Your search keyword '"Zsolt Fejes"' showing total 3 results

1. Computational Study of Catalytic Urethane Formation

Author

Hadeer Q. Waleed, Marcell Csécsi, Rachid Hadjadj, Ravikumar Thangaraj, Dániel Pecsmány, Michael Owen, Milán Szőri, Zsolt Fejes, Béla Viskolcz, and Béla Fiser

Subjects

QD241-441, Polymers and Plastics, catalyst-free, proton affinities, Organic chemistry, General Chemistry, catalysts, urethane formation, DFT, composite method, Article

Abstract

Polyurethanes (PUs) are widely used in different applications, and thus various synthetic procedures including one or more catalysts are applied to prepare them. For PU foams, the most important catalysts are nitrogen-containing compounds. Therefore, in this work, the catalytic effect of eight different nitrogen-containing catalysts on urethane formation will be examined. The reactions of phenyl isocyanate (PhNCO) and methanol without and in the presence of catalysts have been studied and discussed using the G3MP2BHandHLYP composite method. The solvent effects have also been considered by applying the SMD implicit solvent model. A general urethane formation mechanism has been proposed without and in the presence of the studied catalysts. The proton affinities (PA) were also examined. The barrier height of the reaction significantly decreased (∆E0 > 100 kJ/mol) in the presence of the studied catalysts, which proves the important effect they have on urethane formation. The achieved results can be applied in catalyst design and development in the near future.

Published

2022

2. Experimental and Theoretical Study of Cyclic Amine Catalysed Urethane Formation

Author

Hadeer Q. Waleed, Dániel Pecsmány, Marcell Csécsi, László Farkas, Béla Viskolcz, Zsolt Fejes, and Béla Fiser

Subjects

Polymers and Plastics, amine catalysts, kinetics, catalyst free, composite method, ab initio, General Chemistry

Abstract

The alcoholysis of phenyl isocyanate (PhNCO) using stoichiometric butan-1-ol (BuOH) in acetonitrile in the presence of different cyclic amine catalysts was examined using a combined kinetic and mechanistic approach. The molecular mechanism of urethane formation without and in the presence of cyclic amine catalysts was studied using the G3MP2BHandHLYP composite method in combination with the SMD implicit solvent model. It was found that the energetics of the model reaction significantly decreased in the presence of catalysts. The computed and measured thermodynamic properties were in good agreement with each other. The results prove that amine catalysts are important in urethane synthesis. Based on the previous and current results, the design of new catalysts will be possible in the near future.

Published

2022

3. Urethane Formation with an Excess of Isocyanate or Alcohol: Experimental and Ab Initio Study

Author

Milán Szőri, Zsófia Borbála Rózsa, Peter Mizsey, Christian Orlando Camacho López, Béla Viskolcz, Wafaa Cheikh, and Zsolt Fejes

Subjects

Arrhenius equation, isocyanate excess, allophanate, Polymers and Plastics, ab initio, Kinetics, Ab initio, mechanism, Alcohol, General Chemistry, urethane formation, Isocyanate, Article, Solvent, lcsh:QD241-441, chemistry.chemical_compound, symbols.namesake, chemistry, lcsh:Organic chemistry, kinetics, Thermochemistry, symbols, Physical chemistry, Stoichiometry

Abstract

A kinetic and mechanistic investigation of the alcoholysis of phenyl isocyanate using 1-propanol as the alcohol was undertaken. A molecular mechanism of urethane formation in both alcohol and isocyanate excess is explored using a combination of an accurate fourth generation Gaussian thermochemistry (G4MP2) with the Solvent Model Density (SMD) implicit solvent model. These mechanisms were analyzed from an energetic point of view. According to the newly proposed two-step mechanism for isocyanate excess, allophanate is an intermediate towards urethane formation via six-centered transition state (TS) with a reaction barrier of 62.6 kJ/mol in the THF model. In the next step, synchronous 1,3-H shift between the nitrogens of allophanate and the cleavage of the C&ndash, N bond resulted in the release of the isocyanate and the formation of a urethane bond via a low-lying TS with 49.0 kJ/mol energy relative to the reactants. Arrhenius activation energies of the stoichiometric, alcohol excess and the isocyanate excess reactions were experimentally determined by means of HPLC technique. The activation energies for both the alcohol (measured in our recent work) and the isocyanate excess reactions were lower compared to that of the stoichiometric ratio, in agreement with the theoretical calculations.

Published

2019