Acrylated Biopolymers Derived via Epoxidation and Subsequent Acrylation of Vegetable Oils

Ho, Yee Heng; Parthiban, Anupreetha; Thian, Min Chyong; Ban, Zhen Hong; Siwayanan, Parthiban

doi:10.1155/2022/6210128

Cited by 12 publications

(6 citation statements)

References 48 publications

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“…The efficiency of different nucleophilic catalysts was evaluated using the same operational conditions in order to select the most appropriate catalysts for use in the process. TEA and TPP were selected as two of the most common catalysts used in acrylation reactions [ 18 ], together with three salts of chromium (III).…”

Section: Methodsmentioning

confidence: 99%

“…On the other hand, acrylation of vegetable oils has been generally carried out as a two-step process consisting in an initial epoxidation reaction (as explained above), followed by acrylation using acrylic acid. This is the common way of obtaining acrylated epoxidized vegetable oils, such as the ones made of soybean, palm, castor, linseed, or Jatropha seed [ 17 , 18 , 19 ]. However, in terms of green chemistry (atom economy) and cost-effectiveness, it would be desirable to synthesize acrylated vegetable oils via the direct addition of acrylic acids to the carbon–carbon double bond of the triglyceride as it is prone to capturing electrophiles [ 20 ].…”

Section: Introductionmentioning

confidence: 99%

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One-Step Method for Direct Acrylation of Vegetable Oils: A Biobased Material for 3D Printing

Mendes-Felipe,

Isusi,

Gómez-Jiménez-Aberasturi

et al. 2023

Polymers

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The substitution of fossil resources by alternatives derived from biomass is a reality that is taking on a growing relevance in the chemical and energy industries. In this sense, fats, oils, and their derived products have become indispensable inputs due to their broad functional attributes, stable price and sustainable character. Acrylated vegetable oils are considered to be very versatile materials for very broad applications (such as in adhesives, coatings or inks) since, in the presence of photoinitiators, they can be polymerized by means of UV-initiated free radical polymerizations. The usual process for the synthesis of acrylate vegetable oils consists in reacting epoxidized oils derivatives with acrylic acid. Here, the influence of different catalysts on the activity and selectivity of the process of acrylation of epoxidized soybean oil is studied. In addition, a novel one-step method for direct acrylation of vegetable oils is also explored. This new approach advantageously uses the original vegetable resource and eliminates intermediate reactions, thus being more environmentally efficient. This study offers a simple and low-cost option for synthesizing a biomass-derived monomer and studies the potential for the 3D printing of complex structures via digital light processing (DLP) 3D printing of the thus-obtained novel sustainable formulations.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

One-Step Method for Direct Acrylation of Vegetable Oils: A Biobased Material for 3D Printing

Mendes-Felipe,

Isusi,

Gómez-Jiménez-Aberasturi

et al. 2023

Polymers

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show abstract

“…The main variables affecting the acrylation process are the molar concentration of EVO to acrylic acid, the rate of reaction, the nature and quantity of EVO, and the catalyst and inhibitor used. 110 The primary purpose of an inhibitor is to prevent homo-polymerization during the reaction process. Various inhibitors, such as 4-methoxyphenol, 111 hydroquinone, 112 and 4- tert -butylcatechol, 113 are employed in acrylation reactions.…”

Section: Chemical Modification Of Vegetable Oils (Vos) Into 3d-printa...mentioning

confidence: 99%

Synthesis and application of sustainable vegetable oil-based polymers in 3D printing

Saraswat,

Shagun,

Dhir

et al. 2024

RSC Sustain.

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“…Specific acrylate group peaks were observed at 1636, 1406 and 810 cm À1 , indicating a successful ring-opening acrylation reaction. 28 After UV polymerization of the AELO coatings, these peak the intensities decreased, indicating that the double bonds in the acrylate groups cleaved and converted to single -C-H bonds known also as crosslinking, resulting in an increase in the -C-H stretch intensity at about 3000 cm À1 . The same spectral changes were observed in the FT-IR spectrum of acrylated epoxidized soybean oil in a self-healing reaction with pentaerythritol tetrakis(3-mercaptopropionate).…”

Section: Ft-ir Spectroscopy Analysismentioning

confidence: 99%

Interaction of porous substrate and vegetable oil-based hydrophobic thermoset coatings during UV-polymerization

Husić,

Mahendran,

Sinic

et al. 2023

Journal of Plastic Film & Sheeting

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In the current study, we report the progress in developing new UV polymerizable hydrophobic biobased coatings from modified vegetable oil for porous substrates like paper and wood. The aim was to produce novel hydrophobic coatings on porous substrates and investigate how the porous nature of the substrates will be affected by different chemical formulations that penetrate into the interior of the substrate during the exposure to different intensities of UV light, and what hydrophobic properties that interaction will result in. The curing formulations were based on acrylated epoxidized linseed oil (AELO) as a prepolymer. For the UV polymerization, 1-hydroxycyclohexyl phenyl ketone (Irgacure 184) was used as a photoinitiator; isobornyl acrylate (IBA) and isosorbide methacrylate (IM) were used as bio-based diluents; hexadecyltrimethoxysilane (HDTMS), vinyl-polydimethylsiloxane (v-PDMS), triethoxyoctylsilane (TEOS) were used as hydrophobic additives and they were added in different concentrations to the AELO curing formulations. The formulations were then cured under UV light on wood and paper substrates. FT-IR analysis showed that the AELO resin was successfully polymerized on both paper and wood substrates, and by contact angle measurements it was found that the highest hydrophobicity was achieved for the coatings that contain HDTMS (108° in average). The layer thickness on wood substrates was in between 9 and 20 µm, and on paper substrates between 8 and 24 µm. Only about a 5° difference in contact angle was observed between the coatings with respect to change in diluents and different UV light intensity. All cured samples showed a good chemical resistance to acetic acid, citric acid and ethyl alcohol after 1 hour exposure; to acetone and ethylbutyl acetate after 10 s, and to benzine after 2 minutes. Outstanding hydrophobic behavior was observed for the HDTMS coatings, however, better physical properties were determined for the coatings containing v-PDMS and TEOS, on which the scratching was observed after the applied force of 1.5 and 0.6 N in comparison to HDTMS coatings (0.4 N). The resulting properties achieved for the AELO coatings indicated that it has a potential to be used for wood coating and packaging application.

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Acrylated Biopolymers Derived via Epoxidation and Subsequent Acrylation of Vegetable Oils

Cited by 12 publications

References 48 publications

One-Step Method for Direct Acrylation of Vegetable Oils: A Biobased Material for 3D Printing

One-Step Method for Direct Acrylation of Vegetable Oils: A Biobased Material for 3D Printing

Synthesis and application of sustainable vegetable oil-based polymers in 3D printing

Interaction of porous substrate and vegetable oil-based hydrophobic thermoset coatings during UV-polymerization

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