Carbonylation of glycerol with urea to glycerol carbonate over supported Zn catalysts

Kondawar, Sharda E.; Mane, Rasika B.; Vasishta, A.; More, Sagar; Dhengale, Shankar D.; Rode, Chandrashekhar V.

doi:10.1007/s13203-017-0177-2

Cited by 30 publications

(24 citation statements)

References 33 publications

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“…The activation energy (Ea) obtained from present work was 50.5 kJ.mol -1 . This value could be compared to Zn/MCM-41 catalyst which gave activation energy of 39.82 kJ.mol -1 [20]. The value of Ea here was also lower than that of polystyrene, chitosan and commercial silica which gave 142.9, 163 and 166.7 kJ.mol -1 , respectively [7].…”

Section: The Results Of Kinetic Modeling and Parameter Estimationmentioning

confidence: 77%

“…Further, by comparing amberlyst-15 with ZnBr2 containing ionic liquid to catalyze the same reaction, it was found that glycerol conversion could reach 52 to 65% within the temperature range of 393-413 K with a catalyst loading of 0.5% [10]. Kondawar et al [20] investigated the influence of temperature within a range of 393-433 K over Zn catalyst. It was found that glycerol conversion increased from 56 to 95%.…”

Section: The Influence Of Reaction Temperature (353-383 K)mentioning

confidence: 99%

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Kinetics Modeling of Glycerol Carbonate Synthesis from Glycerol and Urea over Amberlyst-15 Catalyst

et al. 2019

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Synthesize of glycerol carbonate from glycerol and urea is an attractive path as glycerol carbonate has a large potential as a green solvent. The aim of the present study was to develop a kinetic model of glycerol carbonate synthesis with amberlyst-15 resins as a catalyst. The investigation was carried out at various temperatures from 353 to 383 K and catalyst loading from 0.25 to 1 wt.% of glycerol. The experimental results indicated that both temperature and catalyst loading have an important effect on the glycerol conversion. According to the experimental result, the highest glycerol conversion was found 36.90% which was obtained using a molar ratio of urea to glycerol 1:3, catalyst loading of 1 wt.%, stirrer speed of 700 rpm, the temperature of 383 K and reaction time of 5 h. A kinetic model was developed based on elementary steps that take place over the catalyst. The model estimated that the pre-exponential factor was 2.89.104 mol.g–1.min–1 and the activation energy was 50.5 kJ.mol–1. By comparing the simulation and experimental data, it could be inferred that the model could predict the trend of experimental data well over the range of temperature and catalyst loading investigated in the present study.

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Section: The Results Of Kinetic Modeling and Parameter Estimationmentioning

confidence: 77%

Section: The Influence Of Reaction Temperature (353-383 K)mentioning

confidence: 99%

Kinetics Modeling of Glycerol Carbonate Synthesis from Glycerol and Urea over Amberlyst-15 Catalyst

et al. 2019

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“…anks to its high surface area of 692 m 2 g −1 , well-dispersed ZnO phase onto the mesoporous framework of MCM-41, and good balanced acid (which activates urea molecules, 0.020 mmol g −1 ) with basic sites (which activates the glycerol, 1.61 mmol g −1 ), 75% glycerol conversion and 98% selectivity of GC were determined. Similarly, immobilizing ZnO catalyst onto the different acid carriers (MCM-41, SBA-15, SiO 2 , Al 2 O 3 , ZrO 2 , and s-ZrO 2 ) (5% Zn/MCM-41, 83% GC yield at 140℃ in 5 h) [64], Zn-exchanged zeolites including Zn-MOR, Zn-ZSM-5, Zn-beta, and Zn-FAU (Zn-HY-3, 93% GC yield at 150℃ for 3 h) [65], activated red mud-supported Zn/Al oxide catalysts (50% Zn/Al-ARM, 58.1% GC yield at 140℃ within 5 h) were also reported for efficient transformation of glycerol and urea into GC with relative good yields. Zinc exchanged heteropoly tungstate (Zn x TPA) catalysts were successfully developed and evaluated for selective carbonylation of glycerol with urea to manufacture GC [66].…”

Section: Reaction With Zinc-based Catalyst As Depicted Inmentioning

confidence: 99%

Progress of Catalytic Valorization of Bio-Glycerol with Urea into Glycerol Carbonate as a Monomer for Polymeric Materials

Zhang

Wang

et al. 2020

Advances in Polymer Technology

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Versatile polymers with highly adjustable characteristics and a broad range of applications are possibly developed owing to the contemporary industrial polymerization techniques. However, industrial production of large amounts of chemicals and polymers heavily depends on petroleum resources which are dwindling and unsustainable. Of particular interest is to utilize sustainable and green resources for the manufacture of polymeric materials. The efficient transformation of bio-glycerol to the relevant functional derivatives are being widely investigated owing to the increasing demand for enhancing the value of glycerol manufactured by biodiesel and oleochemical industries. With respect to glycerol-based polymer chemistry and technology, considering the economy and environmental benefits, using effective catalysts for the selective transformation of bio-glycerol and urea into glycerol carbonate (GC) as a polymer monomer is of great significance. In this review, recent studies on GC synthesis involving the catalysts such as zinc, magnesium, tungsten, ionic liquid-based catalysts, reaction conditions, and possible pathways are primarily described. Some critical issues and challenges with respect to the rational development of heterogeneous catalytic materials like well-balanced acid-base sites are also illustrated.

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“…Carbonylation of glycerol with ethylene carbonate in supercritical carbon dioxide (CO 2 ) in the presence of zeolites and Amberlyst A26 (OH − and HCO 3 − forms of ion exchange resins) resulted in a low percentage of glycerol conversion of <25% [14]. The preparation of GC using urea as the carbonyl source and catalyst with Lewis acid sites associated with sulfonate groups of the polystyrene matrix was shown to be a more feasible route [18,19], exhibiting GC molar yields of 61% to 85% based on glycerol. Yoo et al [16] reported that the use of heterogeneous mesoporous zinc sulfate as a catalyst for the glycerol-urea reaction exhibited a good molar yield of 86%.…”

Section: Introductionmentioning

confidence: 99%

ZnO/SiO2 Composite as Catalyst for the Transformation of Glycerol to Glycerol Carbonate

2020

Makara J.Sci

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Carbonylation of glycerol with urea to glycerol carbonate over supported Zn catalysts

Cited by 30 publications

References 33 publications

Kinetics Modeling of Glycerol Carbonate Synthesis from Glycerol and Urea over Amberlyst-15 Catalyst

Kinetics Modeling of Glycerol Carbonate Synthesis from Glycerol and Urea over Amberlyst-15 Catalyst

Progress of Catalytic Valorization of Bio-Glycerol with Urea into Glycerol Carbonate as a Monomer for Polymeric Materials

ZnO/SiO2 Composite as Catalyst for the Transformation of Glycerol to Glycerol Carbonate

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