Your search keyword '"Ahmed H. Ragab"' showing total 5 results

1. Thermal, mechanical, and photocatalytic dye degradation performances of the functionalized GO and TiO2 decorated carbon foam composites

Author

Muhammad Azeem Aslam, Lefang Zhang, Xin Liu, Yimei Xu, Na Li, Ping Zhang, Ahmed H. Ragab, Ahmed Deifalla, and Muhammad Khan

Subjects

Carbon foam, FGO and FTiO2, Microstructure, Thermal, Mechanical, Catalytic dye degradations, Mining engineering. Metallurgy, TN1-997

Abstract

Although pitch-derived carbon foam (CF) is not new, but the progress for enhanced thermal, mechanical, and catalytic dye degradations need to be explored. Numerous works were performed to improve the structural morphology and properties of the CFs by dispersing various additives. But mostly it was noticed that such additives enhanced one aspect of the CFs at the cost of other ones. In this work, various additive loadings of the functionalized graphene oxide (FGO), and functionalized titanium dioxide (FTiO2) were synergistically dispersed into the CF matrix via facile pyrolysis for the preparation of CF/FGO and CF/FGO + FTiO2 hybrid composites to improve the structural morphology and properties of the CFs. Functionalization of the graphene oxide (GO) and titanium dioxide (TiO2) nanoparticles (NPs) was performed for the purpose to decrease the possible aggregations, and enhancing the compatibility and interaction between the additives and the CF matrix. A total of seven CF composites including pure CF were synthesized and explored for their structural, thermal, mechanical, and catalytic dye degradation performances. The microstructural investigations revealed that cellular morphology, pore size, shape, and porous homogeneity of the CF composites were significantly improved after the FGO and FTiO2 loadings. The thermal and mechanical behaviors revealed that as the additives loading of the FGO and FTiO2 are increased, the thermal and mechanical responses of the CF composites are significantly improved. The maximum thermal conductivity of 27.9 W/m K was revealed by 4wt.% CF/FGO + FTiO2 hybrid composite. Similarly, the optimum compressive strength of 15.7 MPa, specific compressive strength of 3.5 10 m3, excellent stress–strain, and improved Young's modulus of 42.2 MPa was shown by 4wt.% FGO + FTiO2 hybrid composite. The catalytic activity was evaluated by degrading orange II dye in an aqueous medium under ultraviolet (UV) light irradiation. The TiO2-containing composite was found to be active and the sample with 4wt.% CF/FGO + FTiO2 hybrid composite achieved a significant 78.9% degradation of the dye within just 80 min.

Published

2023

2. Heterogeneous nucleation and growth of interlaced CuO nanosheets on porous nickel foams as binder-free electrode material

Author

Tongfei Lei, Azam Khan, Jasim Yousaf, Ahmed Deifalla, Feng Pan, Ahmed H. Ragab, Ali Sayqal, Muhammad Khan, Mohd Zahid Ansari, and Yaqoob Khan

Subjects

Crystal growth, Super saturation, Nanosheets, Thick films, Aqueous chemical growth, Mining engineering. Metallurgy, TN1-997

Abstract

The monoclinic CuO has a natural tendency to grow into sheet-like structures from alkaline solutions without the need for any specialized reaction conditions or structural directing agents. We demonstrate this growth habit of CuO by heterogeneously nucleating it onto Ni foam substrate from just the ammonical solutions of Cu salts. The growth kinetics were found to be fast and, dense, interlaced thin films with an average sheet width of 20 nm can be grown by simply controlling the degree of supersaturation of the solution. Strongly adhered films with thicknesses up-to 5 μm were deposited from three different Cu salt solutions. Due to faster growth kinetics, growth time has little effect on both the film and nanosheet thickness. Detailed structural and compositional characterizations of the CuO nanosheets were made using FESEM, HRTEM, SAED, XRD and, XPS. The utility of the grown CuO nanosheets is demonstrated as a ready to use electrode for electrochemical supercapacitors. Specific capacitance in excess of 498 F/g was calculated from the Galvanostatic charge–discharge measurements collected at a current density of 0.5 A/g.

Published

2023

3. Carbon foam composites containing carbon nanotubes and graphene oxide as additives for enhanced mechanical, thermal, electrical and catalytic properties

Author

Jianfeng Wang, Muhammad Khan, Amjad Hussain, Idrees Khan, Ammara Nawaz, Ahmed H. Ragab, Ali Sayqal, Tongfei Lei, and Amir Zada

Subjects

Pitch derived carbon foam, Multi-walled carbon nanotubes, Graphene oxide, Structural and catalytic properties, Mining engineering. Metallurgy, TN1-997

Abstract

Based on the versatile nature and applications of Carbon foam (CF), up to now many attempts were performed to improve the structure and properties of CF by incorporating various additives in the CF matrix. But these additives improved one property on the cost of another ones. Herein, we have synergistically incorporated multi-walled carbon nanotubes (MWCNTs) and graphene oxide (GO) with varying loadings as additives in the CF matrix via direct pyrolysis to achieve all the desired properties. Seven different types of CF composites including pure CF were prepared and their effect on the structure, mechanical, thermal, electrical and catalytic characteristics has been reported. The results revealed that after the inclusion of MWCNTs and GO contents, the microstructural performance of CF samples was amazingly improved. Additionally, it was observed that mechanical, thermal, electrical and catalytic behaviors of the CF samples were significantly enhances by the increase of nanohybrids. The compressive strength and Young's modulus reveals their optimum limits up to 19.3 and 57.4 MPa respectively on 2 wt.% MWCNTs-GO additive loadings. Similarly, the greatest thermal and electrical conductivities of 30.92 W/m. K and 27.4 × 103 S/m were showed by CF samples having 2 wt. % MWCNTs-GO loadings. Whereas, the decolorization activity of the CF and their nanocomposites were tested against methyl orange dye and it was observed that the sample with enhanced MWCNTs and GO have good decolorization activity and much sustainable than other samples. The 4% CF/MWCNTs-GO decolorized about 76% MO dye under exposure to UV light within 60 min. The decolorization of MO dye increases with increasing nanocomposite dosage and decreasing initial dye concentration.

Published

2023

4. Recent advances in the structure and biomedical applications of nanodiamonds and their future perspectives

Author

Feng Pan, Muhammad Khan, Ahmed H. Ragab, Elisha Javed, Hessa A. Alsalmah, Idrees Khan, Tongfei Lei, Amjad Hussain, Ahmed Mohamed, Amir Zada, and Mohd Zahid Ansari

Subjects

Nanodiamonds, Surface modification, Biocompatibility, Drug delivery, Sensors, Anti-cancer and orthopedics, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Nanodiamond (ND) is becoming the core center of interest for many researchers due to its immense utilization in different fields of science. The extraordinarily unique attributes provided by NDs include biocompatibility, easy production, chemical inertness, rich surface chemistry, small size, and fluorescence resistance. In biomedical sciences, all these characteristics uplift the standards of ND particles. Recent studies on the biomedical side have been found to strengthen its significance ever since ND tested positive for utilization in diagnostics and drug delivery. In addition, NDs have been proven beneficial in the manufacturing of biodegradable surgical instruments, scaffolds for tissue engineering, and drugs to eliminate resistant microbes and viruses. Genetic materials are also delivered to the center of the nucleus with the aid of ND particles. In this review, we have discussed in detail all the benefits of NDs, their applications in sensors, ND-blood interactions, blood-contacting, orthopedics, anti-cancer agents, antimicrobial agents, and drug/gene delivery. The importance and significance of the purification, synthesis, processing, and surface functionalization of NDs have been discussed. Recent advances in modern technologies in the field of biomedical and biological sciences also have been covered in this manuscript.

Published

2023

5. Zirconium oxide with graphene oxide anchoring for improved heavy metal ions adsorption: Isotherm and kinetic study

Author

Saedah R. Al-Mhyawi, D.M.D. Bader, Majed A. Bajaber, Samia M. Abd El Dayem, Ahmed H. Ragab, Khaled A. Abd El-Rahem, Mohamed A. Gado, Bahig M. Atia, and Mohamed F. Cheira

Subjects

Uranium sorption, Zirconium oxide/graphene oxide, Kinetics, Thermodynamic circumstances, Mining engineering. Metallurgy, TN1-997

Abstract

Heavy metal contamination is a major environmental issue worldwide and a significant public health risk. However, developing environmentally sustainable and technically viable solutions or adsorbents for treating water contamination caused by heavy metals is urgently needed. In this work, an eco-friendly approach of obtaining a new composite material called ZrO2/GO that was prepared from the synthesized nano zirconium oxide (ZrO2) and graphene oxide (GO) prepared from spent carbon rods in zinc carbon batteries. ZrO2/GO was analyzed by XRD, SEM, BET, EDX, and FTIR to learn more about its composition and structure. The batch approach determined the optimal sorption conditions, including pH4, 50 mg ZrO2/GO, 150 mg/L U(VI), and 50 min of sorption time. ZrO2/GO was found to have a 128 mg/g sorption capacity. The Langmuir and 2nd-order kinetic equations can be exploited to elucidate the adsorption approach with reasonable accuracy. Since sorption is exothermic when it occurs naturally, thermodynamic restrictions were also envisioned. ZrO2/GO retains over 92% heavy metal ions (VI) removal efficiency even after 7 cycles. ZrO2/GO shows assurance as a potent sorbent material to extract hexavalent heavy metal ions and adsorption capacity from massive solution volumes.

Published

2023