Optical and electrical properties of copper alumina nanoparticles reinforced chlorinated polyethylene composites for optoelectronic devices

“…The direct and indirect values gradually rise by around 15% when only 1.5 wt% of FeVO 4 NPs are added to the PU/PMMA bent, as shown in Table 1. The growth of the electron‐donor nature and polymer backbone conjugation, as well as the splitting of the valence and conduction bands, are credited with this expansion of the optical energy gap 32 …”

“…The growth of the electron-donor nature and polymer backbone conjugation, as well as the splitting of the valence and conduction bands, are credited with this expansion of the optical energy gap. 32 The tail energy of Urbach E u analyzes how many localized states and the faults there are in the restricted bandgap and it can be calculated as follows:…”

Comparative analysis of the structural, optical, mechanical, and electrical properties of PMMA/PU blend‐based nanocomposites with FeVO₄ nanofiller for energy storage devices

“…The direct and indirect values gradually rise by around 15% when only 1.5 wt% of FeVO 4 NPs are added to the PU/PMMA bent, as shown in Table 1. The growth of the electron‐donor nature and polymer backbone conjugation, as well as the splitting of the valence and conduction bands, are credited with this expansion of the optical energy gap 32 …”

“…The growth of the electron-donor nature and polymer backbone conjugation, as well as the splitting of the valence and conduction bands, are credited with this expansion of the optical energy gap. 32 The tail energy of Urbach E u analyzes how many localized states and the faults there are in the restricted bandgap and it can be calculated as follows:…”

Comparative analysis of the structural, optical, mechanical, and electrical properties of PMMA/PU blend‐based nanocomposites with FeVO₄ nanofiller for energy storage devices

“…In this study, a poly(vinyl chloride) homopolymer with a K value range of 65.7-67.1 and a degree of polymerization of 1050-30 was used. According to the manufacturer's datasheet, the polymer had a bulk density of approximately 0.55 g/cm 3 with a precision of 0.02 g/cm 3 . TCI supplied the plasticizer, Bis(2-Ethylhexyl)phthalate (DEHP) (>98.0%).…”

“…TCI supplied the plasticizer, Bis(2-Ethylhexyl)phthalate (DEHP) (>98.0%). Merck provided uncoated precipitated calcium carbonate (CC) (98%) with particle sizes 50 μm and a density of 2.83 g/cm 3 . We purchased calcium stearate (>98%) from CDH.…”

“…The compatibility of PVC with numerous additives makes it an extremely versatile polymer even for making nanocomposites. [1][2][3] Specific improvements mechanical or physical attributes can be achieved by the addition of fillers in reasonable proportions. Specific inorganic fillers, such as calcium carbonate, talc, mica, and others, can be added to polymers to increase their thermal stability while also offering composite materials with better resistance to wear, hardness, and stiffness at a cheaper material costs.…”

Exploring the synergistic effect of inorganic and organic particulates in polyvinyl chloride composites through comparative analysis and accelerated weathering

Synthesis, Characterization, Conductivity and Gas Sensing Application of Poly(diphenylamine)/Nickel Oxide Nanocomposites