PXRD Analysis Research Articles

Pea Pod–Derived Biochar–Zeolitic Imidazolate Framework Composite for the Photocatalytic Degradation of Two Organic Dyes Crystal Violet and Victoria Blue

ABSTRACTThe rapid increase of water pollution globally is a vital environmental concern that requires the immediate attention of researchers to find new innovative ways to remove unwanted environmental pollutants from our water sources. With the advances in the field of sustainable engineering, there is a high demand for the effective utilization of biomass resources for the removal of aqueous environmental contaminants. Biochar is carbon carbon‐enriched substance obtained by biomass pyrolysis; it is inexpensive and has received wide attention in the field of wastewater treatment. Herein, we describe the synthesis of pea pod (PO) biochar‐reinforced zeolitic imidazolate framework (ZIF‐8) nanocomposite (PO@ZIF‐8) through the in situ precipitation of ZIF‐8 onto the biochar surface. The crystal growth, morphology, chemical composition, and optical characteristics of fabricated PO@ZIF‐8 nanocomposite were scrutinized through PXRD, SEM, TEM, UV‐DRS, PL, and XPS analysis. The dodecahedral‐shaped PO@ZIF‐8 particles have an average size between 140 and 160 nm. The biochar‐reinforced ZIF‐8 nanocomposite showed significantly higher photocatalytic activity than the pure ZIF‐8 for the degradation of two commonly found organic dyes crystal violet (CV) and Victoria Blue (VB) in the presence of direct sunlight irradiation. The PO@ZIF‐8 nanocomposite showed the highest degradation efficiency of ~87% and ~80% within 50 min of irradiation time at a catalyst dosage of 20 mg for 30 ppm CV and VB dye solutions at pH 8. First‐order kinetics were obeyed during the photodegradation with 0.041 and 0.030 min−1 as the constant of degradation for the removal of CV and VB. The radical scavenger experiment and the photoluminescence analysis confirm the active participation of ·OH radical in the degradation of both dyes. LC–MS and TOC analysis was also performed to determine the degradation products and for evaluation of the degradation progress. Moreover, the synthesized PO@ZIF‐8 composite also exhibit good stability till the fourth cycle with high degradation efficiency thus making it a good choice of catalyst in the field of environmental decontamination.

MoS2 nanosheet assisted poly vinyl alcohol cross-linked with carboxylated acryl-amido-2-methyl-1-propanesulfonic acid in medium temperature proton exchange membrane fuel cell application

ABSTRACT Initially, the carboxylated-acryl amido propane sulfonic acid (C-AMPSA) was synthesized through the thiol-ene reaction using 2-acrylamido-2-methylpropane sulfonic acid and 3-mercapto propane sulfonic acid monomers. The C-AMPSA was cross-linked with polyvinyl alcohol to create a non-perfluorinated membranes were of these acid group-containing monomers. Using a cross-linking technique, a poly vinyl alcohol cross-linked C-AMPSA (PVA-C-AMPSA) polymer was prepared. Following that, the MoS2 nanosheets (NSs) were synthesized through the one-pot hydrothermal method, and their phase purity, functionality, and morphology were evaluated by p-XRD, FT-IR, and FE-SEM analyses. These nanosheets were then incorporated into PVA-C-AMPSA polymer nanocomposite membranes at various concentrations (0%, 1%, 2%, 3%, and 5% by weight). In addition, the physicochemical properties of bare and MoS2 nanosheets incorporated PVA-C-AMPSA polymer nanocomposite membranes were assessed, including water uptake, swelling ratio, and ion-exchange capacity. Remarkably, the membrane with 5% of MoS2 NSs in PVA-C-AMPSA displayed an ion-exchange capacity of 1.13 mmol g−1 and a proton conduction of 1.8 × 10−3 S cm−1 at 110°C. The Arrhenius plot indicated that the proton transport was involved in both Grotthuss and vehicular mechanisms. In the fuel cell testing, the PVA-C-AMPSA polymer nanocomposite membrane containing MoS2 NSs demonstrated superior performance, achieving a peak power density (PD) exceeding 0.7 W cm−2 and an open-circuit voltage (OCV) surpassing 0.93 V at 110°C. In contrast, the pure PVA-C-AMPSA membrane exhibited a peak PD of over 0.4 W cm−2 and an OCV of around 0.6 V at the same temperature. Additionally, the 5% of MoS2 NSs incorporated PVA-C-AMPSA polymer nanocomposite membrane exhibited outstanding oxidative stability with 87.7% of degradation when exhibited to a Fenton reagent at 80°C for 8 h.

Superior proton conductivity of amino acid-modified UiO-66-(COOH)2 embedded in chitosan: Mechanistic insights into the acid-base interactions

We focus on optimizing acid-base interactions and hydrogen bonding networks to achieve enhanced proton conductivity under low relative humidity (RH) and high temperature. By functionalizing UiO-66-(COOH)2 with glutamic acid (Glu) and lysine (Lys), we generate Glu-UiO-66-(COOH)2 and Lys-UiO-66-(COOH)2. These modified materials are subsequently incorporated into chitosan (CS) to produce the composites Glu-UiO-66-(COOH)2@CS and Lys-UiO-66-(COOH)2@CS. The successful incorporation of amino acids and cross-linking between -COOH and -NH2 groups in the composites, confirmed by FTIR and PXRD analyses, significantly enhances the structural integrity and durability by strengthening the network, and reducing polymer chain mobility. Proton conductivity assessments reveal that Lys-UiO-66-(COOH)2@CS-7 exhibits a remarkable conductivity of 0.022 S/cm at 100 % RH and 363 K, outperforming Glu-UiO-66-(COOH)2@CS-7. The lower activation energy (Ea) of 0.28 eV for Lys-UiO-66-(COOH)2@CS-7, compared to 0.336 eV for Glu-UiO-66-(COOH)2@CS-7, highlights the significant improvement in intramolecular acid-base interactions and hydrogen bonding. Furthermore, Lys-UiO-66-(COOH)2@CS-7 maintains notable proton conductivity at 43 % RH, with an Ea of 0.216 eV, demonstrating its efficacy in low-humidity conditions. These findings underscore the profound impact of amino acid modifications and cross-linking on proton conductivity by reinforcing acid-base interactions, hydrogen bonding networks, and proton transfer efficiency.

Biosynthesis of cobalt oxide nanoparticles and their cytotoxicity against cancer cells mouse colon adenocarcinoma cell line

The application of plant extracts for the biosynthesis of cobalt oxide nanoparticles is eco-friendly, more economical, less toxic, and more biocompatible. In this study, we used Rose hip extract to synthesize cobalt oxide nanoparticles (Co3O4 NPs). The biosynthesized cobalt oxide nanoparticles were characterized by FT-IR spectroscopy, X-ray diffraction (XRD), and scanning electron microscopy (SEM). The PXRD and FTIR analyses confirmed the successful synthesis and the characteristic bands of Co3O4 NPs, respectively. The FESEM image showed that the Co3O4 NPs were approximately spherical morphology with a mean size of 90.77 ± 32.35 nm. The EDX analysis showed the elemental composition contains carbon in the formulation of Co3O4 NPs. The results showed that the plant extracts can be used to synthesiz cobalt oxide nanoparticles with good quality at nanoscale sizes. The as-prepared Co3O4 NPs exhibited excellent cell toxicity properties against mouse colon adenocarcinoma cells, indicating that biosynthesized cobalt oxide nanoparticles have potential applications in cancer and nanomedicine.

Reaction-assisted MOF manipulation for synthesis of UIO-66-NHCHO topology for prodrug fabrication: pH-responsive targeted drug delivery

A pH-responsive metal-organic framework (MOF)-based prodrug was synthesized via a premeditated formic acid-assisted amide reaction to form the UiO-66-NHCHO topology from UiO-66-NH2. This topology can be covalently attached to the methotrexate drug (MTX) to form theUiO-66-NH-HCN-MTX prodrug. The pristine MOF, UiO-66-NHCHO, and prodrug were characterized using PXRD, FT-IR, FE-SEM, BET, TGA, and NMR analyses. The solid-state NMR and FT-IR confirmed UiO-66-NHCHO topology.The loading efficiency and capacity of the prodrug were 88.96 % and 100.07 mg/g, respectively. These values were 12.90 % and 13.25 mg/g higher than those of the MTX-loaded MOF. This confirms the role of bonding in prodrug synthesis, beyond merely loading MTX through drug adsorption. At low pH the applied prodrug was activated due to CN cleavage. By decreasing pH from 7.4 to 5.5, imitating a tumor environment, the cumulative release of MTX increased by 64.94 %. This release rate was reached by 550 min, which was 230 min longer than the maximum MTX release from the loaded MOF. Such a premeditated delay can effectively suppress the burst release of MTX. At both pH levels, the Higuchi release kinetic model fit the release data better than other models, demonstrating that diffusion through the MOF pores controls drug delivery.

Preparation of two new chiral metal-organic frameworks for lipase immobilization and their use as biocatalysis in the enantioselective hydrolysis of racemic naproxen methyl ester

Considering the selective pharmacological activity of chiral drugs, it is important to develop new chiral materials to synthesize them. In this work, two new chiral MOFs (UiO-66@Np and UiO-66@Ib) were prepared by the covalent attachment of the chiral compounds (S-naproxen and S-ibuprofen) to the amine-functionalized Zr-MOF (UiO-66-NH2). Then, Candida rugosa lipase (CRL) was immobilized on these chiral MOFs to fabricate two new biocomposites (UiO-66@Np@CRL and UiO-66@Ib@CRL) as effective biocatalysts, which enable significant enhancement in the catalytic activity and enantioselectivity of lipase. The FTIR, SEM, EDX, TGA, and PXRD analyses were carried out to confirm the formation of the biocomposites. The catalytic performances of the biocomposites (UiO-66@Np@CRL and UiO-66@Ib@CRL) were evaluated in the typical hydrolysis of p-nitro-phenyl palmitate (p-NPP) and the catalytic enantioselective hydrolysis of (R,S)-naproxen methyl ester. Under optimal conditions, UiO-66@Np@CRL showed a higher enantiomeric excess of the substrate (ees) value and a 98 % and 50 % conversion rate, respectively, than that of UiO-66@Ib@CRL. Besides, an excellent enantioselectivity (E) value of 458 was obtained in the presence of the biocomposite (UiO-66@Np@CRL). In addition, it was observed that the catalytic activity, conversion rate and ees value of this composite (UiO-66@Np@CRL) remained almost unchanged in reuse after 6 months. The results showed that in enantioselective reactions, the highest conversion and enantioselectivity could be achieved when the chiral compound bound to the MOF and the model compound used are the same.

A 2D open framework zinc phosphate and its high proton conductance properties at medium and low temperature

A 2D open-framework zinc phosphate [C3N2H12][Zn2(HPO4)3] (1) was synthesized by solvothermal method. The inorganic anion layer is constructed from Zn2P2O12 cluster units and the interlayer spaces are filled by the diprotonated DAP molecules. The resultant compound had high purity and thermal stability by PXRD and TG analysis. This compound exhibited strongly temperature and humidity dependent proton conductivity, and its highest proton conductivity achieves 2.36 × 10−2 S.cm−1 at 100 %RH and 333 K. Moreover, the important effect of the dense hydrogen bond network in elevating the proton conductivity was explored through comparing the structure and proton conduction behavior between 1 and [C3N2H12][Zn(HPO4)2] (2), which synthesized via the same hydrothermal reaction process, and only a slight difference in the amount of DAP.

Synthesis, characterization, antibacterial, antioxidant and molecular docking studies of Zn(II) complexes with imine quinoline derivative ligand

The efficacy of metal complexes with bioactive ligands for pharmaceutical purposes is increasingly gaining clinical and commercial importance for treating infectious diseases. This research aimed to synthesize new Zn(II) complexes, assess their potential applications in antibacterial and antioxidant properties, and explore their molecular docking properties. The synthesis was done by condensing 7-chloro-2-hydroxyquinoline-3-carbaldehyde and 2,2′-thiodianiline with Zn(II) metal complexes. A range of spectroscopic techniques, such as 1H and 13C NMR, FTIR, TG/DTA, pXRD, and UV–Vis, were employed to characterize both the ligand and its complexes. Imine quinoline ligand (L), ZnL, and ZnL2 all had average crystallite diameters of 13.28, 21.19, and 16.26 nm, respectively, according to pXRD analysis, which confirmed that the synthesized ligand and its Zn(II) complexes showed polycrystalline properties. Based on the results, an octahedral geometry was proposed for the complexes. A very good agreement was obtained between the experimental and the TD-DFT calculated absorption peaks. Their biological potency against Gram-positive (Staphylococcus aureus ATCC 25926) and Gram-negative (Escherichia coli ATCC 25922 and Pseudomonas aeruginosa ATCC 248) bacterial strains as well as antioxidant properties were tested. The ZnL complex showed a maximum growth inhibition of 9.50 ± 0.41 mm against S. aureus ATCC 25926; whereas the maximum growth inhibition of the ZnL2 complex was 9.67 ± 0.47 mm and 9.33 ± 0.47 mm against ATCC 25926, respectively. With an IC50 of 167.3 ± 1.04 mg/mL, ZnL had the strongest antioxidant activity against DPPH radicals. All the complexes had strong binding affinities according to the molecular docking investigation: L (−11.31 kcal/mol), ZnL (−11.38 kcal/mol), and ZnL2 (−13.51 kcal/mol) against the active sites of S. aureus and (−7.92, −8.07, and −8.92) kcal/mol, respectively, against the active sites of E. coli. The Zn(II) complexes had the highest potency of biological activity.

Minting Progress: Multifunctional Bismuth Oxide Nanoparticles via Mentha arvensis extract for Biomedical Advancements

AbstractTo surpass the constraints associated with conventional therapeutic methods in clinical therapy, nanoparticles have been rapidly prepared and developed as a separate treatment method for diseases. In this study, we have synthesized bismuth oxide nanoparticles (BiNPs) using aqueous leaf extract of Mentha arvensis (M. arvensis) as a biogenic approach. The formation of BiNPs was confirmed by the characteristic peak observed at 276 nm in the UV–vis spectrum and PXRD analysis exhibited the crystalline nature with monoclinic phase. The TEM images revealed the quasi‐spherical shape of BiNPs with an average particle size of 12 nm. For biomedical studies, BiNPs exhibited significant cytotoxicity against A431 cell line (lung cancer) with IC50 value of 92.45 µg/mL. Further studies revealed significantly higher apoptosis, antibacterial, anti‐inflammatory, antidiabetic, and antioxidant activities of the biosynthesized BiNPs. The collective results from the study suggest that the M. arvensis mediated synthesis of multifunctional BiNPs enhances their biological potential, positioning it as a potential candidate for the multimodal therapeutic applications.

Synthesis of Pyrrolo [2,1-a]isoquinolines using Cu NPs decorated microcrystalline cellulose in 2-Methyl-THF: A biodegradable heteregeneous nanocatalyst for the sustainable cascade approach

Copper nanoparticles (Cu NPs) supported on microcrystalline cellulose (MCC) serve as an efficient and biodegradable heterogeneous nanocatalyst for the synthesis of pyrrolo [1,2a] isoquinoline under mild and sustainable reaction conditions through a cascade reaction involving condensation, addition, oxidation, and cyclization events. The catalyst underwent thorough characterization via various techniques, including FT-IR, PXRD, XPS, FE-SEM, EDX, TEM, and HR-TEM analysis. Optimized reaction conditions facilitated high-yield production of a diverse range of pyrrolo [1,2a] isoquinolines in 2-Me THF solvent, and the method demonstrated scalability with successful gram-scale synthesis. Notably, the catalyst exhibited reusability for up to five cycles without a significant decrease in activity. This approach aligns with eco-friendly principles, as evidenced by favorable green chemistry metrics for compound 4a, including low process mass intensity (7.83), a minimal environmental impact factor (6.83), a substantial atom economy (67.56 %), efficient reaction mass efficiency (60.76 %), high chemical yield (92.37 %), low mass intensity (1.64), notable mass productivity (60.97 %), considerable carbon efficiency (69.15 %), and optimum efficiency (89.93 %). These results highlight the sustainable and environmentally conscious nature of the developed synthetic methodology.

Exploring the structure and dynamics of soft and hard cuticle of Bombyx mori using solid-state NMR techniques

This study conducts a comprehensive analysis and comparison of Bombyx mori cuticles across different developmental stages, ranging from larval to adult, utilizing advanced solid-state NMR techniques. The primary objective is to elucidate the underlying reasons for the contrasting hardness of adult cuticles and softness of larval cuticles. Notably, PXRD analysis reveals a prominent broad peak at 19.34°, indicating the predominantly amorphous nature of both larval and adult cuticles. Analysis of 13C CP-MAS SSNMR spectra highlights an elevated proportion of phenoxy carbon in adult cuticles (6.77%) compared to larval cuticles (1.24%). Furthermore, a distinctive resonance line at 144 ppm is exclusively observed in adult cuticles, due to catechols, suggesting potential biochemical pathway variations during development. Significant variations in the primary components of 13C chemical shift anisotropy (CSA) tensors for aliphatic carbons of amino acids, catechols, and lipids between adult and larval cuticles indicate alterations in electronic environments. Additionally, the shorter spin–lattice relaxation time of carbon nuclei in larval cuticles compared to adult cuticles implies slower motional dynamics with enhanced degree of sclerotization in adults. By investigating the internal structure and dynamics of cuticles, this research not only contributes to biomimetic material development but also enhances our understanding of structural changes across different developmental stages of B. mori.

Integrating strategy to investigate the formation and stabilization mechanisms of Curcumin-Cyclodextrin inclusion complexes: experimental characterizations and multi-scale computational simulations.

The Cyclodextrin (CD) encapsulation technology can significantly enhance the water solubility of Curcumin (CUR) and effectively protect it against chemical degradations. In the current study, a combination of experimental and multi-scale computational approaches was used to investigate the binding mechanism between CUR and β-CDs (β-CD, 2-HP-β-CD, Me-β-CD, and DM-β-CD). Phase solubility studies showed that β-CDs exhibited a strong binding affinity with CUR and significantly enhanced its solubility. SEM, PXRD, DSC, and TG analysis confirmed the formation of inclusion complexes, resulting in the transition of CUR from crystalline to an amorphous state. FTIR, 1H, and 13CNMR spectra deduced that CUR may have multiple binding conformations with β-CDs. The rationality of molecular dynamics simulation systems was confirmed by comparing the simulated IR spectrum from quantum mechanics with the experimental IR spectrum. MM-PBSA and umbrella sampling simulation calculated the binding free energy of the CUR/CD inclusion complexes, ranking Me-β-CD > DM-β-CD > 2-HP-β-CD > β-CD, and clarified that van der Waals interaction played a major role in stabilizing the inclusion complexes. RDF analysis confirmed that the release of high-energy water molecules drove the formation of the CUR/CD inclusion complex, and the β-CD substituents affected their exterior hydration layer. Additionally, principal component analysis (PCA) and non-covalent interaction analysis revealed three CUR/CD binding modes: bead-on-string, terminal insertion, and V-shaped-folding. The research strategy adopted here can serve as a paradigm for investigating the encapsulation mechanism of poorly soluble drugs with CDs.

Lanthanide MOF-based luminescent sensor array for detection and identification of contaminants in water and biomarkers

In today's society, heavy metal ions and antibiotic contaminants have caused great harm to water systems and human health. In this study, six isostructural lanthanide metal-organic frameworks [Ln(H3imda)2(TPA)(H2O)2](Tb for CUST-881, Eu for CUST-882, Dy for CUST-883, Er for CUST-884, Nd for CUST-885, Sm for CUST-886) were constructed by selecting terephthalic acid (TPA) and 4,5-Imidazoledicarboxylic acid (H3imda) and lanthanide metal ions via solvethermal method. Among them, CUST-881 and CUST-882 can selectively detect Fe3+, Cr2O72−, CrO42, and ceftriaxone sodium (CRO) in water systems and uric acid in urine. CUST-881 shows very low detection limits for these five substances. Furthermore, Principal Component Analysis (PCA) was used to distinguish Fe3+, Cr2O72−, CrO42−, and CRO in water. To our knowledge, this is the first time that they have been able to be simultaneously distinguished. In addition, the possible sensing mechanism was studied through UV–visible spectroscopy, Infrared spectroscopy, and PXRD analysis. Furthermore, the probe also showed satisfactory repeatability and recovery when applied to UA samples that simulated urine. Based on the above results, lanthanide metal-organic frameworks have great potential for practical monitoring of contaminants in water environments.

Design and development of Fujicalin-based axitinib liquisolid compacts for improved dissolution and bioavailability to treat renal cell carcinoma

Poor dissolution of axitinib (AXT) limits its effectiveness through the oral route. The present study investigated, prospective of liquisolid (LS) technology to improve dissolution rate and oral bioavailability of AXT to treat renal cell carcinoma. LS compacts were fabricated with PEG 200, Fujicalin SG, and Aerosil 200 as solvent, carrier, and coat material, respectively. The behavior of LS-systems during tabletting was investigated using Kawakita, Heckel, and Leuenberger analysis. LS compacts were examined for P-XRD, DSC, SEM, and in vitro drug dissolution. For optimization, a 32 full factorial design was utilized. Cell line A498 was utilized for in vitro cytotoxicity study. A bioavailability study was performed using rabbits. DSC and P-XRD analysis confirmed the transition of crystalline AXT to its partial amorphization and molecular dispersion. Consequently, LS6 demonstrated a significantly rapid drug dissolution (Q20; >99 %) than the directly compressed tablets (18.05 %). Additionally, 2.03-fold increase in oral bioavailability, and inhibited dose-dependent cell growth with 1.75-fold increased apoptosis rate. Overall, an LS6 compact consisting of 15 % AXT concentration in PEG 200 and a 20 w/w ratio of Fujicalin SG: Aerosil 200 exhibited improved formulation properties, enhanced dissolution rate, and bioavailability. Thus developed potential product may contribute low-cost production with patient-improved survival expectations.

Design, Synthesis, and Characterization of Polyoxotungstate-Decorated Ionic Liquid-Based Hybrid Material, [BmIm]4[SiW12O40] toward Rapid Adsorption of Dye and Antibacterial Activities.

A multifunctional polyoxometalate-ionic liquid (POM-IL)-based hybrid material comprising silicotungstic acid, [BmIm]4[SiW12O40], has been synthesized and demonstrated its efficiency toward methylene blue removal and as an antibacterial agent. Single-crystal XRD analysis confirms that the material crystallizes in monoclinic symmetry (SG: Pn), with lattice parameters a = 13.1396(5) Å, b = 16.9655(8) Å, c = 14.3493(7) Å, and Z = 2. The structure comprises a single polyanionic [SiW12O40]4- moiety surrounded by four cationic [BmIm]+ units of two different conformations, which supported DFT and Hirshfeld surface analysis. The material shows excellent removal efficiency for methylene blue, with a maximum adsorption capacity of 92.47 mg/g and 83.05% reusability after five cycles. On the contrary, FTIR and ζ-potential analyses confirm that electrostatic interactions are the predominant factors governing the adsorption process. The material also acts as a superior antibacterial agent against the opportunistic pathogens Pseudomonas aeruginosa, Klebsiella pneumoniae, and Escherichia coli with a MIC of 500-700 μg/mL. However, a comparative assessment showed that the material was more effective against P. aeruginosa compared to the other two pathogens. PXRD analysis confirms the phase purity, and FESEM and TEM analyses exhibit block-shaped morphology with particle sizes ∼2-3 μm.

Achieving Complete Conversion from Nickel Foam to Nickel Sulfide Foam for a Freestanding Hybrid‐Supercapacitor Electrode

AbstractWe present a unique, one‐step, hydrothermal process to prepare nickel sulfide (Ni3S2) foam by a simple and direct conversion from nickel foam, which contributes both as a scaffold for the reaction and as reactant. The Ni3S2 foam exhibits remarkable mechanical stability, retaining the structural integrity of the foam and excellent crystallinity even after ultrasonication at 200 W for 30 mins. We document the transformation of the nickel foam template into a Ni3S2 foam, highlighting the role of synthesis duration on the phase evolution and unique morphology of Ni3S2. PXRD and SEM analyses reveal a complete transformation after 24 hours from the nickel foam to a pure Ni3S2 foam, which has a highly porous and interconnected ultra‐thin nanosheet architecture. This significantly enhances the surface area and provides many electrochemical reaction sites. In a three‐electrode cell, the capacity of the Ni3S2 foam electrode is 3.9 C cm−2 at 8 mA cm−2, which is higher than previous reports for Ni3S2. In a hybrid supercapacitor device, the Ni3S2 foam demonstrates significant increase in capacitance through 500 cycles and the capacitance plateaus after 2000 cycles. Even after 8500 continued charge‐discharge cycles, the device exhibits excellent cycle stability indicating improvement with age.

Eco-friendly synthesis of tin oxide nanoparticles: A novel strategy for managing early blight and soft rot in tomato crops

Tomato, a globally cultivated crop, is susceptible to early blight (Alternaria solani) and soft rot disease (Pectobacterium carotovorum), resulting in significant yield reductions. In this study, we report the biosynthesis of tin oxide nanoparticles (SnO2 NPs) via a novel, eco-friendly route and evaluate their efficacy against these phytopathogens. Characterization of SnO2 NPs revealed a mean particle size of 11.5 nm, uniform distribution, and pure and high crystallinity, as confirmed by TEM, SAED pattern, and P-XRD analysis. The green-synthesized SnO2 NPs achieved 100 % inhibition of fungal growth at 500 μg/mL and displayed a larger zone of inhibition against Pectobacterium carotovorum than the conventional antibiotic streptomycin. A notable decrease in the exponential phase of the OD600 curve and CFU/mL was further observed with increasing concentrations of NPs. They also demonstrated superior antioxidant properties compared to the standard, achieving over 90 % inhibition at a concentration of 300 μg/mL. The Terminalia chebula seed extract not only acts as a stabilizing agent but also exhibit antimicrobial activity. The synergy between the intrinsic antimicrobial properties of the SnO2 NPs and the bioactive compounds from the seed extract enhance the overall effectiveness of the nanoparticles against these pathogens. Our findings suggest that green-synthesized SnO2 NPs offer a promising and sustainable solution for managing early blight and soft rot disease in tomato crops.

Self-Assembled Nanostructure of Ionic Sn(IV)porphyrin Complex Based on Multivalent Interactions for Photocatalytic Degradation of Water Contaminants.

[Sn(H2PO4)2(TPyHP)](H2PO4)4∙6H2O (2), an ionic tin porphyrin complex, was synthesized from the reaction of [Sn(OH)2TPyP] (1) with a dilute aqueous solution of a polyprotic acid (H3PO4). Complex 2 was fully characterized using various spectroscopic methods, such as X-ray single-crystal crystallography, 1H NMR spectroscopy, elemental analysis, FTIR spectroscopy, UV-vis spectroscopy, emission spectroscopy, EIS mass spectrometry, PXRD, and TGA analysis. The crystal structure of 2 reveals that the intermolecular hydrogen bonds between the peripheral pyridinium groups and the axially coordinated dihydrogen phosphate ligands are the main driving force for the supramolecular assembly. Simultaneously, the overall association of these chains in 2 leads to an open framework with porous channels. The photocatalytic degradation efficiency of methyl orange dye and tetracycline antibiotic by 2 was 83% within 75 min (rate constant = 0.023 min-1) and 75% within 60 min (rate constant = 0.018 min-1), respectively. The self-assembly of 2 resulted in a nanostructure with a huge surface area, elevated thermodynamic stability, interesting surface morphology, and excellent catalytic photodegradation performance for water pollutants, making these porphyrin-based photocatalytic systems promising for wastewater treatment.

Facile synthesis of Tl, Pb, and Bi doped CeO2 nanoparticles and the evaluation of their in-vitro cytotoxicity and photocatalytic performance

Our work attempted a green route for provisioning of thallium, lead, and bismuth into cerium oxide nanoparticles (Tl, Pb, and Bi–CeO2 NP) via the application of Alhagi maurorum. We configured the physicochemical attributes of procured NPs via PXRD, Raman, FESEM/PSA/EDX, and UV–Vis/DRS assessments. Attendance of doped metals in structure of CeO2 was confirmed by outcomes of PXRD and EDX analyses. Next to the porous morphology, FESEM images also demonstrated the induced alterations in particle size after the doping of different metals. We also tested the photocatalytic function of synthesized NP on Methylene blue (MB) dye on UV light, which displayed the superior degradation functionality of Tl–CeO2 NP. The toxicity function of synthesized pure and Tl, Pb, and Bi–CeO2 NP on breast cancer cell (MDA-MB-231) and breast normal cell (MCF-10 A) lines was considered through the results of MTT trial. The outcomes of synthesized NPs displayed no signs of any cytotoxic effects against MCF-10 A and MDA-MB-231 cells, which signified the creation of non-toxic nanoparticles by the introduced doping process. Therefore, we suggest the applicability of our product in drug delivery systems and also industrial implementations similar to dye photodegradation and annihilation of pollution.

Efficient photocatalytic removal of plastic additive from simulated wastewater by guar gum-CuMn2O4 nanocomposite

Herein, a biocompatible nanocomposite based on guar gum (GG-CuMn2O4) was successfully synthesized and utilized for the elimination of toxic Allyl 2,4,6 tribromophenyl ether (ATE), a commonly used plastic additive. The research involved the green fabrication of CuMn2O4, which was then integrated into the polymeric matrix of guar gum to form GG-CuMn2O4 nanocomposite. The successful creation of the green-synthesized nanocomposite coated with a polymeric matrix at the nanoscale was confirmed by characterization. PXRD analysis revealed a semi-crystalline structure, while microscopic examinations committed the encapsulation of CuMn2O4 within a sheet-like structure in nanorange (1–100 nm). Incorporating the CuMn2O4 nanocomposite into the GG gel matrix reduced the likelihood of nanocomposite leaching, thereby enhancing material efficiency and biocompatibility. Highest removal of ATE (95 %) was achieved at a concentration of 5 mg L−1 with a catalytic dose of 10 mg, pH 7, and in the presence of Sunlight. The removal of the pollutant followed first-order kinetics, exhibiting Langmuir adsorption. The study examined the release dynamics of ATE from both underwater-expanded packaging materials and electrical wire components over various time intervals, concurrently assessing the degradation characteristics of the leached ATE. LC-MS analysis has corroborated that GG-CuMn2O4 demonstrates a profound capacity in disassembling intricate, hazardous pollutant structures into metabolites of enhanced safety, catalytically driven by Sunlight. The polymeric GG-CuMn2O4 nanocomposite exhibited remarkable reusability for up to ten consecutive cycles and advocated its sustainability efficiency and industrial applications.