6710-62-9

Basic information

• Product Name: 1-Phenyl-2-butyn-1-one
• Synonyms: 1-Phenyl-2-butyn-1-one;Tetrolophenone;1-phenylbut-2-yn-1-one;2-Butynophenone;Butynophenone;NSC 138596
• CAS NO: 6710-62-9
• Molecular Formula: C₁₀H₈O
• Molecular Weight: 144.17
• Mol File: 6710-62-9.mol
• Article Data: 24

Chemical Properties

• Boiling Point: 236.7°C at 760 mmHg
• Flash Point: 86.4°C
• Appearance: /
• Density: 1.05g/cm³
• Vapor Pressure: 0.0468mmHg at 25°C
• Refractive Index: 1.547
• CAS DataBase Reference: 1-Phenyl-2-butyn-1-one(CAS DataBase Reference)
• NIST Chemistry Reference: 1-Phenyl-2-butyn-1-one(6710-62-9)
• EPA Substance Registry System: 1-Phenyl-2-butyn-1-one(6710-62-9)

Safety Data

• Hazardous Substances Data: 6710-62-9(Hazardous Substances Data)

Usage

Description

1-Phenyl-2-butyn-1-one, with the molecular formula C10H8O, is a yellow solid chemical compound characterized by a distinctive smell. It is classified as an alkyne due to the presence of a carbon-carbon triple bond. 1-Phenyl-2-butyn-1-one is a valuable reagent in organic synthesis, known for its ability to react with various nucleophiles. It is commonly used in organic chemistry research and serves as a building block in the synthesis of pharmaceuticals and agrochemicals. However, it should be handled with care due to its flammable nature and potential to cause skin and respiratory irritation.

Uses

Used in Organic Chemistry Research:
1-Phenyl-2-butyn-1-one is used as a research compound for studying organic chemistry, particularly in the synthesis and reactions of various organic compounds.
Used in Pharmaceutical Synthesis:
1-Phenyl-2-butyn-1-one is used as a building block in the synthesis of pharmaceuticals, contributing to the development of new drugs and medicinal compounds.
Used in Agrochemical Synthesis:
1-Phenyl-2-butyn-1-one is used as a building block in the synthesis of agrochemicals, aiding in the development of new agricultural chemicals and pesticides.
Used as a Reagent in Organic Synthesis:
1-Phenyl-2-butyn-1-one is used as a valuable reagent in organic synthesis due to its ability to react with various nucleophiles, facilitating the creation of diverse chemical structures and compounds.

InChI:InChI=1/C10H8O/c1-2-6-10(11)9-7-4-3-5-8-9/h3-5,7-8H,1H3

Upstream product

• 590-14-7 1-bromo-1-propene 
• 67-56-1 methanol 
• 932-88-7 1-iodo-2-phenylethyne 
• 591-50-4 iodobenzene 
• 201230-82-2 carbon monoxide 
• 74-99-7 prop-1-yne 
• 6224-91-5 trimethyl(prop-1-ynyl)silane 
• 98-88-4 benzoyl chloride 
• 78-75-1 1,2-Dibromopropane 
• 6919-61-5 N-methoxy-N-methylbenzamide 
• 67538-43-6 dipropynyltrimethylantimony(V) 
• 22548-15-8 Lithium- 
• 22548-32-9 Natrium- 
• 22548-20-5 Kalium- 

Downstream Products

• 1234155-82-8 (E)-3,4-dimethyl-1-phenyl-2-penten-1-one 
• 39159-65-4 1-benzoyl-2-(N-phenylamino)-1-propene 
• 18052-64-7 1-Phenyl-1-trimethylsilyloxy-butin-⁽²⁾ 
• 17335-06-7 ethyl 4-benzoyl-5-methylisoxazole-3-carboxylate 
• 145089-91-4 (Z)-3-(2-hydroxyphenylamino)-1-phenylbut-2-en-1-one 
• 79416-50-5 (S)-1-Phenyl-but-2-yn-1-ol 
• 32398-66-6 (R)-1-phenylbuta-2-yn-1-ol 
• 10250-60-9 1,5-dimethyl-3-phenyl-1H-pyrazole 
• 37928-17-9 5-methyl-3,4-diphenyl isoxazole 

Relevant articles and documents

Rhodium-Catalyzed C?H Activation/Annulation Cascade of Aryl Oximes and Propargyl Alcohols to Isoquinoline N-Oxides

A β-hydroxy elimination instead of common oxidization to carbonyl group in secondary propargyl alcohols was successfully developed to form 2-benzyl substituted isoquinoline N-oxides by a Rhodium-catalyzed C?H activation and annulation cascade, in which moderate to excellent yields (up to 92%) could be obtained under mild reaction conditions, along with good regioselectivity, broad generality and applicability. (Figure presented.).

Laccase-mediated Oxidations of Propargylic Alcohols. Application in the Deracemization of 1-arylprop-2-yn-1-ols in Combination with Alcohol Dehydrogenases

The catalytic system composed by the laccase from Trametes versicolor and the oxy-radical TEMPO has been successfully applied in the sustainable oxidation of fourteen propargylic alcohols. The corresponding propargylic ketones were obtained in most cases in quantitative conversions (87–>99 % yield), demonstrating the efficiency of the chemoenzymatic methodology in comparison with traditional chemical oxidants, which usually lead to problems associated with the formation of by-products. Also, the stereoselective reduction of propargylic ketones was studied using alcohol dehydrogenases such as the one from Ralstonia species overexpressed in E. coli or the commercially available evo-1.1.200, allowing the access to both alcohol enantiomers mostly with complete conversions and variable selectivities depending on the aromatic pattern substitution (97–>99 % ee). To demonstrate the compatibility of the laccase-mediated oxidation and the alcohol dehydrogenase-catalyzed bioreduction, a deracemization strategy starting from the racemic compounds was developed through a sequential one-pot two-step process, obtaining a selection of (S)- or (R)-1-arylprop-2-yn-1-ols with excellent yields (>98 %) and selectivities (>98 % ee) depending on the alcohol dehydrogenase employed.

Covalent Adaptable Networks with Tunable Exchange Rates Based on Reversible Thiol–yne Cross-Linking

The design of covalent adaptable networks (CANs) relies on the ability to trigger the rearrangement of bonds within a polymer network. Simple activated alkynes are now used as versatile reversible cross-linkers for thiols. The click-like thiol–yne cross-linking reaction readily enables network synthesis from polythiols through a double Michael addition with a reversible and tunable second addition step. The resulting thioacetal cross-linking moieties are robust but dynamic linkages. A series of different activated alkynes have been synthesized and systematically probed for their ability to produce dynamic thioacetal linkages, both in kinetic studies of small molecule models, as well as in stress relaxation and creep measurements on thiol–yne-based CANs. The results are further rationalized by DFT calculations, showing that the bond exchange rates can be significantly influenced by the choice of the activated alkyne cross-linker.