Abstract
In this work, high oleic soybean oil was used to synthesize an acrylic monomer (HOSBM), which was copolymerized with myrcene and styrene at a 90:10 wt/wt feed ratio to obtain copolymers containing myrcene (HOSBM-M) and styrene (HOSBM-S). These copolymers were employed here as macromolecular plasticizers to modify the brittle nature of polystyrene (PS). Specifically, the soy-based copolymers were added to commodity polystyrene at 5-20 wt %, and the copolymer effect on the polymer blends’ structure and behavior was studied. We report on the blends’ morphology and thermal/mechanical properties and employ thermodynamic and mechanical models to understand the interactions between the PS matrix and the HOSBM copolymer dispersed phase. Microscopy indicated that the mixed materials have a phase-separated structure composed of the PS-based matrix and the copolymer-based dispersed phase. Our thermodynamic estimations and measurement of the thermal transitions showed that the blends are partially miscible, where a fraction of PS chains migrated into the dispersed phase and the copolymer was partially situated in the PS matrix. Therefore, HOSBM-M and HOSBM-S plasticize the PS matrix, decreasing the glass transition temperature and moduli. The mechanical properties of the blends depicted a trade-off between the flexural modulus, strength, and toughness. Although the PS/HOSBM-S blends showed decreased storage/flexural moduli and strength compared to neat PS, the decline was significantly lower than that demonstrated by the HOSBM-M blends. Moreover, adding the HOSBM-S copolymer to PS at 10-15 wt % loading enhances the material’s extensibility compared to pure PS. The trend in the toughness values shows that the optimal HOSBM-S loading is 10 wt % to obtain materials with the best middle ground between flexural modulus, strength, extensibility, and toughness.
Original language | English |
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Pages (from-to) | 2474-2486 |
Number of pages | 13 |
Journal | ACS Applied Polymer Materials |
Volume | 6 |
Issue number | 5 |
DOIs | |
State | Published - Mar 8 2024 |
Externally published | Yes |
Funding
The research reported was partially supported by the National Science Foundation via EPSCoR OIA-1655740. The authors gratefully acknowledge Kimberly Ivey and George Wetzel (Clemson University) for their help and advice.
Funders | Funder number |
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National Science Foundation | OIA-1655740 |
Keywords
- biobased polymers
- bioderived plasticizer
- high oleic soybean oil monomer
- interfacial adhesion
- polymer blends