Impact Modification and Fracture Mechanisms of Core–Shell Particle Reinforced Thermoplastic Protein

2017

Adv Polym Technol

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Novatein thermoplastic protein was blended with modified polyethylene (containing either epoxy, carboxylic acid functionalities partially neutralised to produce zinc carboxylate salts, or maleic anhydride functionalities) to alter blend morphology and to manipulate thermal and mechanical properties. Up to 40 pph Novatein polyethylene (PE) was blended with Novatein by extrusion and injection moulding. Using zinc ionomer resulted in optimal properties and was compatible with a finely dispersed morphology at high content; high interfacial tension (σ) and a viscosity ratio (λ) of ~1 was observed. Unmodified blends and those containing epoxy functionalities showed co-continuity at low PE content. Whilst co-continuity appeared to increase impact resistance, other mechanical properties decreased due to lack of phase interaction. Maleic anhydride-grafted-polyethylene blends showed a finely dispersed PE phase, yet was less compatible. Zinc ionomer was deemed to be the most appropriate for modification of mechanical properties in Novatein. K E Y W O R D Sbiopolymers, blends, morphology, thermoplastic protein How to cite this article: Smith MJ, Verbeek CJR. The relationship between morphology development and mechanical properties in thermoplastic protein blends.

Section: Mechanical Propertiesmentioning

confidence: 93%

The relationship between morphology development and mechanical properties in thermoplastic protein blends

2017

Adv Polym Technol

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“…[13] Similarly, increased glycerol plasticizer content in TPS increased the impact resistance of TPS/polycaprolactone blends, albeit that the mechanism of modification is different to when relying on morphology. In a previous study, [2] using core-shell reinforced Novatein, the critical matrix ligament thickness was achieved at a particle content of 20 wt%, after which significant improvements were observed. [15] For example, the inclusion of 20-30 wt% PBAT in a PLA matrix caused the impact strength to double compared to neat PLA, and triple when epoxy functionalized compatibilizer was added.…”

Section: Introductionmentioning

confidence: 90%

“…However, it is known that for Novatein reinforced with elastomeric core-shell particles, the critical reinforcement level needed for improvement in energy absorption was ~15-20 wt%, [2] while in reactive Novatein/polyethylene blends, this point was >20 wt% for some blends. However, it is known that for Novatein reinforced with elastomeric core-shell particles, the critical reinforcement level needed for improvement in energy absorption was ~15-20 wt%, [2] while in reactive Novatein/polyethylene blends, this point was >20 wt% for some blends.…”

Section: Mechanical Propertiesmentioning

confidence: 99%

Manipulating morphology in thermoplastic protein/polyester blends for improved impact strength

2017

Adv Polym Technol

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Novatein thermoplastic protein was blended with 10 wt% poly(butylene adipate-coterephthalate) (PBAT) compatibilized with Joncryl ADR-4368 and 2-methylimidazole (2MI). Morphology was tailored for favorable impact strength through changing viscosity ratio (λ) and interfacial tension (γ 12 ). For uncompatibilized blends, λ decreased and γ 12 increased with increasing Novatein water content, whereas compatibilizers caused a decrease in both λ and γ 12 . PBAT continuity was high when uncompatibilized, but dispersion improved with decreasing λ and increasing γ 12 . The dispersed domain size decreased in all compatibilized blends; PBAT continuity was lowest in samples with the smallest λ. Compatibilized blends had higher impact strength than Novatein and uncompatibilized blends through improved interfacial adhesion, smaller domain size, and increased dispersion. By altering λ and γ 12 , and with appropriate chemical interaction, a morphology can be created for improved impact strength. Increasing PBAT content showed further increases in impact strength; however, a cocontinuous morphology formed, demonstrating that composition can override the effect of λ and γ 12 . K E Y W O R D Sblends, impact resistance, morphology development, polyester, thermoplastic protein

“…Novatein thermoplastic protein, a biodegradable polymer produced from bloodmeal , has poor energy absorbing properties depending on plasticizer content and protein denaturant levels. The injection molding grade of Novatein shows high tensile strength and modulus but has low strain at break and impact strength . In comparison, increased plasticizer and protein denaturant content brings about better energy absorbing properties in Novatein, but a reduction in strength and modulus are observed .…”

Section: Introductionmentioning

confidence: 98%

“…The addition of an elastomeric polymer into a rigid matrix, either through blending or the incorporation of synthesized particles are common techniques for improving energy absorption . Impact modification of Novatein has been achieved in a number of ways; nano‐scale core‐shell particles with an elastomeric core and rigid shell were shown to improve the unnotched impact strength by an order of magnitude . Similarly, reactively blending high contents (∼40 wt%) of modified polyethylene (PE) with Novatein, doubled the elongation at break and increased impact strength by ∼350%, while decreasing tensile strength by less than 25% .…”

Section: Introductionmentioning

confidence: 99%

Structural changes and energy absorption mechanisms during fracture of thermoplastic protein blends using synchrotron FTIR

Polymer Engineering & Sci

2017

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Novatein thermoplastic protein embrittles quickly after processing due to desorption of plasticizer, leading to poor energy absorbing properties such as impact strength. However, impact modified Novatein blends, containing functionalized polyethylene or nano‐scale core‐shell particles exhibit increased energy absorbing properties. The phase distribution of reinforced blends, and the protein secondary structure changes as a result of blending and fracture was investigated using synchrotron FT‐IR microspectroscopy. Morphological changes in Novatein/polyethylene blends were responsible for variations in mechanical properties, rather than changes in secondary structure. In contrast, a greater impact strength was correlated to an increase of disordered secondary structures in core‐shell particle reinforced Novatein. Blends which exhibited greater elongation or yielding during fracture showed a significant difference between protein secondary structure in the bulk matrix and the yielded material after fracture. It was concluded that the change in conformation of protein structures during fracture is an energy absorbing mechanism that acts in conjunction with the free elongation of the matrix due to decreasing interparticle distance for materials reinforced with nano‐particles. POLYM. ENG. SCI., 58:E124–E134, 2018. © 2017 Society of Plastics Engineers