- In the area of smart textiles, Albargi et al. developed the novel piezoresistive strain sensor using a graphene/siloxane composite conductive ink applied to plied auxetic yarn (PAY), marking a significant advancement in wearable sensor technology. The blend of lycra and cotton yarns, braided core-spun and coated with siloxane polymer resin, improves mechanical durability and longevity. The innovative design enhances the negative Poisson’s ratio, resulting in a 2.5 times increase in sensitivity and a fivefold increase in strain range. This sensor efficiently translates mechanical strain into electrical resistance changes, offering promising health monitoring and structural diagnostics applications, heralding a new era of flexible, textile-based wearable technologies.

- In the domain of environmental protection, Shahid et al. presented the use of IoT-based sensor networks for enhancing air quality monitoring in the Middle East. The study provides the real-time, accurate data for tracking pollution trends and informing decisions. These networks, especially carbon-based sensors, offer extensive spatial coverage and are crucial for detecting gaseous pollutants. They are vital in mitigating health risks, protecting ecosystems, and addressing climate change. By integrating IoT-based systems with advanced data analysis techniques like machine learning and AI, policymakers can design effective mitigation strategies, aligning with Sustainable Development Goals and promoting sustainable development in resource-constrained regions.

- In the field of biomedical applications of advanced nanomaterials, Shahbaz et al. successfully synthesized high-purity chromium aluminum carbide via facile sol-gel method. Comprehensive characterization confirmed their structural, morphological, and chemical properties, making them suitable precursors for MXenes production. Notably, the synthesized phases exhibited significant antifungal activity against Candida albicans and minimal impact on the viability of E. coli and S. aureus. Cytotoxicity studies revealed that Cr₂AlC induced oxidative stress in HepG2 cells, while Cr₃AlC₂ and Cr₄AlC₃ showed lower cytotoxicity, underscoring their potential for biomedical applications. This research highlights the versatile applications of MAX phases in materials science and biomedicine.

- In the domain of environmental remediations, Alkorbi et al. reported the management of industrial dye effluents to reduce its significant environmental risks. The authors investigate the photocatalytic degradation of Direct Red 28 dye using a ternary composite of graphitic carbon nitride, TiO₂, and polyorthoanisidine (g-C₃N₄/TiO₂/POA), synthesized via in situ oxidative polymerization of o-anisidine. The detailed characterization of composite material ensured the successful fabrication. Photocatalytic tests demonstrated 86% degradation of Direct Red 28 at 30 mg/L dosage in 240 min at pH 2, with a 79% degradation rate after four cycles, highlighting the composite’s stability and efficiency. The enhanced reusability and effectiveness are attributed to increased light absorption and reduced electron-hole recombination in the presence of g-C₃N₄ and POA.

- Zainab et al. empowered the field of self-cleaning textiles in a study by synthesizing superhydrophobic materials through an eco-friendly, scalable, one-step hydrothermal process. The resulting superhydrophobic carbon quantum dots SCQDs exhibited crystalline carbon cores and amorphous hydrophobic polymeric chains, with a size distribution of 2–8 nm and an average size of 5 nm, produced by microwave-assisted carbonization. Their ultra-small size and high nanoscale surface roughness enabled water droplets to roll off, achieving a contact angle 163.64°. Applied to textile fabric via dip coating with a polydimethylsiloxane (PDMS) binder, SCQDs displayed aggregation-induced emission under UV light due to stable passivated surface states. The coated fabric maintained self-cleaning properties at a 10° angle without compromising porosity or comfort. A solvent-induced precipitation and filtration method for SCQD aggregates offered scalability over conventional synthesis methods. This facile approach for fabricating SCQD-coated surfaces demonstrates significant potential for commercial-scale self-cleaning applications in healthcare and outdoor wearables, maintaining superhydrophobicity in harsh environments without secondary pollution.