592-47-2

Basic information

• Product Name: TRANS-3-HEXENE
• Synonyms: 3-HEXENE;(E)-3-HEXENE;TRANS-3-HEXENE;(3E)-3-Hexene;hex-3-ene;3-HEXENE (CIS- AND TRANS- MIXTURE) 95+%;3-Hexene (cis- and trans- mixture);3-Hexene (cis- and trans- mixture)
• CAS NO: 592-47-2
• Molecular Formula: C₆H₁₂
• Molecular Weight: 84.16
• EINECS: 236-261-4
• Product Categories: Heterocycles
• Mol File: 592-47-2.mol
• Article Data: 118

Chemical Properties

• Melting Point: -113 °C
• Boiling Point: 67 °C(lit.)
• Flash Point: 10 °F
• Appearance: /
• Density: 0.677 g/mL at 25 °C(lit.)
• Refractive Index: n20/D 1.394(lit.)
• CAS DataBase Reference: TRANS-3-HEXENE(CAS DataBase Reference)
• NIST Chemistry Reference: TRANS-3-HEXENE(592-47-2)
• EPA Substance Registry System: TRANS-3-HEXENE(592-47-2)

Safety Data

• Hazard Codes: F,Xn
• Statements: 11-65
• Safety Statements: 9-16-23-29-33-62
• RIDADR: UN 3295 3/PG 2
• WGK Germany: 3
• F: 10-23
• HazardClass: 3
• PackingGroup: II
• Hazardous Substances Data: 592-47-2(Hazardous Substances Data)

Usage

Description

TRANS-3-HEXENE is a colorless liquid hydrocarbon and a type of alkene with a chemical formula of C6H12. It is a highly flammable and volatile compound with a melting point of -125.5°C and a boiling point of 61.0°C.
Used in Chemical Production:
TRANS-3-HEXENE is used as a precursor in the production of various chemicals, including plastics, detergents, and synthetic lubricants.
Used in Food Industry:
TRANS-3-HEXENE is found naturally in fruits such as pineapples and apples, contributing to their characteristic aroma and flavor.
Used in Pharmaceutical Manufacturing:
TRANS-3-HEXENE is used in the manufacturing of pharmaceuticals.
Used as a Solvent in Industrial Processes:
TRANS-3-HEXENE is used as a solvent in various industrial processes.
It is important to handle TRANS-3-HEXENE with caution due to its flammability and potential health hazards if not handled properly.

InChI:InChI=1/2C6H12/c2*1-3-5-6-4-2/h2*5-6H,3-4H2,1-2H3/b6-5+;6-5-

Upstream product

• 592-41-6 1-hexene 
• 60-29-7 diethyl ether 
• 310447-99-5 3,4-dichlorobut-1-ene 
• 75-16-1 methylmagnesium bromide 
• 872823-88-6 3-bromo-4-methoxy-hexane 
• 623-37-0 n-hexan-3-ol 
• 626-93-7 n-hexan-2-ol 
• 97-95-0 2-ethyl-1-butanol 
• 89583-12-0 meso-3,4-dibromohexane 
• 821-08-9 hexa-1,5-dien-3-yne 
• 111-27-3 hexan-1-ol 
• 106-98-9 1-butylene 
• 201230-82-2 carbon monoxide 
• 187737-37-7 propene 

Downstream Products

• 623-37-0 n-hexan-3-ol 
• 3377-87-5 3-bromohexane 
• 2346-81-8 3-chlorohexane 
• 859974-21-3 1-(1-ethyl-butyl)-4-chloro-benzene 
• 4463-35-8 para-3-tolylhexane 
• 4468-42-2 3-phenylhexane 
• 30647-63-3 erythro-3,4-Dithiocyanatohexan 
• 71032-67-2 cis-1,2-diethylcyclopropane 
• 71032-66-1 trans-1,2-diethylcyclopropane 
• 4812-22-0 2-ethyl-1-nitro-2-butene 
• 109-68-2 2-pentene 
• 106-98-9 1-butylene 
• 3681-82-1 acetic acid hex-3-enyl ester 
• 69182-63-4 diacetoxy-1,6 hexene-3 

Relevant articles and documents

Switching the Reactivity of Palladium Diimines with “Ancillary” Ligand to Select between Olefin Polymerization, Branching Regulation, or Olefin Isomerization

Coordinating solvents are commonly employed as ancillary ligands to stabilize late transition metal complexes and are conventionally considered to have little effect on the reaction products. Our work identifies that the presence of ancillary ligand in Pd-diimine catalyzed polymerizations of α-olefins can drastically alter reactivity. The addition of different amounts of acetonitrile allows for switching between distinct reaction modes: isomerization–polymerization with high branching (0 equiv.), regular chain-walking polymerization (1 equiv.), and alkene isomerization with no polymerization (>20 equiv.). Optimization of the isomerization reaction mode led to a general set of conditions to switch a wide variety of diimine complexes into efficient alkene isomerization catalysts, with catalyst loading as low as 0.005 mol %.

Seed-mediated Growth of Alloyed Ag-Pd Shells toward Alkyne Semi-hydrogenation Reactions under Mild Conditions?

Ag@Ag-Pdx core-shell nanocomposites with various Ag/Pd ratio were deposited on Ag nanoplates using a seed growth method. When physically loaded on C3N4, Ag@Ag-Pd0.077/C3N4 with optimized Ag/Pd ratio could accomplish high catalytic performance for the semi-hydrogenation of phenylacetylene as well as other aliphatic (both terminal and internal alkynes) alkynes and phenylcycloalkynes containing functional groups (such as ester, hydroxyl, ethyl groups) under room temperature and 1 atm H2. The alloying and ensemble effects are used to interpret such catalytic performance.

Transfer hydrogenation of alkynes into alkenes by ammonia borane over Pd-MOF catalysts

Ammonia borane with both hydridic and protic hydrogens in its structure acted as an efficient transfer hydrogenation agent for selective transformation of alkynes into alkenes in non-protic solvents. Catalytic synergy between the μ3-OH groups of the UiO-66(Hf) MOF and Pd active sites in Pd/UiO-66(Hf) furnished an elusive >98% styrene selectivity and full phenylacetylene conversion at room temperature. Such performance is not achievable by a Pd + UiO-66(Hf) physical mixture or by a commercial Pd/C catalyst.