Effect of Microwave Cure on the Thermo-Mechanical Properties of Tung Oil-Based/Carbon Nanotube Composites

Abstract: Tung oil is uniquely reactive among plant-based natural oils due to the series of conjugated carbon-carbon double bonds in its fatty acid chains. These conjugated carbon-carbon double bonds impart a high reactivity towards cationic polymerization in the presence of other reactive co-monomers, such as divinylbenzene and styrene. An impressive decrease in the cure time of tung oil-based thermosets has been achieved when the resins investigated were microwaved in the presence of carbon nanotubes (CNTs). However, … Show more

“…F50-T50-F showed a higher storage modulus (540 MPa) than F40-T60-F (340 MPa) and F30-T70-F (60MPa) at room temperature (Table 2). These values are comparable to the reported storage modulus values of other tung oil polymers [2,9,25]. It was difficult to run F30-T70-F samples, as these samples were too brittle to continue in tension mode, and broke above 45 °C.…”

“…The broad range of peaks in the 5.5-6.5 ppm (highlighted with green square shape in Figure 10a) region suggested a conjugated triene structure for TO, which was absent in soluble portions of FMA-TO polymers [32]. The absence of any characteristic peaks of FMA in the 5-6 ppm region confirmed that the predominant TO-related compounds in the soluble portions of FMA-TO polymers might be TO oligomers [2]. A similar conclusion was reached from 13 C spectra of FMA-TO polymers, as the TO-related carbon predominated in the 120-150 ppm and 10-40 ppm regions (highlighted with a green square shape in Figure 10b).…”

“…This helped in development of more cross-linking sites, which consequently led to rigidity in structure as well as brittleness in the materials. This resulted in polymers with low mechanical properties [2,25]. In Figure 7b, F40-T60-F exhibited broad tan δ transition compared to F50-T50-F, which indicated the presence of a heterogeneous polymer network in the system [14].…”

“…In Figure 10a, the proton signals of TO at δ 4.05-4.10 ppm and 4.27-4.31 ppm correspond to glycerol methylene units in TO. The multiplets appearing at δ 5.33-6.59 ppm are attributed to the olefinic protons in TO [2,29]. For FMA, the methylene proton (-CH 2 -OCO-) signal appears as a singlet δ 4.96 ppm, the vinyl and furan-ring protons in the downfield region (δ 6.03-7.05 ppm) and the α-CH 3 protons at δ 1.79 [30].…”

“…Major advantages of this bio-based resource include low cost, availability, renewability and biodegradability. Vegetable oil-derived polymeric materials with good thermomechanical and excellent damping properties will help to replace petroleum-based products in the near future [1,2]. Highly cross-linked thermoset-type materials can be produced from fatty acid unsaturation [1].…”

Synthesis and Properties of Thermosets from Tung Oil and Furfuryl Methacrylate

“…F50-T50-F showed a higher storage modulus (540 MPa) than F40-T60-F (340 MPa) and F30-T70-F (60MPa) at room temperature (Table 2). These values are comparable to the reported storage modulus values of other tung oil polymers [2,9,25]. It was difficult to run F30-T70-F samples, as these samples were too brittle to continue in tension mode, and broke above 45 °C.…”

“…The broad range of peaks in the 5.5-6.5 ppm (highlighted with green square shape in Figure 10a) region suggested a conjugated triene structure for TO, which was absent in soluble portions of FMA-TO polymers [32]. The absence of any characteristic peaks of FMA in the 5-6 ppm region confirmed that the predominant TO-related compounds in the soluble portions of FMA-TO polymers might be TO oligomers [2]. A similar conclusion was reached from 13 C spectra of FMA-TO polymers, as the TO-related carbon predominated in the 120-150 ppm and 10-40 ppm regions (highlighted with a green square shape in Figure 10b).…”

“…This helped in development of more cross-linking sites, which consequently led to rigidity in structure as well as brittleness in the materials. This resulted in polymers with low mechanical properties [2,25]. In Figure 7b, F40-T60-F exhibited broad tan δ transition compared to F50-T50-F, which indicated the presence of a heterogeneous polymer network in the system [14].…”

“…In Figure 10a, the proton signals of TO at δ 4.05-4.10 ppm and 4.27-4.31 ppm correspond to glycerol methylene units in TO. The multiplets appearing at δ 5.33-6.59 ppm are attributed to the olefinic protons in TO [2,29]. For FMA, the methylene proton (-CH 2 -OCO-) signal appears as a singlet δ 4.96 ppm, the vinyl and furan-ring protons in the downfield region (δ 6.03-7.05 ppm) and the α-CH 3 protons at δ 1.79 [30].…”

“…Major advantages of this bio-based resource include low cost, availability, renewability and biodegradability. Vegetable oil-derived polymeric materials with good thermomechanical and excellent damping properties will help to replace petroleum-based products in the near future [1,2]. Highly cross-linked thermoset-type materials can be produced from fatty acid unsaturation [1].…”

Synthesis and Properties of Thermosets from Tung Oil and Furfuryl Methacrylate

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