Molten Sn solvent expands liquid metal catalysis.

Regulating favorable assemblies of metallic atoms in the liquid state provides promise for catalyzing various chemical reactions. Expanding the selection of metallic solvents, especially those with unique properties and low cost, enables access to distinctive fluidic atomic structures on the surface of liquid alloys and offers economic feasibility. Here, Sn solvent, as a low-cost commodity, supports unique atomic assemblies at the interface of molten SnInCu, which are highly selective for H synthesis from hydrocarbons.

High-Energy Aqueous Sodium-Ion Batteries Using Water-in-Salt Electrolytes and 3D Structured Electrodes.

Aqueous sodium-ion batteries (SIBs) are gradually being recognized as viable solutions for large-scale energy storage because of their inherent safety as well as low cost. However, despite recent advancements in water-in-salt electrolyte technologies, the challenge of identifying anode materials with sufficient specific capacity persists, complicating the wider adoption of these batteries. This study introduces an innovative and straightforward approach for synthesizing vanadium oxide laser-scribed graphene (VO-LSG) composites, which function as effective anode materials in aqueous sodium-ion batteries.

Patient perspectives on educational needs in scleroderma-interstitial lung disease.

Background: Systemic sclerosis is a chronic and rare connective tissue disease with multiorgan effects, including interstitial lung disease (ILD). Navigating systemic sclerosis-interstitial lung disease presents a challenge for patients due to the gaps in patient education, which can impact patient health and quality of life. This study utilized the nominal group technique to identify priority knowledge gaps among patients with systemic sclerosis-interstitial lung disease and inform future educational interventions and research.

Unconventional aspects in metal-embedded laser-induced graphene.

Laser-induced graphene (LIG) has gained significant attention, with over 170 publications in 2023 alone. This surge in popularity is due to the unique advantages LIG offers over traditional thermal methods, such as fast, solvent-free, scalable production and its ability to scribe intricate patterns on various substrates, including heat-sensitive materials like plastics. In recent developments, metal-embedded LIG (M-LIG) has expanded the potential applications of LIG, particularly in energy storage, microelectronics, and sensing.