3056-73-3

Usage

Synthesis Reference(s)

The Journal of Organic Chemistry, 14, p. 261, 1949 DOI: 10.1021/jo01154a011Synthetic Communications, 25, p. 2877, 1995 DOI: 10.1080/00397919508011836

InChI:InChI=1/C15H13NO/c17-15(16-14-9-5-2-6-10-14)12-11-13-7-3-1-4-8-13/h1-12H,(H,16,17)/b12-11+

Upstream product

• 6502-38-1 chalcone oxime 
• 102-92-1 cinnamoyl chloride 
• 62-53-3 aniline 
• 538-56-7 cinnamic acid anhydride 
• 4198-15-6 3-hydroxy-N,3-diphenylpropanamide 
• 621-82-9 Cinnamic acid 
• 60299-77-6 cinnamoyl cyanide 
• 76128-84-2 Thiozimtsaeureanilid 
• 459-44-9 4-methylbenzenediazonium tetrafluoroborate 
• 100-42-5 styrene 
• 201230-82-2 carbon monoxide 
• 103-71-9 phenyl isocyanate 
• 29834-36-4 trans-3-bromo-1,4-diphenylazetidin-2-one 
• 84958-06-5 C₂₂H₁₉NO₃S 

Downstream Products

• 14371-10-9 (E)-3-phenylpropenal 
• 3271-81-6 hydrocinnamanilide 
• 93500-91-5 α,β-dibromohydrocinnamanilide 
• 1020478-99-2 N-phenyl-cinnamimidoyl chloride 
• 34188-23-3 α-Methylthio-β-chlordihydrozimtsaeureanilid 
• 34193-80-1 3-Chloro-2-(2-chloro-ethylsulfanyl)-3,N-diphenyl-propionamide 
• 5866-86-4 Phenyl-[(E)-(3-phenyl-acryloyl)]-carbamic acid isopropyl ester 
• 104-55-2 3-phenyl-propenal 
• 15954-54-8 β-Butyl-hydrozimtsaeure-anilid 
• 7474-18-2 3,3-diphenylpropanoic acid N-phenylamide 
• 1139588-27-4 N,5-diphenyl-4,5-dihydroisoxazol-3-amine 
• 1191104-11-6 N,3-diphenyl-3-(4,4,5,5-tetramethyl-1,3,2-dioxaborolan-2-yl)propanamide 
• 4888-33-9 4-phenyl-3,4-dihydro-1H-quinolin-2-one 
• 1207742-42-4 4-(4-(methylsulfonyl)phenyl)-3,4-dihydroquinolin-2(1H)-one 

Relevant academic research and scientific papers

Organocatalytic Trans Semireduction of Primary and Secondary Propiolamides: Substrate Scope and Mechanistic Studies

We report a chemoselective, phosphine-catalyzed semireduction of primary and secondary propiolamides. In the presence of stoichiometric pinacolborane and catalytic n-tributylphosphine, a variety of propiolamides were successfully converted to the corresponding acrylamides in excellent yield with (E)-stereoselectivity. The reaction condition is tolerant of various functional groups including alkene, alkyne, ketone, or ester. Deuterium labeling studies established that the hydride from activated pinacolborane is added to the α-carbon and the proton on the amide nitrogen is abstracted by the ?-carbon to furnish the (E)-acrylamides. DFT calculations revealed a clear energetic driving force for the (E)- over the (Z)-isomer. (Figure presented.).

Iron-catalyzed oxidative amidation of acylhydrazines with amines

A new approach for amide bond formation via a mild and efficient Iron-catalyzed cross-coupling reaction of acylhydrazines and amines using TBHP as oxidant is described. This protocol is compatible with a wide range of amines and acylhydrazines. In addition, the synthetic application of the reaction is presented.

Chlorination Reaction of Aromatic Compounds and Unsaturated Carbon-Carbon Bonds with Chlorine on Demand

Chlorination with chlorine is straightforward, highly reactive, and versatile, but it has significant limitations. In this Letter, we introduce a protocol that could combine the efficiency of electrochemical transformation and the high reactivity of chlorine. By utilizing Cl3CCN as the chloride source, donating up to all three chloride atom, the reaction could generate and consume the chlorine in situ on demand to achieve the chlorination of aromatic compounds and electrodeficient alkenes.

Carboxylic Acid Deoxyfluorination and One-Pot Amide Bond Formation Using Pentafluoropyridine (PFP)

This work describes the application of pentafluoropyridine (PFP), a cheap commercially available reagent, in the deoxyfluorination of carboxylic acids to acyl fluorides. The acyl fluorides can be formed from a range of acids under mild conditions. We also demonstrate that PFP can be utilized in a one-pot amide bond formation via in situ generation of acyl fluorides. This one-pot deoxyfluorination amide bond-forming reaction gives ready access to amides in yields of ≤94%.

Investigating the Role of Weak Interactions to Explore the Polymorphic Diversity in Difluorinated Isomeric N-Phenylcinnamamides

A total of nine difluoro derivatives of N-phenylcinnamamides have been synthesized from fluoro-substituted cinnamic acids and anilines in order to investigate the formation of polymorphs arising due to the conformational flexibility around the amide and vinyl group. Among them, four compounds have been found to exist in multiple polymorphic forms, which includes concomitant polymorphism, solvatomorphism, and packing polymorphism, while the remaining five compounds display monomorphic behavior. Crystal structure analyses of all the forms belonging to these four compounds reveal that, although the molecules are primarily held by strong N-H?O hydrogen bonds, the relative interplay of weak C-H?F, C-H?O, C-H?π, and π?πinteractions allows the flexible molecules to adopt different orientations and exhibit polymorphism. These forms interestingly also display different thermal stabilities, and they have been quantified by intermolecular interaction topological analyses. The occurrence of different primary packing motifs in these crystal structures has been further investigated by the crystal structure prediction (CSP) computational method, wherein an energy landscape of an unsubstituted N-phenylcinnamamide was generated and a number of hypothetical structures were accessed with experimentally obtained crystal structures of its difluoro-substituted derivatives.

Nickel-Catalyzed Reductive Cross-Coupling of N-Acyl and N-Sulfonyl Benzotriazoles with Diverse Nitro Compounds: Rapid Access to Amides and Sulfonamides

Herein we report a Ni-catalyzed reductive transamidation of conveniently available N-acyl benzotriazoles with alkyl, alkenyl, and aryl nitro compounds, which afforded various amides with good yields and a broad substrate scope. The same catalytic reaction conditions were also applicable for N-sulfonyl benzotriazoles, which could undergo smooth reductive coupling with nitroarenes and nitroalkanes to afford the corresponding sulfonamides.

Tungsten-Catalyzed Transamidation of Tertiary Alkyl Amides

Transamidation has recently emerged as a straightforward and convenient means to diversify amides. However, the kinetically and thermodynamically demanding transamidation of notoriously robust, fully alkyl-substituted tertiary amides still remains a longstanding challenge. Here, we describe a method for the activation of tertiary alkyl amides to streamline transamidation using simple tungsten(VI) chloride as a catalyst and chlorotrimethylsilane as an additive. The highly electrophilic and oxophilic tungsten catalyst enables the selective scission of a C-N bond of tertiary alkyl amides to effect transamidation of a myriad of structurally and electronically diverse tertiary alkyl amides and amines. Mechanistic study implies that the synergistic effect of the catalyst and the additive could pronouncedly induce the nucleophilic acyl substitution of tertiary alkyl amide with amine to realize transamidation.

Manganese Catalyzed Direct Amidation of Esters with Amines

The transition metal catalyzed amide bond forming reaction of esters with amines has been developed as an advanced approach for overcoming the shortcomings of traditional methods. The broad scope of substrates in transition metal catalyzed amidations remains a challenge. Here, a manganese(I)-catalyzed method for the direct synthesis of amides from a various number of esters and amines is reported with unprecedented substrate scope using a low catalyst loading. A wide range of aromatic, aliphatic, and heterocyclic esters, even in fatty acid esters, reacted with a diverse range of primary aryl amines, primary alkyl amines, and secondary alkyl amines to form amides. It is noteworthy that this approach provides the first example of the transition metal catalyzed amide bond forming reaction from fatty acid esters and amines. The acid-base mechanism for the manganese(I)-catalyzed direct amidation of esters with amines was elucidated by DFT calculations.

Chromium-catalyzed ligand-free amidation of esters with anilines

Amides are important structural motifs in pharmaceutical and agrochemical chemistry because of the intriguing biological active properties. We report here the amidation of commercially available esters with anilines that was promoted by low-cost and air-stable chromium(III) pre-catalyst combined with magnesium, providing access to amides. This reaction occurs without the use of external ligands in a simple operation. Mechanistic studies indicate that a reactive aminated Cr species responsible for the amidation can be considered, which may be formed by reaction of low-valent Cr with aniline followed by reduction with hydrogen evolution.

Electron-Catalyzed Aminocarbonylation: Synthesis of α,β-Unsaturated Amides from Alkenyl Iodides, CO, and Amines

Aminocarbonylation of alkenyl iodides with CO and amines proceeded under heating to produce α,β-unsaturated amides in good yields (23 examples, 71% average yield). This catalyst-free method exhibited good functional-group tolerance, and open a straightforward access to functionalized acrylamides, as illustrated by the synthesis of Ilepcimide. A hybrid radical/ionic mechanism involving chain electron transfer is proposed for this transformation.