Modeling sustainable photocatalytic degradation of acidic dyes using Jordanian nano-Kaolin-TiO and solar energy: Synergetic mechanistic insights.

The abstract highlights the global issue of environmental contamination caused by organic compounds and the exploration of various methods for its resolution. One such approach involves the utilization of titanium dioxide (TiO) as a photocatalyst in conjunction with natural adsorption materials like kaolin. The study employed a modeling-based approach to investigate the sustainable photocatalytic degradation of acidic dyes using a Jordanian nano-kaolin-TiO composite material and solar energy.

Structural, Electronic, Elastic, and Optical Characteristics of AgZF (Z = Sb and Bi) Fluoro-Perovskites: Using a Computational Approach for Energy Generation.

This research is being conducted to learn more about various compounds and their potential uses in various fields such as renewable energy, electrical conductivity, the study of optoelectronic properties, the use of light-absorbing materials in photovoltaic device thin-film LEDs, and field effect transistors (FETs). AgZF3 (Z = Sb, Bi) compounds, which are simple, cubic, ternary fluoro-perovskites, are studied using the FP-LAPW and low orbital algorithm, both of which are based on DFT. Structure, elasticity and electrical and optical properties are only some of the many features that can be predicted.

Jordanian Kaolinite with TiO for Improving Solar Light Harvesting Used in Dye Removal.

TiO-Kaolinite nanocomposite photocatalysts were synthesized using the sol-gel method, with titanium isopropoxide/HCl as reactants and Jordanian kaolinite clay as a support material. The samples' TiO content ranged from 10% to 70% (m/m). TiO-Kaolinite composites were characterized using FTIR, SEM, XRF, and XRD.