5202-76-6

Upstream product

• 5202-75-5 N-[benzoylamino(ethyl)methyl]benzamide 
• 23437-02-7 5-Methyl-2-phenyl-2-oxazoline 
• 51127-16-3 rac-4-ethyl-2-phenyloxazol-5(4H)-one 
• 10283-95-1 N-allylbenzamide 
• 86290-16-6 4-benzamido-1,2-oxothiolane 2-oxide 
• 63163-76-8 (E)-1--2-methyl-1-propen 
• 98-88-4 benzoyl chloride 
• 21384-41-8 N-benzoyl-2-methylaziridine 

Downstream Products

• 1078123-56-4 N-(1-(1-methoxynaphthalen-4-yl)propyl)benzamide 

Relevant academic research and scientific papers

Selective preparation of (Z)- and (E)-prop-1-enylamides from N-allylbenzamides

A series of para-substituted N-allylbenzamides was submitted to isomerization under basic conditions. With LDA at -78°C, the corresponding (E)-N-(prop-1-enyl)benzamide was the major product. With n-butyllithium and the mixture warmed to 0°C, the (Z)-isomer was essentially furnished.

XtalFluor-E mediated proto-functionalization of: N -vinyl amides: Access to N -acetyl N, O -acetals

XtalFluor-E has been extensively used in a broad range of reactions in the past few years. Here we report its use with protic nucleophiles in a catalytic manner for the in situ generation of protons that lead to the proto-functionalization of activated ol

Structure-Dependent Nickel-Catalysed Transposition of N -Allylamides to E- or Z-Enamides

The nickel-catalysed transposition of a carbon-carbon double bond of N-allyl and N-homoallyl amides is described. While the transposition of acyclic amides gave very high Z-selectivity of the enamides, corresponding cyclic N-allyl amides led exclusively t

Pd-Boron-Catalyzed One Carbon Isomerization of Olefins: Water Assisted Process at Room Temperature

A palladium-boronate/borane-system -catalyzed isomerization of olefins has been uncovered. An efficient catalytic combination of [Pd(OAc)2]3-boronate-PCy3-enabled olefin isomerization at 80 °C has been investigated. Addition of water to the reaction showed a remarkable improvement and the isomerization occurred at ambient temperature. These catalytic systems function efficiently for the isomerization of functionalized as well as unfunctionalized olefins. The catalytic conditions demonstrate the involvement of both nonhydride and metal-hydride medium and can be switchable with water as an additive.

A convenient synthesis of N-vinyl enamides via the lithiation and ring-opening reaction of 2-phenyl-2-oxazolines

A simple and efficient synthesis of N-vinyl enamides via the lithiation and ring-opening reaction of 2-phenyl-2-oxazolines with lithium diisopropylamide at room temperature has been developed. This method is especially suitable for the synthesis of multif

Nickel-Catalyzed Synthesis of Enamides and Enecarbamates via Isomerization of Allylamides and Allylcarbamates

A single-component, air-stable nickel precatalyst can catalyze the isomerization of allylamides for the synthesis of enamides. The scope of the reaction encompasses various substituted allylamides and allylcarbamates as well as homoallylamides. The reaction can be performed on a multigram-scale without specialized glove-box equipment or Schlenk techniques.

Relay catalysis by a metal-complex/bronsted acid binary system in a tandem isomerization/carbon-carbon bond forming sequence

A one-pot tandem isomerization/carbon-carbon bond forming sequence catalyzed by a ruthenium complex/Bronsted acid binary system is demonstrated. The method enables the use of readily available allylamides to deliver reactive imines under relay catalysis using a binary catalytic system. Subsequent Bronsted acid catalyzed carbon-carbon bond forming reactions of the generated imines with nucleophilic components afforded Friedel-Crafts and Mannich products in good yields. Copyright

Reactions of N-acylaziridines with sodium metal and sodium naphthalenide. Elimination of olefines

Reactions of N-acylaziridines 1a-g (N-benzoyl except 1d) with sodium or naphthalenide N.- in THF provide a variety of products that usually arise via the aziridino ketyls 2. Homolytic ring opening of 2 generates the amidatoalkyl radicals 3. Only with a very short reaction time were small amounts of benzil or benzoylnaphthalenes obtained indicating a reversible trapping of 2 by dimerization or coupling with N.-. Homolysis of 2 produced always the more stable 3 apart from reactions of monomethylaziridines 1c,d where the primary radical i-3c,d is kinetically favoured. The amides R1CONHCHR4CHR2R3 (9, isopropylamides i-9c,d from 1c,d) were usually the main products. 9 arise from 3 either by H atom abstraction from THF (probably in sodium metal runs) or by reduction of 3 to carbanions 5 that abstract a proton from THF (N.- runs). Addition of 5a (R2-4 = H) to 1a gives finally the ketone 8a. Self reaction of primary radical 3a is dimerization. Self reaction of tertiary or secondary radicals is disproportionation when an allylamide arises. This isomerizes to an enamide unless it is conjugated. R2R3C=CHR4 and R1CONH2 arise (probably) always. The mechanism, possibly a cyclic process of anion 6, is not clear. Johann Ambrosius Barth 1996.

Silylamines in Organic Synthesis. Reactivity of N,N-Bis(silyl) Enamines toward Electrophiles. A Route to Substituted 2-Aza-1,3-butadienes and Pyridines

N,N-Bis(silyl) enamines appeared to be weak nucleophilic reagents and exhibited a very low reactivity toward electrophiles.However, in the presence of a nucleophilic catalyst, nucleophilic activation of the silicon-nitrogen bond was observed.Under fluoride ion catalysis (TBAF or CsF), N,N-bis(silyl) enamines reacted with carbonyl compounds to give substituted 2-aza-1,3-butadienes.Good yields were obtained in reactions with aromatic aldehydes or ketones.In the case of aliphatic carbonyl compounds, 2-aza 1,3-dienes were only formed in moderate yields.Interestingly, enamidines were easily obtained in high yields upon reactions of dimethylformamide in the presence of MeONa as catalyst.The reaction of aromatic α,β-unsaturated ketones gave 2-aza 1,3,5-trienes, which were not isolated but underwent an intramolecular cycloaddition reaction with regioselective formation of substituted 2,4-diarylpyridines.