Rapid N2O Formation from N2 on Water Droplet Surfaces.

Nitrogen (N2) has long been considered as stable atmospheric reservoir for N element and has a persistence time of hundreds of years. This study reveals that oxygen (O2) at typical tropospheric concentrations can rapidly activate N2, leading to substantial production of nitrous oxide (N2O), the third most impactful greenhouse gas, at rates approaching 2.83 ± 0.

Position statement of the Spanish Working Group on Crohn's Disease and Ulcerative Colitis on the use of Telemedicine in Inflammatory Bowel Disease.

Inflammatory Bowel Disease (IBD) is a chronic digestive condition that requires continuous monitoring by healthcare professionals to determine appropriate therapy and manage short- and long-term complications. Telemedicine has become an essential approach for managing chronic conditions such as IBD, improving care accessibility and continuity, decreasing hospitalization rates, and optimizing patient follow-up. It enables rapid treatment adjustments and encourages patient self-management.

Heterogenous Chemistry of IO as a Critical Step in Iodine Cycling.

Global iodine emissions have been increasing rapidly in recent decades, further influencing the Earth's climate and human health. However, our incomplete understanding of the iodine chemical cycle, especially the fate of higher iodine oxides, introduces substantial uncertainties into atmospheric modeling. IO was previously deemed a "dead end" in iodine chemistry; however, we provide atomic-level evidence that IO can undergo rapid air-water or air-ice interfacial reactions within several picoseconds; these reactions are facilitated by prevalent chemicals on seawater such as amines and halide ions, to produce photolabile reactive iodine species such as HOI and IX (X = I, Br, and Cl).

Promoting ClO Generation from the HOCl + HOCl Reaction on Aqueous/Frozen Air-Water Interfaces.

Hypochlorous acid (HOCl) is considered a temporary reservoir of dichlorine monoxide (ClO). Previous studies have suggested that ClO is difficult to generate from the reaction of HOCl + HOCl in the gas phase. Here, we demonstrate that ClO can be generated from the HOCl + HOCl reaction at aqueous/frozen air-water interfaces, which is confirmed by ab initio molecular dynamic calculations.

Tunable Topological Wetting State of Water Droplets on Planar Surfaces: Closed-Loop Chemical Heterogeneity by Design.

Understanding droplet wetting on surfaces has broad implications for surface science and engineering. Here, we report a joint theoretical/experimental study of the topological wetting states of water droplets on chemically heterogeneous closed-loop and planar surfaces. Interestingly, we provide both simulation and experimental evidence of biloop or even multiloop transition wetting states of water droplets.