J. R. Campanelli scite author profile

SYNOPSISThe hydrolytic depolymerization of molten P E T in excess water was studied using a 2 L stirred pressure reactor at temperatures of 250,265, and 280°C. Rate constants for hydrolysis are calculated from the initial rate data. At initial water : PET charge ratios (w/w) exceeding 5.1, essentially complete depolymerization to monomer is possible at 265°C. At lower water: PET initial charges, an equilibrium is established. The equilibrium constants are calculated for 2 g water/g PET at three temperatures. A kinetic model is proposed to describe the hydrolysis reaction. The model is shown to fit experimental data and to yield good predictions for the equilibrium concentration of carboxyl groups. Carboxyl-group concentrations are measured using an end-group analysis technique. Potentiometric titrations are carried out in one of two solvent systems, dimethylpheno1:chloroform or dimethylsulfoxide, depending on the extent of hydrolysis. 0 1993 John Wiley & Sons, Inc.

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Catalyzed hydrolysis of polyethylene terephthalate melts

Campanelli

Cooper

Kamal

1994

J of Applied Polymer Sci

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SYNOPSISThe effect of zinc catalysts on the hydrolytic depolymerization of polyethylene terephthalate (PET) melts in excess water was studied using a 2-L stirred pressure reactor at temperatures of 250, 265, and 280°C. The main products of the reaction were found to be terephthalic acid, ethylene glycol, and diethylene glycol. Rate constants were calculated from initial rate data at each temperature and found to be about 20% greater than the corresponding rate constants for uncatalyzed hydrolysis. The catalytic effect of zinc, as well as sodium, salts is attributed to the electrolytic destabilization of the polymer-water interface during hydrolysis. The depolymerization rate data at 265°C were found to fit a kinetic model proposed earlier for the uncatalysed hydrolysis of PET. The effect of zinc and sodium salts on the activation energy of hydrolysis, or on the formation of ethylene glycol monomer is unclear.

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Kinetics of glycolysis of poly(ethylene terephthalate) melts

Campanelli

Kamal

Cooper

1994

J of Applied Polymer Sci

128

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SYNOPSISThe reaction of poly(ethy1ene terephthalate) (PET) melts with ethylene glycol was examined in a pressure reactor at temperatures above 245°C. The reaction rate was found to depend on temperature and on the concentrations of liquid ethylene glycol and of ethylene diester groups in the polymer. A kinetic model proposed for the initial period of the reaction was found to be consistent with experimental data. It was found that internal catalysis by ethylene glycol does not play a n important role in the glycolytic depolymerization of PET.The rate constants for glycolysis were calculated for three different temperatures, yielding an activation energy of 92 kJ/mol. Zinc salts, which have a catalytic effect on glycolysis of P E T below 245"C, do not appear to influence glycolysis rates above that temperature.

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Blends of vinylic copolymer with plasticized lignin: Thermal and mechanical properties

Feldman

Banu

Campanelli

et al. 2001

J of Applied Polymer Sci

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ABSTRACT:The article presents an investigation into the use of plasticizers for reducing the degree of association existing within lignin molecules, in order to overcome adverse effects on the mechanical properties of its blends with a vinyl chloride-vinyl acetate (VC-VAc) copolymer. Infrared spectroscopy and differential scanning calorimetry were performed to examine the effect of the plasticizer type and concentration in plasticizing Alcell, an organosolv lignin. The results show that the compatibility and efficiency of a plasticizer are strongly influenced by the solubility parameter, which should be close to that of the lignin. Polyblends prepared with several plasticizers, Alcell lignin, and the VC-VAc copolymer were also investigated by thermal analysis and mechanical testing. Variations in the mechanical properties of these blends were found to correlate with the lignin dispersion quality and with the plasticizer efficiency in Alcell lignin.

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Dynamic Interfacial Tension of Surfactant Mixtures at Liquid–Liquid Interfaces

Campanelli

Wang

1999

Journal of Colloid and Interface Science

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J. R. Campanelli

A kinetic study of the hydrolytic degradation of polyethylene terephthalate at high temperatures

Catalyzed hydrolysis of polyethylene terephthalate melts

Kinetics of glycolysis of poly(ethylene terephthalate) melts

Blends of vinylic copolymer with plasticized lignin: Thermal and mechanical properties

Dynamic Interfacial Tension of Surfactant Mixtures at Liquid–Liquid Interfaces

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