Crystallization of Poly(vinylidene fluoride) in Blends with Poly(methyl methacrylate‐co‐methacrylic acid) Copolymers

Abstract: A series of poly(methyl methacrylate-co -methacrylic acid) (PMMA-co -MAA) random copolymers ranging in MAA content from 0-15 mol% is synthesized and blended with poly(vinylidene fl uoride) (PVDF). Using infrared spectroscopy, it is observed that the absorption bands attributed to hydrogen-bonded carbonyl groups increase in intensity as the amount of MAA in the copolymer increases. In DSC analysis, the crystallization temperature of the PVDF in the blend initially decreases by ca. 12 °C with MAA contents rangin… Show more

“…In this context, FDSC consequently suggests good miscibility of PMMA-MAA with PVDF in the concentration range 5–10 wt % PMMA-MAA with slight positive influence of PMMA-MAA compared to PMMA for the β-phase production during cooling from the melt state (in particular at representative cooling rate of the extrusion-calendering process). These effects could be attributed to enhanced PVDF/PMMA-MAA interactions inducing higher miscibility with PVDF, in agreement with findings by Landis et al on PVDF crystallization in the presence of tiny amounts of PMMA-MAA …”

“…This demixing phenomenon in shearing conditions induces complex effects on PVDF crystallization (enhanced β-phase crystallization at 5 wt % PMMA-MAA and inhibited β-phase crystallization at 10 wt % PMMA-MAA). Such conclusions could agree with previous conclusions from Landis et al demonstrating that an elevated quantity of MAA moieties could have a negative effect on the resulting compatibility . Finally, differences in molecular weight between PMMA-MAA (37 500 g/mol) and PMMA (97 000 g/mol) with large subsequent differences in melt viscosity and terminal relaxation times could explain this demixing phenomena in intense shear/elongation flows.…”

“…Such conclusions could agree with previous conclusions from Landis et al demonstrating that an elevated quantity of MAA moieties could have a negative effect on the resulting compatibility. 52 Finally, differences in molecular weight between PMMA-MAA (37 500 g/mol) and PMMA (97 000 g/mol) with large subsequent differences in melt viscosity and terminal relaxation times could explain this demixing phenomena in intense shear/elongation flows. Detailled investigations are required in the future to reproduce this phenomenon in a controlled shear/elongation environment to stabilize and control the microstructure and the miscibility extent of PVDF/PMMA-MAA blends (in particular at elevated PMMA-MAA content.…”

“…These effects could be attributed to enhanced PVDF/PMMA-MAA interactions inducing higher miscibility with PVDF, in agreement with findings by Landis et al on PVDF crystallization in the presence of tiny amounts of PMMA-MAA. 52 3.2. β-Phase Crystallization in PVDF/PMMA-MAA Films Produced by Extrusion-Calendering. Taking into account FDSC results, thin films of PVDF/PMMA-MAA (thickness range of 25−35 μm) were produced by melt-state extrusion-calendering process that provide intense cooling rates (±200 °C/s depending on film thickness and materials).…”

Beta Phase Crystallization and Ferro- and Piezoelectric Performances of Melt-Processed Poly(vinylidene difluoride) Blends with Poly(methyl methacrylate) Copolymers Containing Ionizable Moieties

“…In this context, FDSC consequently suggests good miscibility of PMMA-MAA with PVDF in the concentration range 5–10 wt % PMMA-MAA with slight positive influence of PMMA-MAA compared to PMMA for the β-phase production during cooling from the melt state (in particular at representative cooling rate of the extrusion-calendering process). These effects could be attributed to enhanced PVDF/PMMA-MAA interactions inducing higher miscibility with PVDF, in agreement with findings by Landis et al on PVDF crystallization in the presence of tiny amounts of PMMA-MAA …”

“…This demixing phenomenon in shearing conditions induces complex effects on PVDF crystallization (enhanced β-phase crystallization at 5 wt % PMMA-MAA and inhibited β-phase crystallization at 10 wt % PMMA-MAA). Such conclusions could agree with previous conclusions from Landis et al demonstrating that an elevated quantity of MAA moieties could have a negative effect on the resulting compatibility . Finally, differences in molecular weight between PMMA-MAA (37 500 g/mol) and PMMA (97 000 g/mol) with large subsequent differences in melt viscosity and terminal relaxation times could explain this demixing phenomena in intense shear/elongation flows.…”

“…Such conclusions could agree with previous conclusions from Landis et al demonstrating that an elevated quantity of MAA moieties could have a negative effect on the resulting compatibility. 52 Finally, differences in molecular weight between PMMA-MAA (37 500 g/mol) and PMMA (97 000 g/mol) with large subsequent differences in melt viscosity and terminal relaxation times could explain this demixing phenomena in intense shear/elongation flows. Detailled investigations are required in the future to reproduce this phenomenon in a controlled shear/elongation environment to stabilize and control the microstructure and the miscibility extent of PVDF/PMMA-MAA blends (in particular at elevated PMMA-MAA content.…”

“…These effects could be attributed to enhanced PVDF/PMMA-MAA interactions inducing higher miscibility with PVDF, in agreement with findings by Landis et al on PVDF crystallization in the presence of tiny amounts of PMMA-MAA. 52 3.2. β-Phase Crystallization in PVDF/PMMA-MAA Films Produced by Extrusion-Calendering. Taking into account FDSC results, thin films of PVDF/PMMA-MAA (thickness range of 25−35 μm) were produced by melt-state extrusion-calendering process that provide intense cooling rates (±200 °C/s depending on film thickness and materials).…”

Beta Phase Crystallization and Ferro- and Piezoelectric Performances of Melt-Processed Poly(vinylidene difluoride) Blends with Poly(methyl methacrylate) Copolymers Containing Ionizable Moieties

Enhancing released electrical energy density of poly(vinylidene fluoride-co-trifluoroethylene)-graft-poly(methyl methacrylate) via the pre-irradiation method

Compatibilization of poly(vinylidene fluoride)/natural rubber blend by poly(methyl methacrylate) modified natural rubber