3742-42-5

Basic information

• Product Name: 4-Ethylcyclohexene
• Synonyms: 4-Ethyl-1-cyclohexene;4-Ethylcyclohexene
• CAS NO: 3742-42-5
• Molecular Formula: C₈H₁₄
• Molecular Weight: 110.2
• Mol File: 3742-42-5.mol
• Article Data: 28

Chemical Properties

• Melting Point: -81.99°C (estimate)
• Boiling Point: 131 ºC
• Flash Point: 13 ºC
• Appearance: /
• Density: 0.802
• Vapor Pressure: 11.7mmHg at 25°C
• Refractive Index: 1.4470
• CAS DataBase Reference: 4-Ethylcyclohexene(CAS DataBase Reference)
• NIST Chemistry Reference: 4-Ethylcyclohexene(3742-42-5)
• EPA Substance Registry System: 4-Ethylcyclohexene(3742-42-5)

Safety Data

• Hazardous Substances Data: 3742-42-5(Hazardous Substances Data)

Usage

General Description

4-Ethylcyclohexene is a chemical compound with the molecular formula C8H14. It is classified as an alkene, with a double bond between carbon atoms 1 and 2 in the cyclohexene ring. 4-Ethylcyclohexene is a clear, colorless liquid with a sweet, gasoline-like odor. 4-Ethylcyclohexene is commonly used as a solvent and as an intermediate in the production of other chemicals. It is also used in the manufacture of rubber, plastics, and other industrial products. The compound is flammable and should be handled and stored with care due to its potential hazards.

InChI:InChI=1/C8H14/c1-2-8-6-4-3-5-7-8/h3-4,8H,2,5-7H2,1H3

Upstream product

• 100-40-3 4-ethenylcyclohexene 
• 4534-74-1 4-ethylcyclohexanol 
• 978-70-1 tris<2-(3-cyclohexen-1-yl)ethyl>aluminum 
• 617-86-7 triethylsilane 
• 1678-91-7 ethyl-cyclohexane 
• 64-17-5 ethanol 
• 1873-88-7 1,1,1,3,5,5,5-heptamethyltrisiloxan 
• 106-99-0 buta-1,3-diene 
• 201230-82-2 carbon monoxide 
• 123-07-9 4-Ethylphenol 
• 1453-24-3 1-ethylcyclohexene 
• 500283-40-9 4-Ethyl-cyclohexanol-acetat 
• 932-66-1 1-cyclohexenyl methyl ketone 

Downstream Products

• 32658-82-5 1-(1-ethylcyclohexyl)benzene 

Relevant articles and documents

Heterometallic Mg?Ba Hydride Clusters in Hydrogenation Catalysis

Reaction of a MgN“2/BaN”2 mixture (N“=N(SiMe3)2) with PhSiH3 gave three unique heterometallic Mg/Ba hydride clusters: Mg5Ba4H11N”7 ? (benzene)2 (1), Mg4Ba7H13N“9 ? (toluene)2 (2) and Mg7Ba12H26N”12 (3). Product formation is controlled by the Mg/Ba ratio and temperature. Crystal structures are described. While 3 is fully insoluble, clusters 1 and 2 retain their structures in aromatic solvents. DFT calculations and AIM analyses indicate highly ionic bonding with Mg?H and Ba?H bond paths. Also unusual H????H? bond paths are observed. Catalytic hydrogenation with MgN“2, BaN”2 and the mixture MgN“2/BaN”2 has been studied. Whereas MgN“2 is only active in imine hydrogenation, alkene and alkyne hydrogenation needs the presence of Ba. The catalytic activity of the MgN”2/BaN“2 mixture lies in general between that of its individual components and strong cooperative effects are not evident.

One-pot synthesis of aldoximes from alkenes: Via Rh-catalysed hydroformylation in an aqueous solvent system

Aldoxime synthesis directly starting from alkenes was successfully achieved through the combination of hydroformylation and subsequent condensation of the aldehyde intermediate with aqueous hydroxylamine in a one-pot process. The metal complex Rh(acac)(CO)2 and the water-soluble ligand sulfoxantphos were used as the catalyst system, providing high regioselectivities in the initial hydroformylation. A mixture of water and 1-butanol was used as an environmentally benign solvent system, ensuring sufficient contact of the aqueous catalyst phase and the organic substrate phase. The reaction conditions were systematically optimised by Design of Experiments (DoE) using 1-octene as a model substrate. A yield of 85% of the desired linear, terminal aldoxime ((E/Z)-nonanal oxime) at 95% regioselectivity was achieved. Other terminal alkenes were also converted successfully under the optimised conditions to the corresponding linear aldoximes, including renewable substrates. Differences of the reaction rate have been investigated by recording the gas consumption, whereby turnover frequencies (TOFs) >2000 h-1 were observed for 4-vinylcyclohexene and styrene, respectively. The high potential of aldoximes as platform intermediates was shown by their subsequent transformation into the corresponding linear nitriles using aldoxime dehydratases as biocatalysts. The overall reaction sequence thus allows for a straightforward synthesis of linear nitriles from alkenes with water being the only by-product, which formally represents an anti-Markovnikov hydrocyanation of readily available 1-alkenes.

Alkene Transfer Hydrogenation with Alkaline-Earth Metal Catalysts

The alkene transfer hydrogenation (TH) of a variety of alkenes has been achieved with simple AeN′′2 catalysts [Ae=Ca, Sr, Ba; N′′=N(SiMe3)2] using 1,4-cyclohexadiene (1,4-CHD) as a H source. Reaction of 1,4-CHD with AeN′′2 gave benzene, N′′H, and the metal hydride species N′′AeH (or aggregates thereof), which is a catalyst for alkene hydrogenation. BaN′′2 is by far the most active catalyst. Hydrogenation of activated C=C bonds (e.g. styrene) proceeded at room temperature without polymer formation. Unactivated (isolated) C=C bonds (e.g. 1-hexene) needed a higher temperature (120 °C) but proceeded without double-bond isomerization. The ligands fully control the course of the catalytic reaction, which can be: 1) alkene TH, 2) 1,4-CHD dehydrogenation, or 3) alkene polymerization. DFT calculations support formation of a metal hydride species by deprotonation of 1,4-CHD followed by H transfer. Convenient access to larger quantities of BaN′′2, its high activity and selectivity, and the many advantages of TH make this a simple but attractive procedure for alkene hydrogenation.