Structural, electronic, optical, and mechanical properties of cubic SnZrO3 and SnHfO3 have been studied under different hydrostatic pressures within the framework of density functional theory. A strong atomic interaction resulting from a considerable drop in the lattice parameter and bond length was observed. The Sn–O and Hf/Zr–O showed strong ionic and weak covalent characteristics, respectively, and the bond strengths are found to enhance under the applied pressure. Poisson’s ratio of these compounds also supports the bonding nature. The external pressure remarkably changed the optical absorption and conductivity of the materials to a higher value in the UV region of the solar spectrum and the direct bandgap of Sn(Zr/Hf)O3 significantly reduced, thereby enhancing the conductivity. Likewise, in other optical parameters, the elastic properties exhibited some noticeable changes: the stiffness, ductility, anisotropy, hardness, and machinability of these materials were significantly increased due to external pressure. All the findings indicate the high potentiality of these compounds to be used in optoelectronics and photovoltaic applications in the UV spectrum under hydrostatic pressure.
Conjugate pure mixed convection in a differentially heated square cavity with two vertically placed heat conductive revolving cylinders has been analyzed in computational approach applying the Finite Element Method. This analysis has been implemented considering the upper and lower wall as insulated simultaneously and the left vertical wall as heated maintaining constant temperature (i.e., isothermally heated) and the right vertical wall as isothermally cooled. The outcomes of this study have been examined concerning streamlines, isotherms, average Nusselt number (Nu) which unveils a noteworthy fact that both the rotating cylinders' inclination patterns and Reynolds number have a vital role upon the Nu, flow pattern, and isotherms. From that perspective, best heat transfer phenomena have been observed for counterclockwise circulation of both cylinders so that the condition for these cases has been assessed from a distance variation between the two cylinders maintaining a constant speed ratio (s). The best result has been specified for different speed ratios at different materials of the rotating cylinders.
The principal focus of this experiment was to investigate the dynamic friction properties of different fabric samples at dry and wet skin conditions for a fixed load. The experiment was done by a simple setup with fabric sliding mechanism over human skin for four separate fabric samples of two different categories. Friction forces between different fabrics and human skin were measured through the experimental procedure and afterwards friction coefficient was calculated using Capstan formula from the obtained value of force. It was observed that the friction coefficient of Garment fabrics is lower than that of Special fabrics in dry condition. Wet condition resulted in higher frictional effects than dry condition of the skin providing perfect matching of natural frictional characteristics of any surface. Besides, the wetness of skin, as well as wettability of fabrics, also have a significant influence on the friction coefficient.
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