32134-69-3

Upstream product

• 527-35-5 2,3,5,6-tetramethylphenol 
• 108-24-7 acetic anhydride 
• 95-93-2 1,2,4,5-tetramethylbenzene 
• 127-09-3 sodium acetate 
• 127-08-2 potassium acetate 
• 2142-79-2 2,3,5,6-tetramethylacetophenone 
• 64-19-7 acetic acid 
• 32134-67-1 (2,3,5,6-tetramethylphenyl)-λ³-iodanediyl diacetate 
• 3240-34-4 [bis(acetoxy)iodo]benzene 

Relevant academic research and scientific papers

Gold-catalyzed oxidative acyloxylation of arenes

A variety of nonactivated hindered aromatic rings are acyloxylated (22 examples, up to 83% yield) in the presence of PPh3AuCl as the catalyst and di(acetoxy)iodobenzene as the oxidant. The reaction proceeds at 110 °C in an acid media and allows the formation of both hindered acetoxy and acyloxy derivatives. This methodology nicely complements the Pd-catalyzed arene acyloxylation reaction, which is not operating on hindered substrates and allows the Au-catalyzed unprecedented acyloxylation reaction of arenes, implying various carboxylic acids.

Gold(III)-catalyzed direct acetoxylation of arenes with iodobenzene diacetate

AuCl3-catalyzed direct acetoxylation of electron-rich aromatic compounds has been achieved with iodobenzene diacetate as the acetoxylation reagent.

Aromatic Iodination: Evidence of Reaction Intermediate and of the ?-Complex Character of the Transition State

The reactivity of the four different procedures of aromatic iodination is compared under the same experimental conditions, and their selectivity toward two substrates in competition, i. e., mesitylene (1,3,5-trimethylbenzene, MES) and durene (1,2,4,5-tetramethylbenzene, DUR), is evaluated.Two of these procedures, namely, S2O82-/I2 and Ce(IV)/I2, present strong oxidizing capacity.Since the same MES/DUR relative reactivity is obtained from the four procedures, it becomes possible to state that a common reactive intermediate, most likely the I+ ion, is generated.The use of the MES/DUR mechanistic probe allows one to describe the reactivity picture of the iodination reaction as one of electrophilic substitution at the aromatic nucleous, with a transition state properly represented in terms of a ?-complex.The radical cation of durene also forms when the iodination is carried out by means of oxidizing agents, but it is solely responsible for the formation of side-chain substitution products and is not involved in the nuclear substitution process.

Regioselective Side-Chain Nitration of Polymethylbenzenes Directed by an Acyl Function and Its Application to the Synthesis of Polysubstituted Phthalic Acid Derivatives

Nitration of three types of tetramethylacetophenones and pentamethylacetophenone with fuming nitric acid in acetic anhydride was carried out.The product distributions were compared with those estimated from substituent effects.A variety of acylpentamethylbenzenes including pentamethylbenzoic acid were reacted with the nitrating system to give regioselectively 2-(nitromethyl)-3,4,5,6-tetramethylacylbenzenes.The selective nitrations of some benzoic acid derivatives followed by an alkaline treatment have been found to provide the N-hydroxyphthalimide derivatives, which a re readily converted to the phthalic anhydrides and the phthalazines.

Studies on Electrolytic Substitution Reactions. XVII. Selective Nuclear Acetoxylation of Alkylaromatic Compounds

Anodic nuclear monoacetoxylation of alkylaromatics (p-xylene, isodurene, mesitylene, durene) can be achieved with high selectivity with respect to the side-chain acetate by carrying out the electrolysis in the presence of Pd on carbon in a nondevided cell.This arrangement utilizes cathodically generated hydrogen to effect cleavage of the benzylic acetate as it is formed, thus continuously regenerating the substrate.The nuclear acetate which is resistant toward hydrogenolysis accumulates in the reaction moxture.