A flexible poly(vinylidene difluoride) (PVDF) composite film embedding LiNbO 3 ceramics decorated with silver nanoparticles (Ag NPs) has been synthesized using the solvent casting method. The polar β-phase, Ag NPs, and LiNbO 3 phases were confirmed in the composite film using various characterization methods. The composite film showed promising degradation of cationic and anionic dyes using piezocatalysis under ultrasonication. Moreover, this composite film also effectively degraded two model pharmaceutical pollutants named tetracycline and ciprofloxacin using piezocatalysis under ultrasonication. In addition to this, this composite film piezocatalytically removed more than 99.999% of Escherichia coli and 96.65% of Staphylococcus aureus bacteria within 180 min of sonication. The piezocatalytic performance of the PVDF composite film embedding Ag-loaded LiNbO 3 in all three applications was superior to that obtained in the case of the PVDF film embedding LiNbO 3 and the bare PVDF film. This demonstrates the pronounced effect of Ag NPs in the increase of piezocatalytic activity in the composite film.
Multicatalytic activities (photocatalysis, piezocatalysis, and pyrocatalysis) of ferroelectric ceramics Ba0.85Ca0.15Ti0.9Zr0.1O3 (BCZTO) were studied. Maximum degradations (89% and 81%) were achieved in piezo-photocatalytic experiments for degradation of Rhodamine B (RB) and ciprofloxacin. Similarly, 95% degradation of RB was achieved during pyrocatalysis in 250 heating/cooling cycles. Antibacterial performance of ceramics was analyzed with the help of Gram-positive and Gram-negative bacteria-killing processes. The bacterial colony formation drops to zero in 90 min with poled samples of BCZTO ceramics. The poled samples performed much better than that of the unpoled samples in all the catalytic reactions as well as in the bacterial killing process.
The piezocatalytic, photocatalytic, and piezo‐photocatalytic properties of BaZr0.02Ti0.98O3 (BZT) were examined for degradation of organic dyes and killing of bacteria present in the wastewater. Poled and unpoled powder samples were investigated using rhodamine‐B (RB), methyl orange (MO) dyes, and gram‐negative Escherichia coli in simulated water. The poled BZT sample demonstrated significant degradation of RB and MO dyes as compared to the unpoled BZT sample during piezocatalytic, photocatalytic, and piezo‐photocatalytic experiments. Moreover, ultrasonication‐induced piezocatalysis was found to be more effective than stirring in dye degradation using the poled BZT sample. Also, the piezo‐photocatalysis through poled BZT sample (using ultrasonication and ultraviolet (UV) light) was found to be more effective in dye degradation than that of only piezocatalysis and only photocatalysis. During antibacterial testing, the poled BZT sample showed nearly 90% and 100% bacterial killing under UV light and ultrasonication, respectively,, whereas the unpoled BZT sample showed only ~5% and ~35% bacterial killing. The significant enhancement in dye degradation and bacterial killing using the poled sample explicitly indicated the role of internal electric field in multicatalytic activities.
The diesel soot (DS) coated non-woven fabric was studied for oil-water separation along with the adsorption of dyes, detergents, and pharmaceuticals. The DS coated non-woven fabric showed more than 95% separation efficiency and consistent repeatable performance during oil-water separation experiment. In addition to this, the DS coated non-woven fabric of 17.2 cm
2
area successfully adsorbed ~85%, 97%, and 100% methylene blue (MB) dye, ciprofloxacin, and detergent, respectively from their respective solutions within 30 min, which was not possible using uncoated non-woven fabric. The DS coated non-woven fabric was found to be hydrophobic with the contact angle of 140° which was almost invariant upto 60 °C. Hence, the DS coated non-woven fabric showed promising performance in the oil-water separation and adsorption applications.
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