2013
DOI: 10.1021/jf401185y
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Use of Polyhydroxybutyrate and Ethyl Cellulose for Coating of Urea Granules

Abstract: Fertilizers contain essential nutrients for agricultural growth and development. However, most nitrogen fertilizers are substances with high solubility of ions and are very susceptible to leaching and volatilization. To minimize these losses, an alternative is the creation of a physical barrier around granules. One way is to coat granules with polymers. In the present work urea granules were coated with polyhydroxybutyrate and ethyl cellulose in various conditions in the presence of emulsifiers. The original g… Show more

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Cited by 141 publications
(80 citation statements)
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“…The first weight loss was observed at approximately 100-125 ∘ C corresponding to the following: (i) the loss of nonconstitutional water, (ii) removal of interlayer water, (iii) elimination of water coordinated to exchangeable cations or structural water as mentioned in [63], and (iv) degradation of urea; this discloses the fact that the release properties of our engineered urea CRF formulation would work best at that temperature range. Based on the findings obtained by [64], urea loss at about 140-250 ∘ C is caused by both (i) its own vaporization and (ii) degradation to its complementary form known as biuret [NH(CO) 2 (NH 2 ) 2 ]. The second weight loss was observed at about 225-350 ∘ C attributed to (i) the continuous sublimation of urea and (ii) decomposition or self-condensation of biuret [NH(CO) 2 (NH 2 ) 2 ] to more complex decomposition product to the completion of vaporization and degradation reaction [64].…”
Section: Thermogravimetricmentioning
confidence: 99%
See 1 more Smart Citation
“…The first weight loss was observed at approximately 100-125 ∘ C corresponding to the following: (i) the loss of nonconstitutional water, (ii) removal of interlayer water, (iii) elimination of water coordinated to exchangeable cations or structural water as mentioned in [63], and (iv) degradation of urea; this discloses the fact that the release properties of our engineered urea CRF formulation would work best at that temperature range. Based on the findings obtained by [64], urea loss at about 140-250 ∘ C is caused by both (i) its own vaporization and (ii) degradation to its complementary form known as biuret [NH(CO) 2 (NH 2 ) 2 ]. The second weight loss was observed at about 225-350 ∘ C attributed to (i) the continuous sublimation of urea and (ii) decomposition or self-condensation of biuret [NH(CO) 2 (NH 2 ) 2 ] to more complex decomposition product to the completion of vaporization and degradation reaction [64].…”
Section: Thermogravimetricmentioning
confidence: 99%
“…Based on the findings obtained by [64], urea loss at about 140-250 ∘ C is caused by both (i) its own vaporization and (ii) degradation to its complementary form known as biuret [NH(CO) 2 (NH 2 ) 2 ]. The second weight loss was observed at about 225-350 ∘ C attributed to (i) the continuous sublimation of urea and (ii) decomposition or self-condensation of biuret [NH(CO) 2 (NH 2 ) 2 ] to more complex decomposition product to the completion of vaporization and degradation reaction [64]. The third weight loss was observed at around 500-575 ∘ C and was ascribed to the dehydroxylation of kaolinite a phenomena constituted by the decomposition of urea-kaolinite intercalated compound as well as elimination of structural hydroxyl and organic matter [45,62,63].…”
Section: Thermogravimetricmentioning
confidence: 99%
“…The second and third degradation phases around 75-230 ∘ C and 250-320 ∘ C correspond to both urea vaporization and its complementary degradation compound biuret [NH(CO) 2 (NH2) 2 ], respectively. Preliminary kaolinite dehydroxylation as well as continuous sublimation of urea to its complex decomposition product corresponds to fourth and fifth degradation phases seen at 350-550 ∘ C and 550-800 ∘ C [63], respectively.…”
Section: Tg-dtg Analysismentioning
confidence: 95%
“…Urea Chitosan [25][26][27] Polyhydroxybutyrate (phb), ethyl cellulose Polyethylene, polyvinyl acetate, polyurethane, polyacrylic, polylatic acid KH 2 PO 4 Chitosan, gellan gum [28] NPK Chitosan [29][30][31] Cellulose, natural gum, rosin, waxes…”
Section: Agrochemical Used Polymer Used Referencementioning
confidence: 99%