Enhanced Magnetoelectric and Energy Storage Performance of Strain-Modified PVDF-Ba0.7Ca0.3TiO3-Co0.6Zn0.4Fe2O4 Nanocomposites

The experimental development of thin films that exhibit higher room -temperature low -field magnetoelectric (ME) sensing without compromising reliable electrical energy storage capabilities is rare. Here, an improved ferroelectric polarization, ME coupling and energy storage performance of polymer -based nanocomposites, which find applications in portable high -power dielectric capacitors, are studied. Multiferroic nanofiller-based three-phase flexible nanocomposites, polyvinylidene fluoride (PVDF)-(Ba 0.7 Ca 0.3 )TiO 3 -(Co 0.6 Zn 0.4 )Fe 2 O 4 , were fabricated using compression molding to enhance polarization which is pivotal for applications. PVDF with a high beta -phase content (92.4 %), switchable ferroelectric behavior and higher breakdown strength (510 kV/mm) was obtained under optimized process conditions (500 MPa at 165 degrees C). The fabrication assisted alteration of intermolecular chain distance results in a tensile strain (1.42 %) of beta -crystallites corresponding to an internal stress of -21 MPa. The progressive increase of nanofiller content has led to enhanced polarization (11 mu C/cm 2 ), soft ferromagnetic properties, and enhanced ME coupling of 59 mV/cm-Oe due to switchable magnetostriction ( lambda 11 = -18 ppm and d lambda 11 /d = -22 x 10 -9 Oe -1 ) at lower saturation field of 1.2 kOe. The ME sensitivity was found to be more than two -folds enhanced compared to solution -cast films making them prospective self -biased flexible devices for wearable electronics. Simultaneously, enhanced change of magnetization (19.6 %) under electric field was obtained. Detailed energy storage characteristics confirm that the nanofiller inclusion up to 7.12 vol% effectively improved the recoverable energy storage density (21.2 J/cm 3 ) with an efficiency of 67 %. The experimental and simulation results corroborate a significantly improved breakdown strength of 617 kV/mm with reliable performance. Thus, careful processing provides viable polymer dielectrics with beneficial storage characteristics.