Most of the global energy demand is related to the residential and commercial sectors. This significant share in the energy demand portfolio also shows a significant share of greenhouse gas emissions from the great cities. This is why renewable and other cleaner energy sources have been attractive in the last three decades. Solar collectors, energy storage, and photovoltaic cells are the most suitable clean technologies applicable to generate and store electricity, cooling, and heating demand in the residential sector. Due to this increasing attractiveness, much research has been done on those technologies to increase the systems' efficiency. One of the most important methods to improve these systems' performance can directly improve thermal conductivity and heat transfer. In this study, the collector is modeled in the system's fluent software and the main parameters are estimated for different nanoparticles. Then an exergy analysis is done to find the entropy generation and exergy destruction of the system to detect the main sources of the irreversibility in the system. Also, the effect of different parameters is studied on the exergy efficiency of this system. The results show that the value of temperature generation in cold climates has been higher than in hot climates, and increasing the inflow and collecting water level has increased consumer water Temperature. Using COPPER nanofluids increases solar water heaters' efficiency by up to 67%, while aluminum OXIDE and COPPER OXIDE nanofluids have 74% and 47% efficiency, respectively.

Background: Candidiasis is the most common fungal infection in human and warm-blooded animals. Candida albicans, is an opportunistic pathogen in immune suppressed hosts, like HIV infected and under chemotherapy patients. Since, antifungal drugs are limited and challenged by resistance. Thus discovering agents with antifungal properties and minimum side effects and toxicity is essential. Nano-agents such as metal OXIDE nano-particles have unique properties such as high surface to volume ratio that introduce them as appropriate antimicrobial agents.Materials and Methods: In this experimental study, antifungal effects of 4 nano-metal OXIDEs; magnesium OXIDE, zinc OXIDE, silicon OXIDE and COPPER OXIDE (MgO, SiO2, ZnO and CuO) were investigated in vitro against Candida albicans and compared with amphotericin B. Solution acetic acid was used for preparing nanoparticles suspensions. Minimum inhibitory concentration (MIC) and minimum fungicidal concentration (MFC) of these nano-particles were evaluated.Results: The results showed that MIC of nano-MgO and nano SiO2 was greater than 3200 mg/mL, but MIC and MFC of nano-ZnO was recorded 200 mg/mL and 400 μg/mL, respectively. The MIC and MFC of nano-CuO was 400 mg/mL. The MIC and MFC of amphotericin B was 0.5 mg/mL and 2 mg/mL, respectively.Conclusions: It is concluded that, ZnO and CuO nanoparticles have anti C. albicans properties and may be used in treatment of infections caused by this fungus that should be investigated in vivo.

A facile mechanochemical-based method for synthesis of COPPER OXIDE (CuO) nanoparticles is here by introduced. For this purpose, COPPER hydrOXIDE powder was synthesized through a facile solution method (CuSO4+2 Na (OH) ® Cu (OH)2+Na2SO4) after which milling of as-prepared Cu (OH)2 precursor and NaCl resulted in the mechanochemical dehydration of Cu (OH)2 and dispersion of CuO nanoparticles into the salt matrix (Cu (OH)2+2NaCl=CuCl2+2NaOH and then CuCl2+2NaOH=CuO+2NaCl+H2O). Subsequently, washing the milled powders led to the removal of salt matrix and separation of CuO particles. The main advantages of the introduced method are synthesis of CuO nanoparticles with narrow size distribution without subsequent annealing during the process. The results of X-ray diffraction (XRD) indicated that the dehydration of Cu (OH)2 into CuO was completed after three hours of milling. Structural analysis using scanning electron microscopy (SEM) equipped with energy dispersive spectroscopy (EDS), transmission electron microscopy (TEM) and particle size analyzer (PSA) showed that CuO particles had moderately equiaxed shape with sizes ranging from 10-27 nm. Also, the results of UV–visible absorption spectroscopy indicated that CuO nanoparticles had a band gap of 2.5 eV.