3118-78-3

Upstream product

• 554-84-7 meta-nitrophenol 
• 1192-96-7 potassium p-cresolate 
• 1122-93-6 potassium p-methoxyphenolate 
• 1523-13-3 3-nitrophenyl benzoate 
• 2550-74-5 potassium 3-bromophenoxide 
• 36294-16-3 potassium m-methylphenoxide 
• 3046-26-2 p-bromophenol, potassium salt 
• 1121-74-0 potassium 4-chlorophenoxide 
• 100-67-4 potassium phenolate 
• 555-03-3 3-nitroanisole 

Downstream Products

• 31515-58-9 m-Nitrophenyl-prop-2-ensulfonat 
• 13831-55-5 bis(3-nitrophenoxy)methane 
• 24318-00-1 3-(benzyloxy)nitrobenzol 
• 1523-13-3 3-nitrophenyl benzoate 
• 1124-31-8 potassium 4-nitrophenolate 
• 14314-69-3 potassium 2,4-dinitrophenolate 
• 2005-08-5 4-chlorophenyl benzoate 
• 16513-72-7 4-cyanophenyl benzoate 
• 1049702-00-2 4-(2-(3-nitrophenoxy)ethyl)morpholine hydrochloride 
• 1262789-85-4 1-(2-(3-nitrophenoxy)ethyl)pyrrolidine hydrochloride 
• 1052420-33-3 1-(2-(3-nitrophenoxy)ethyl)piperidine hydrochloride 
• 1052510-02-7 N,N-dimethyl-3-(3-nitrophenoxy)propan-1-amine hydrochloride 
• 31515-22-7 m-Nitrophenyl-2,3-dibrompropansulfonat 
• 72200-66-9 m-nitrophenyl β-D-mannopyranoside 

Relevant academic research and scientific papers

Ambident Reactivity of Phenolate Anions Revisited: A Quantitative Approach to Phenolate Reactivities

Prompted by the observation that the regioselectivities of phenolate reactions (C versus O attack) are opposite to the predictions by the principle of hard and soft acids and bases, we performed a comprehensive experimental and computational investigation of phenolate reactivities. Rate and equilibrium constants for the reactions of various phenolate ions with benzhydrylium ions (Aryl2CH+) and structurally related quinone methides have been determined photometrically in polar aprotic solvents. Quantum chemical calculations at the SMD(MeCN)/M06-2X/6-31+G(d,p) level confirmed that O attack is generally favored under kinetically controlled conditions, whereas C attack is favored under thermodynamically controlled conditions. Exceptions are diffusion-limited reactions with strong electrophiles, which give mixtures of products arising from O and C attack, as well as reactions with metal alkoxides in nonpolar solvents, where oxygen attack is blocked by strong ion pairing. The Lewis basicity (LB) and nucleophilicity (N, sN) parameters of phenolates determined in this work can be used to predict whether their reactions with electrophiles are kinetically or thermodynamically controlled and whether the rates are activation- or diffusion-limited. Comparison of the measured rate constants for the reactions of phenolates with carbocations with the Gibbs energies for single-electron transfer manifests that these reactions proceed via polar mechanisms.

Enthalpy-entropy correlations in reactions of aryl benzoates with potassium aryloxides in dimethylformamide

Temperature dependences of the relative reactivity of potassium aryloxides XC6H4O-K+ toward 4-nitrophenyl (1), 3-nitrophenyl (2), 4-chlorophenyl (3), and phenyl (4) benzoates in dimethylformamide (DMF) were studied using the competitive reactions technique. The rate constants kX for the reactions of 1 with potassium 4-cyanophenoxide, 2 with potassium 3-bromophenoxide, 3 with potassium 3-bromo-, 4-bromo-, and unsubstituted phenoxides, 4 with potassium 4-methoxy- and 3-methylphenoxides were measured at 25°C. Correlation analysis of the relative rate constants kX/kH(3-Me) and differences in the activation parameters (δδH≠and δ δS ≠) of competitive reactions revealed the existence of six isokinetic series. We investigated the substituent effect of X on the activation parameters for each isokinetic series and concluded that the reactions of aryl benzoates PhCO2C6H4Y with potassium aryloxides in DMF proceed via a four-step mechanism. The large ρ0(Y) and ρXY values at 25°C obtained for the reactions of 1-3 with potassium aryloxides with an electron-donating substituent refer to the rate-determining formation of the spiro-σ-complex. The Hammett plots for the reactions of 1 and 2 exhibit a downward curvature, causing the motion of the transition state for the rate-determining step according to a Hammond effect as the substituent in aryloxide changes from electron-donating to electron-withdrawing. Analysis of data in the terms of two-dimensional reaction coordinate diagrams leads to the conclusion that significant anti-Hammond effects arise in the cases of ortho-substituted and unsubstituted substrates. It was shown that the isokinetic and compensation effects observed for the reactions of aryl benzoates with potassium aryloxides in DMF can be interpreted in the terms of the electrostatic bonding between the reaction centers.

Surfactant-mediated solvent-free dealkylative cleavage of ethers and esters and trans-alkylation under neutral conditions

A simple, surfactant-mediated, one-pot, solvent-free dealkylative cleavage of aryl ethers and esters followed by subsequent optional trans-alkylation under essentially neutral conditions has been developed.

Method of producing organic compounds in presence of oxyethylene ether catalyst and in a solvent minimized environment

A process of producing organic compounds, such as acetaminophen, nitroalcohols and indoles, employs a catalyst system of an oxyethylene ether and a metal containing inorganic or organic reagent. The oxyethylene ether at least partially complexes the metal of the inorganic or organic reagent. As such, the reactions may be conducted neat. The processes are environmentally friendly and operationally simple.