Photo-thermal conversion properties of MXene/metal-organic-frameworks-based nanofluids for solar energy harvesting.

This study focuses on enhancing solar energy capture efficiency by introducing innovative hybrid nanofluids for use in solar thermal collectors, whose performance largely depends on the absorption properties of the working fluid. The newly developed hybrid nanofluids, MXene/NH2-UiO66 (Zr) (noted as MX/UO66) and MXene/MIL-88B (Fe) (noted as MX/ML88), were synthesized using an in-situ solvothermal method, combining annealed Ti3C2Tx MXenes with water-stable metal-organic frameworks (MOFs). These nanofluids achieved high efficiency at low concentrations, providing both economic and performance benefits.

Vitamin E improves oxidative stress, apoptosis, and steroidogenesis impairment in glyphosate-induced mice.

Background: Glyphosate (Gly) is a nonselective pesticide with high potential to toxic effects on the reproductive system. Recent studies suggest that Vitamin E can indeed have a positive impact on the reproductive system, while Gly, a nonselective pesticide, has been linked to significant risks of toxicity on reproductive health. It's crucial to be mindful of the potential impacts of such substances on the reproductive system.

Economic and Environmental Pollutant Impact of Maternal-Fetal Telemedicine.

Objective:  The global issue of greenhouse gas emissions has significant implications for the environment and human health. Telemedicine provides a valuable tool for delivering health care while reducing gas emissions by limiting the need for patient travel. However, the environmental effects of telemedicine in high-risk pregnancy populations remain unassessed.

PD-DEM hybrid modeling of leading edge erosion in wind turbine blades under controlled impact scenarios.

This paper addresses the critical issue of leading edge erosion (LEE) on modern wind turbine blades (WTBs) caused by solid particle impacts. LEE can harm the structural integrity and aerodynamic performance of WTBs, leading to reduced efficiency and increased maintenance costs. This study employs a novel particle-based approach called hybrid peridynamics-discrete element method (PD-DEM) to model the impact of solid particles on WTB leading edges and target material failure accurately.