A Review of Hybrid Humidification and Dehumidification Desalination Systems

The escalating threat of water scarcity, coupled with the inclusion of numerous countries in the list of water-scarce nations, has elevated the issue of water availability to a paramount concern in today\u27s global landscape. Freshwater sources are becoming increasingly scarce, with their proportional decline steadily progressing. Consequently, a growing number of nations have resorted to the desalination of seawater as a viable solution. In response to this critical need, a surge of studies and research endeavors has been dedicated to the development and refinement of desalination processes. One of the most promising innovations in this field is Humidification-Dehumidification (HDH) desalination technology. This paper aims to delve into the potential of HDH desalination technology and its integration with another advanced desalination method known as a hybrid system. By combining these two distinct approaches, it becomes possible to not only enhance productivity but also address certain limitations inherent in each technology. In this paper, we provide an overview of various desalination processes, shedding light on their classifications and characteristics. Our primary focus, however, lies in exploring how HDH desalination technology can be effectively harmonized within a hybrid system to maximize efficiency and mitigate shortcomings observed in individual technologies. The integration of HDH with existing desalination methods has demonstrated notable success, as evidenced by numerous research studies in the field. This research underscores the significance of hybridization in advancing HDH sustainability practices within the desalination sector, ultimately contributing to the global effort to combat water scarcity

A Review of Hybrid Humidification and Dehumidification Desalination Systems

The escalating threat of water scarcity, coupled with the inclusion of numerous countries in the list of water-scarce nations, has elevated the issue of water availability to a paramount concern in today\u27s global landscape. Freshwater sources are becoming increasingly scarce, with their proportional decline steadily progressing. Consequently, a growing number of nations have resorted to the desalination of seawater as a viable solution. In response to this critical need, a surge of studies and research endeavors has been dedicated to the development and refinement of desalination processes. One of the most promising innovations in this field is Humidification-Dehumidification (HDH) desalination technology. This paper aims to delve into the potential of HDH desalination technology and its integration with another advanced desalination method known as a hybrid system. By combining these two distinct approaches, it becomes possible to not only enhance productivity but also address certain limitations inherent in each technology. In this paper, we provide an overview of various desalination processes, shedding light on their classifications and characteristics. Our primary focus, however, lies in exploring how HDH desalination technology can be effectively harmonized within a hybrid system to maximize efficiency and mitigate shortcomings observed in individual technologies. The integration of HDH with existing desalination methods has demonstrated notable success, as evidenced by numerous research studies in the field. This research underscores the significance of hybridization in advancing HDH sustainability practices within the desalination sector, ultimately contributing to the global effort to combat water scarcity

Controlling the microstructure and properties of titania nanopowders for high efficiency dye sensitized solar cells

(a) A highly ordered, vertically oriented TiO2 nanorods compared with TiO2 nanopaticles and (b) Dye sensitized solar cell fabricated using sealing technique. [Display omitted] ► TiO2 nanorods particles size of 3–5nm was synthesized hydrothermally at 100°C. ► SBET was 78.14m2/g and the band gap energy was 3.2eV. ► (Jsc) and (Voc) of the DSSC were in the range 10.84–13.23mAcm−2 and 0.71–0.78V. ► Conversion efficiency of DSSCs was 7.2%. ► IPCE analyses of the DSSC showed two peaks, at ∼350 and 520nm. A low temperature hydrothermal process have been developed to synthesize titania nanorods (NRs) and nanoparticles (NPs) with controlled size for dye sensitized solar cells (DSSCs). Effect of calcination temperature on the performance of TiO2 nanoparticles for solar cells was investigated and discussed. The crystallite size and the relative crystallinity of the anatase phase were increased with increasing the calcination temperature. The structures and morphologies of both (TiO2 nanorods and nanoparticles) were characterized using XRD, SEM, TEM/HRTEM, UV–vis Spectroscopy, FTIR and BET specific surface area (SBET) as well as pore-size distribution by BJH. The size of the titania nanorods was 6.7nm width and 22nm length while it was 13nm for nanoparticles. Efficiency of dye-sensitized solar cells (DSSCs) fabricated with oriented TiO2 nanorods was reported to be more superior compared to DSSC based on mesoporous TiO2 nanoparticles due to their high surface area, hierarchically mesoporous structures, low charge recombination and fast electron-transfer rate. With increasing calcination temperature of the prepared nanopowders, the light-electricity conversion efficiency (η) decreased. The efficiency of the assembly solar cells was decreased due to the agglomeration of the particles and difficulty of electron movement. The power efficiency was enhanced from 1.7% for TiO2 nanoparticles cells at hydrothermally temperature 500°C and 5.2% for TiO2 nanoparticles cells at hydrothermally temperature 100°C to 7.2% for TiO2 nanorods cells under AM1.5 illumination (100mWcm−2)

Benzo[g]quinazolines as antifungal against candidiasis: Screening, molecular docking, and QSAR investigations

Candida albicans, an opportunistic pathogen, is the most common type of fungus and represents a substantial source of human invasive disease (nosocomial infection). This category of fungi are part of our microbiota, and given the appropriate environmental conditions, it has the potential to cause both superficial and systemic infections. There is a soaring resistance against the available anticandidal agents. The purpose of this research is to investigate the activity of certain previously synthesized benzo[g]quinazolines against C. albicans in vitro by using the cup-plate diffusion method. There was a marked difference in the effectiveness of the target compounds 1–6 against the sample of C. albicans that was tested. Benzo[g]quinazolines 1 (inhibition zone = 20 mm) and 2 (inhibition zone = 22 mm) had good effects in comparison to fluconazole (inhibition zone = 26 mm). A docking study was conducted between benzo[g]quinazolines 1–6 and Candida spp. CYP51 to establish the binding mode compared with fluconazole and VT-1161 (oteseconazole) as reference medicines, and it was determined that binding at the active site of Candida spp. CYP51 occurred in the same manner. Quantitative structure–activity relationship (QSAR) investigation was performed to further characterize the identified anticandidal agents and recognize the major regulatory components governing such activity. In future studies, the benzo[g]quinazoline scaffold could serve as a model for the design and development of novel derivatives with antifungal potential