Abstract. The calcium ferrite nano-particles (CaFe 2 O 4 NPs) were synthesized using a sol-gel method for targeted drug delivery application. The proposed nano-particles were initially prepared by mixing calcium and iron nitrates that were added with citric acid in order to prevent agglomeration and subsequently calcined at a temperature of 550ÛC to obtain small particle size. The prepared nanoparticles were characterized by using an XRD (X-ray diffraction), which revealed the configuration of orthorhombic structures of the CaFe 2 O 4 nano-particles. A crystallite size of ~13.59 nm was obtained using a Scherer's formula. Magnetic analysis using a VSM (Vibrating Sample Magnetometer analysis), revealed that the synthesized particles exhibited super-paramagnetic behavior having magnetization saturation of approximately 88.3emu/g. Detailed observation via the scanning electron microscopy (SEM) showed the calcium ferrite nano-particles were spherical in shape.
Here, the researchers carried out an experimental analysis of the effect of the TiO2 nanosolution concentration on the heat transfer of the twin jet impingement on an aluminum plate surface. We used three different heat transfer enhancement processes. We considered the TiO2 nanosolution coat, aluminum plate heat sink, and a twin jet impingement system. We also analyzed several other parameters like the nozzle spacing, nanosolution concentration, and the nozzle-to-plate distance and noted if these parameters could increase the heat transfer rate of the twin jet impingement system on a hot aluminum surface. The researchers prepared different nanosolutions, which consisted of varying concentrations, and coated them on the metal surface. Thereafter, we carried out an X-ray diffraction (XRD) and a Field Emission Scanning Electron Microscopy (FESEM) analysis for determining the structure and the homogeneous surface coating of the nanosolutions. This article also studied the different positions of the twin jets for determining the maximal Nusselt number (Nu). The researchers analyzed all the results and noted that the flow structure of the twin impingement jets at the interference zone was the major issue affecting the increase in the heat transfer rate. The combined influence of the spacing and nanoparticle concentration affected the flow structure, and therefore the heat transfer properties, wherein the Reynolds number (1% by volume concentration) maximally affected the Nusselt number. This improved the performance of various industrial and engineering applications. Hypothesis: Nusselt number was affected by the ratio of the nanoparticle size to the surface roughness. Heat transfer characteristics could be improved if the researchers selected an appropriate impingement system and selected the optimal levels of other factors. The surface coating with the TiO2 nanosolution also positively affected the heat transfer rate.
New technologies need environmental and economic cooperation. Energy consumption is fundamental to human survival, making sustainable development imperative. When discussing energy production, renewable resources such as solar and wind energy are chosen to satisfy future demands. Solar energy is frequently used owing to its availability and several benefits. Though more efficient, silicon solar cells are poisonous and expensive. In comparison to other PV cells, the dye‐sensitized solar cells (DSSCs) have several benefits, such as easily accessible materials, low‐cost production processes, simple processing and exceptional diffuse light performance. DSSCs are more reliable alternative to many photovoltaic systems, including hybrid solar cells, inorganic, and organic. DSSCs technology characteristically be influenced by on photosensitizer, electrolyte, and the metal oxide semiconductor. Significant enhancement in cell efficiency has been ranges reach to 12%, using Ru (II) dyes by enhancing substantial besides essential characterization. The dye, that is acting as a source of photoexcited electrons, is the most significant component of a DSSC. This brief review highlights and discusses a summary of the ongoing research made to assist optimization under using N719 dye for DSSC devices.
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