Increased demand for plastics leads to a large amount of plastic manufacturing, which is accompanied by inappropriate disposal of plastics. The by-products of these waste plastics are microplastics (MPs; less than 5 nm in size), which are produced because of various environmental and physicochemical factors, posing hazardous effects to the ecosystem, such as the death of marine organisms due to the swallowing of plastic specks of no nutritional value. Therefore, the collection, preparation, identification, and recycling of these microsized plastics have become imperative. The pretreatment of MPs requires numerous chemical agents comprising strong acids, bases, and oxidizing agents. However, there is limited research on the chemical resistance of various MPs to these substances to date. In this study, the chemical resistance of five species of MPs (high-density polyethylene, low-density polyethylene, polystyrene, polyethylene terephthalate, and polypropylene) to sulfuric acid, hydrochloric acid, hydrogen peroxide, potassium hydroxide, and sodium hydroxide was studied. The MPs were reacted with these chemical reagents at preset temperatures and durations, and variations in morphology and chemical structures were detected when the MPs were reacted with mineral acids, such as sulfuric acid. The data pertaining to these changes in MP properties could be a significant reference for future studies on MP pretreatment with strong acids, bases, and oxidizing agents.
Graphene-based
fiber-shaped supercapacitors (FSSCs) have received
considerable attention as potential wearable energy storage devices
owing to their simple operating mechanism, flexibility, and long-term
stability. To date, energy storage capacities of supercapacitors have
been significantly improved via strategies such as heteroatom doping
and the incorporation of pseudocapacitive metal oxides. Herein, we
develop a novel and scalable direct-hybridization method that combines
heteroatom doping and metal oxide hybridization for the fabrication
of high-performance FSSCs. Using porous and highly conductive nitrogen
and sulfur co-doped graphene fibers (NS-GFs) as self-heating units,
we successfully convert ruthenium hydroxide anchored to the surface
into ruthenium oxide nanoparticles after programmed sub-second electrothermal
annealing without structural damage of the fibers. The resulting fibers
show an increased gravimetric capacitance of 68.88 F g–1 compared to that of the pristine NS-GF (8.32 F g–1), excellent cyclic stability maintaining 96.67% of the initial capacitance
after 20 000 continuous charging/discharging cycles, and good
mechanical flexibility. The findings of this work advocate a successful
Joule heating strategy for preparing high-performance graphene-based
metal oxide hybrid FSSCs for use in energy storage applications.
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