes [Mn(Rpeb)(OTf)2] exhibit cis-α topology. These types of complexes are shown to catalyze the asymmetric epoxidation of olefins employing H2O2 as a terminal oxidant with up to 96% ee. Obviously, the R group of the diamine backbone can influence the catalytic activity and enantioselectivity in the asymmetric epoxidation of olefins. In particular, Mn(i-Prpeb)(OTf)2 bearing an isopropyl arm, cannot catalyze the epoxidation reaction with H2O2 as the oxidant. However, when PhI(OAc)2 is used as the oxidant instead, all the manganese complexes including Mn(i-Prpeb)(OTf)2 can promote the epoxidation reactions efficiently. Taken together, these results indicate that isopropyl substitution on the Rpeb ligand inhibits the formation of active Mn(V)-oxo species in the H2O2/carboxylic acid system via an acid-assisted pathway.

Synthesis of new chiral Mn(iii)-salen complexes as recoverable and reusable homogeneous catalysts for the asymmetric epoxidation of styrenes and chromenes

New chiral Mn(iii)-salen complexes 1a-e and 2a-e were synthesized from the reaction of C2-symmetric chiral salen ligands and Mn(CH3COO)2·4H2O under an inert atmosphere followed by aerobic oxidation. These complexes were obtained in 91-96% yields and characterized by HRMS, FT-IR, UV-visible spectroscopy, TGA, and elemental analysis. The chiral Mn(iii)-salen complexes 1a-e and 2a-e were evaluated in the asymmetric epoxidation of styrene using NaOCl as an oxidant in ethyl acetate as a green solvent. The chiral Mn(iii)-salen complexes 1b and 2b (2 mol%) catalyzed the asymmetric epoxidation of substituted styrenes and chromenes to afford the corresponding epoxides in 95-98% yields with 29-88% ee's. The catalysts 1b and 2b were recovered and reused for up to 2 and 3 runs, respectively, in the asymmetric epoxidation of styrene, and the yield of styrene oxide gradually decreased but the ee was consistent.

Halohydrin dehalogenase-catalysed synthesis of fluorinated aromatic chiral building blocks

Kinetic resolution of a series of fluorinated styrene oxide derivatives was studied using halohydrin dehalogenase. A mutant HheC-W249P catalysed nucleophilic ring-opening with azide and cyanide ions with excellent enantioselectivity (E-values up to >200), which gives access to various enantiopure β-substituted alcohols and epoxides. It was found that the enzyme tolerates substrates in concentrations over 50 mM. However, different side reactions were observed at elevated concentrations and with prolonged reaction time. The biocatalytic azidolysis and cyanolysis of racemic 4-trifluoromethylstyrene oxide were performed on preparative scale, affording (R)-2-azido-1-(4-trifluoromethyl-phenyl)-ethanol in 38% yield and 97% ee, and (S)-3-hydroxy-3-(4-trifluoromethyl-phenyl)-propionitrile in 30% yield and 98% ee.

Diastereoselective Alkene Hydroesterification Enabling the Synthesis of Chiral Fused Bicyclic Lactones

Palladium-catalysed diastereoselective hydroesterification of alkenes assisted by the coordinative hydroxyl group in the substrate afforded a variety of chiral γ-butyrolactones bearing two stereocenters. Employing the carbonylation-lactonization products as the key intermediates, the route from the alkenes with single chiral center to chiral THF-fused bicyclic γ-lactones containing three stereocenters was developed.

Asymmetric azidohydroxylation of styrene derivatives mediated by a biomimetic styrene monooxygenase enzymatic cascade

Enantioenriched azido alcohols are precursors for valuable chiral aziridines and 1,2-amino alcohols, however their chiral substituted analogues are difficult to access. We established a cascade for the asymmetric azidohydroxylation of styrene derivatives leading to chiral substituted 1,2-azido alcohols via enzymatic asymmetric epoxidation, followed by regioselective azidolysis, affording the azido alcohols with up to two contiguous stereogenic centers. A newly isolated two-component flavoprotein styrene monooxygenase StyA proved to be highly selective for epoxidation with a nicotinamide coenzyme biomimetic as a practical reductant. Coupled with azide as a nucleophile for regioselective ring opening, this chemo-enzymatic cascade produced highly enantioenriched aromatic α-azido alcohols with up to >99% conversion. A bi-enzymatic counterpart with halohydrin dehalogenase-catalyzed azidolysis afforded the alternative β-azido alcohol isomers with up to 94% diastereomeric excess. We anticipate our biocatalytic cascade to be a starting point for more practical production of these chiral compounds with two-component flavoprotein monooxygenases.

Aerobic epoxidation of styrene over Zr-based metal-organic framework encapsulated transition metal substituted phosphomolybdic acid

Catalytic epoxidation of styrene with molecular oxygen is regarded as an eco-friendly alternative to producing industrially important chemical of styrene oxide (STO). Recent efforts have been focused on developing highly active and stable heterogeneous catalysts with high STO selectivity for the aerobic epoxidation of styrene. Herein, a series of transition metal monosubstituted heteropolyacid compounds (TM-HPAs), such as Fe, Co, Ni or Cu-monosubstituted HPA, were encapsulated in UiO-66 frameworks (denoted as TM-HPA@UiO-66) by direct solvothermal method, and their catalytic properties were investigated for the aerobic epoxidation of styrene with aldehydes as co-reductants. Among them, Co-HPA@UiO-66 showed relatively high catalytic activity, stability and epoxidation selectivity at very mild conditions (313 K, ambient pressure), that can achieve 82 % selectivity to STO under a styrene conversion of 96 % with air as oxidant and pivalaldehyde (PIA) as co-reductant. In addition, the hybrid composite catalyst can also efficiently catalyze the aerobic epoxidation of a variety of styrene derivatives. The monosubstituted Co atoms in Co-HPA@UiO-66 are the main active sites for the aerobic epoxidation of styrene with O2/PIA, which can efficiently converting styrene to the corresponding epoxide through the activation of the in-situ generated acylperoxy radical intermediate.

MeOTf/KI-catalyzed efficient synthesis of 2-arylnaphthalenesviacyclodimerization of styrene oxides

The MeOTf/KI-catalyzed synthesis of 2-arylnaphthalene derivatives from aryl ethylene oxides in alcohol under ambient conditions is described. The present protocol has a higher atom efficiency and wider substrate applicability with excellent yields. The reaction proceeded using the aryl ethylene oxides to give 2-arylnaphthalenes either in homo-coupling or in cross-coupling. The reaction could also be carried out at the gram scale in minutes.

MeOTf-catalyzed formal [4?+?2] annulations of styrene oxides with alkynes leading to polysubstituted naphthalenes through sequential electrophilic cyclization/ring expansion

MeOTf-catalyzed formal [4 + 2] annulation of styrene oxides with alkynes to afford polysubstituted naphthalenes has been realized, which undergoes sequential electrophilic cyclization/ring expansion. A range of substrates were tolerated in the formation of naphthalene derivatives with high regioselectivity in satisfactory yields. The reaction could also be carried out on gram scale.

Effect of the Ligand Backbone on the Reactivity and Mechanistic Paradigm of Non-Heme Iron(IV)-Oxo during Olefin Epoxidation

The oxygen atom transfer (OAT) reactivity of the non-heme [FeIV(2PyN2Q)(O)]2+ (2) containing the sterically bulky quinoline-pyridine pentadentate ligand (2PyN2Q) has been thoroughly studied with different olefins. The ferryl-oxo complex 2 shows excellent OAT reactivity during epoxidations. The steric encumbrance and electronic effect of the ligand influence the mechanistic shuttle between OAT pathway I and isomerization pathway II (during the reaction stereo pure olefins), resulting in a mixture of cis-trans epoxide products. In contrast, the sterically less hindered and electronically different [FeIV(N4Py)(O)]2+ (1) provides only cis-stilbene epoxide. A Hammett study suggests the role of dominant inductive electronic along with minor resonance effect during electron transfer from olefin to 2 in the rate-limiting step. Additionally, a computational study supports the involvement of stepwise pathways during olefin epoxidation. The ferryl bend due to the bulkier ligand incorporation leads to destabilization of both (Formula presented.) and (Formula presented.) orbitals, leading to a very small quintet–triplet gap and enhanced reactivity for 2 compared to 1. Thus, the present study unveils the role of steric and electronic effects of the ligand towards mechanistic modification during olefin epoxidation.