Due to the uniqueness and the variation of the ionic radius and oxidation states of the implanted transition metals within nano ferrites structure, The nano ferrites are integrated into many technologies including biomedical application the current study aims to optimize the effect of cerium-dopant on the magnetic behavior and antimicrobial properties of manganese nano ferrites. Cerium-doped manganese nano ferrites are synthesized by chemical co-precipitation method followed by thermal annealing at 500 °C. and investigate the dopant effects on its magnetic behavior and antibacterial properties for biomedical applications. The cubic spinel ferrite is successfully formed and CeO₂ and Fe₂O₃ have appeared as minor phases. The particle size is found to be 20–60 nm. The Ce_0.05Mn_0.95Fe₂O₄ nano ferrite exhibits the highest saturation magnetization of about 20.47 emu/g with 118.22 Oe as coercivity. EPR factors were affected due to crystalline anisotropy that appeared inside the Ce_xMn_X-1Fe₂O₄ spinel ferrites nanomaterials. In comparison to chloramphenicol, cerium nanoparticles exhibited promising inhibitory action against six pathogenic bacteria (Bacillus cereus, Bacillus subtilis, Micrococcus luteus, Escherichia coli, Klebsiella pneumoniae, and Serratia plymuthica). All cerium treatments showed suitable antibacterial activities. However, the treatments of X = 0.000, X = 0.025, and X = 0.050 were the most effective. For Gram-negative bacteria, the best treatment was X = 0.025, while for Gram-positive isolates, the best treatment was X = 0.050 with MIC 5–10 µg/ml. Our finding, open the pathway to integrate cerium doped manganese nano ferrites in biomedical application including against human pathogenic bacteria.

Herein, the presented approach was investigated a unique technique for manufacturing water repellent/UV-protective cotton fabrics through in-situ/thermal polymerization of benzoxazine (BZs) within cotton matrix. Two BZs abbreviated as Ph-p-BZ and Ph-o-BZ were initially synthesized, and their chemical formulas were verified with FTIR, ¹HNMR, and ¹³CNMR spectral mapping data. For Ph-p-BZ, the endothermic peak was observed at 65 ᵒC, to indicate its highly/purified crystalline structure. DSC data for poly-(Ph-p-BZ) and poly-(Ph-o-BZ) showed that, their high Tg was estimated at 210 ᵒC and 195 ᵒC, respectively, due to their highly crystalline/cross-linked network structure. In-situ/thermal polymerization of Ph-p-BZ and Ph-o-BZ as within cotton matrix was subsequently proceeded. Contact angle was observably increased to 125.0° for the fabric coated with four layers of poly-(Ph-p-BZ) (cotton modified with four …

In this work, a new and effective polymeric coating is used to improve mild steel's corrosion resistance. The coating incorporates a Schiff base moiety into a benzoxazine (BZ) precursor, resulting in improved protection against corrosion. The SF-Tol-BZ polymerization behavior and thermal properties were studied using differential scanning calorimetry (DSC) and thermalgravimetric analysis (TGA), respectively, at different curing temperatures. The poly(SF-Tol-BZ) cured at 240 °C had a T_d10 value of 604 °C and a Tg of 225 °C. The efficacy of poly(SF-Tol-BZ) coatings in protecting mild steel (MS) from corrosion in a NaCl (3.5%) solution at room temperature was evaluated using various corrosion measurements, including open circuit potential (OCP), and electrochemical impedance spectroscopy (EIS). The results showed that increasing the poly(SF-Tol-BZ) concentration led to a corresponding increase in its protective …

In this study, we utilized salicylaldehyde (SA) and p-toluidine (Tol-NH₂) to synthesize 2-(Z)[(4-methylphenyl)imino]methylphenol (SA-Tol-SF), which was then reduced to 2-[(4-methylphenyl)amino]methylphenol, producing SA-Tol-NH. SA-Tol-NH was further reacted with formaldehyde to create SA-Tol-BZ monomer. Poly(SA-Tol-BZ) was produced by thermally curing it at 210 °C, after synthesizing it from SA-Tol-BZ. The chemical structure of SA-Tol-BZ was analyzed using various analytical techniques such as FT-IR, ¹H NMR spectroscopy, and ¹³C NMR spectroscopy TGA, SEM, DSC, and X-ray analyses. Afterward, we applied the obtained poly(SA-Tol-BZ) onto mild steel (MS) using thermal curing and spray coating techniques. To examine the anticorrosion attributes of MS coated with poly(SA-Tol-BZ), electrochemical characterization was employed. The study proved that poly(SA-Tol-BZ) coating had a high level of …

Modifying the metal surface is one solution to the industry’s growing corrosion problem. Thus, via threading approach and insertion of copolymers (CoP5-7) containing polyarylidenes through the internal cavity beta-cyclodextrin β-CD, novel pseudopolyrotaxanes copolymers (PC5-7) are developed, resulting in mild steel corrosion inhibition. Inhibitors of corrosion based on β-CD molecules adsorb strongly to metal surfaces because of their many polar groups, adsorption centers, many linkages of side chains, and benzene rings. The corrosion inhibition efficiencies IE % statistics have been revised via the Tafel polarization method and Spectroscopy based on the electrochemical impedance (EIS), with PC7 achieving the highest 99.93% in 1.0 M H₂SO₄; they are mixed-type inhibitors. The chemical composition of the resulting PCs is determined with Fourier transform infrared spectroscopy (FTIR), Scanning electron …

For various optical applications, the fabrication of nanocomposites of co-polyarylidene (cyclohexanone/4-tertiary butyl cyclohexanone) CoP6 with various-sized cadmium sulfide CdS nanoparticles via in situ polymerization has been investigated (CoP6-CdS NCs). Several techniques like FT-IR, XRD, XPS, SEM, TGA, TEM, UV–vis, and fluorescence emission have been used to investigate, characterize, and study nanocomposites' structural and optical characteristics. The optical band gap of NCs was found to have a slight redshift, from 2.81 to 2.71 eV, with no alteration to the absorption peak. The crystallinity and phase formation were studied by XRD, which showed that the produced NCs with larger (CdS) particles retain some crystalline structure. The NCs generated were characterized by SEM and TEM, revealing their aggregation inside the polymer matrix. The thermal stability of the produced nanocomposites …

In this study, 2-[(E)-(hexylimino)methyl] phenol (SA-Hex-SF) was synthesized by adding salicylaldehyde (SA) and n-hexylamine (Hex-NH₂), which was subsequently reduced by sodium borohydride to produce 2-[(hexylamino)methyl] phenol (SA-Hex-NH). Finally, the SA-Hex-NH reacted with formaldehyde to give a benzoxazine monomer (SA-Hex-BZ). Then, the monomer was thermally polymerized at 210 °C to produce the poly(SA-Hex-BZ). The chemical composition of SA-Hex-BZ was examined using FT-IR, ¹H, and ¹³C NMR spectroscopy. Differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), scanning electron microscopy (SEM), and X-ray Diffraction (XRD), respectively, were used to examine the thermal behavior, surface morphology, and crystallinity of the SA-Hex-BZ and its PBZ polymer. Mild steel (MS) was coated by poly(SA-Hex-BZ) which was quickly prepared using spray coating and …

Nowadays growing concerns are rising toward water contamination caused by pharmaceuticals. Consequently, the design of optical sensors for their detection and analysis is extremely essential. In the current work, iron (III) aminoterephthalate-based metal-organic framework (Fe(III)-MOF) was synthesized by two approaches i.e. conventional and ultrasonication without the use of any organic solvents. Calcination of the synthesized Fe(III)-MOFs resulted in formation of different iron oxide phases i.e. magnetite and hematite depending on the calcination conditions. Magnetite NPs obtained from calcination of conventionally prepared MOF were efficiently utilized in the removal of daclatasvir (DAC), a hepatitis C antiviral drug, from water. Adsorption mechanism was investigated, and it was found that electrostatic interaction is the main force governing the adsorption of DAC on the magnetite NPs surface. Moreover, adsorption kinetics was studied, and it was established that adsorption of DAC on magnetite NPs surface follows pseudo-second order kinetics with R² = 0.9970. The removal efficiency reached 99.9% after 220 min while using 5.0 mg/L of DAC. Furthermore, conventionally prepared Fe(III)-MOF showed higher fluorescence signal than ultrasonically-prepared MOF (∼3.0 times). This finding was exploited for utilization of conventionally prepared Fe(III)-MOF as a highly sensitive “turn-off” fluorescent probe for the analysis of nifuroxazide (NIFR) in domestic water. Parameters affecting sensing properties such as pH, solvent type and concentration of Fe(III)-MOF were optimized. The highest fluorescence quenching efficiency of NIFR was achieved while using 50 mg/L of Fe(III)-MOF in pH 9.0. Inner-filter effect was verified experimentally and mathematically to be the principal mechanism of the fluorescence quenching. The developed strategy showed high selectivity and sensitivity towards the analysis of NIFR with limit of detection and quantitation of 8.0 and 25.0 μg/L, respectively. Moreover, the designed sensor was successfully applied for determination of NIFR in domestic water without any interference from other tested antiviral, antidiabetic or antimicrobial drugs.