Advancing Open Science

Earth-abundant nickel phosphide electrocatalysts show great potential for the hydrogen evolution reaction (HER), yet their efficiency requires further enhancement for practical applications. Herein, a novel in situ strategy is developed to synthesize a high-performance electrocatalyst on nickel foam (NF), composed of N-doped carbon-coated Ni₅P₄–Ni₃P heterostructures. This is achieved through the phosphidation and subsequent carbon coating of hydrothermally grown Ni(OH)₂ nanosheets. The resulting catalyst exhibits excellent HER activity in acidic media, requiring a low overpotential of only 63 mV to achieve a current density of 10 mA cm⁻². The superior performance stems from the synergistic effects of multiple factors: the porous nanosheet architecture and multi-phase interfaces provide abundant active sites, while the conductive N-doped carbon network significantly enhances charge-transfer kinetics and catalyst stability. This work presents an effective approach for designing efficient non-precious metal HER electrocatalysts.

Heparan sulfates (HS) are polysaccharides abundantly expressed in the extracellular matrix and the glycocalyx of endothelial cells, having a putative role in vascular function. The role of HS in vascular reactivity remains unclear. Herein, we sought to determine whether HS regulate the vascular tone in physiological conditions. Using male, 6–8-weeks-old, CD1, C57BL/6, syndecan 1 (Sdc1^−/−) and glypican 1 (Gpc1^−/−) knockout mice, we investigated if the degradation of HS with heparinase III altered vascular reactivity to norepinephrine (NE), acetylcholine (ACh) and potassium chloride (KCl). Our findings indicate that HS are crucial players in the vascular response to NE and ACh in CD1, C57BL/6, and Sdc1^−/− but not in Gpc1^−/− mice. Both Sdc1^−/− and Gpc1^−/− showed increased compensatory expression of syndecan 2 and syndecan 4. However, while Sdc1^−/− showed decreased expression of glypican 1, Gpc1^−/− showed increased expression of syndecan 1 in aortic homogenates. The lack of response to the vascular reactivity effects of heparinase III in Gpc1^−/− suggests a differential role of HS to proteoglycan function in the regulation of the vascular tone. Our data demonstrate a physiological role for HS in the regulation of the vascular tone in physiological conditions.

Breastfeeding is a complex biopsychosocial process influenced not only by biological mechanisms but also by a woman’s previous psychological experiences and past traumas. The aim of this review was to analyze current research on the impact of early traumatic experiences, perinatal trauma, psychological difficulties, and previous interpersonal stressors on the initiation, continuation, and emotional course of breastfeeding. Women with a history of trauma are more likely to struggle with emotional regulation difficulties, increased stress, depressed mood, and problems bonding with their child. These factors translate into an increased risk of discontinuing lactation, discomfort during feeding, and reduced self-esteem regarding maternal competence. The literature also emphasizes the role of psychological and social support, which can help mothers cope with emotional tension and promote a positive breastfeeding experience. Consideration of the mother’s previous psychological and traumatic experiences is crucial for a more complete understanding of lactation difficulties and the development of effective forms of support for women in the perinatal period.

The interaction between small organic molecules and coal macerals plays a critical role in regulating fluid retention and transport in coal-related energy and environmental systems. However, the microscopic mechanisms governing adsorption selectivity and interfacial dynamics on different maceral surfaces remain insufficiently understood. In this study, molecular dynamics simulations were employed to investigate the adsorption and desorption behaviors of toluene (TOL) and tetrahydrofuran-2-ol (FUR) on inertinite (INE) and vitrinite (VIT) surfaces at the molecular level. Time-dependent variations in adsorption number, residence time, molecular mobility, interaction energies, and hydrogen-bond characteristics were systematically analyzed. The results reveal strong maceral- and molecule-dependent adsorption preferences. TOL exhibits the most stable adsorption on the INE surface, characterized by rapid surface accumulation, minimal desorption, and a long residence time of 0.43547 ns, which is mainly driven by strong van der Waals interactions and aromatic stacking effects. In contrast, TOL adsorption on VIT is highly dynamic, with frequent desorption events and a markedly reduced residence time of 0.1077 ns. FUR shows relatively weaker and more reversible adsorption on INE, accompanied by enhanced molecular mobility and a shorter residence time of 0.31354 ns. Notably, FUR demonstrates stronger surface retention on VIT, with an extended residence time of 0.34439 ns, which can be attributed to increased electrostatic contributions and intermittent hydrogen bonding. Hydrogen-bond analysis indicates that FUR forms longer-lived hydrogen bonds with VIT (22.05 ps) than with INE (17.86 ps), providing additional stabilization at the interface. These findings elucidate the distinct adsorption mechanisms of aromatic and polar molecules on heterogeneous coal macerals and offer molecular-scale insights into organic matter–coal interfacial processes relevant to energy extraction and subsurface transport.

Maximizing the agricultural output on inherently infertile land and minimizing the environmental cost remain central research imperatives. Albic black soil typifies such infertility. Conventional practice relies on fertilization and straw incorporation, but the albic layer’s impermeability funnels applied nutrients into adjacent aquatic systems. Therefore, this study developed deep placement fertilization by lodging fertilizer directly within the albic layer to block hydrologic loss. The feasibility of mechanization was first validated in pot experiments. Soybeans were allocated to six treatments simulating fertilizer placement at different soil depths: control (C), control and fertilizer (CF), surface soil mixing (SM), surface soil mixing and fertilizer (SMF), plow pan soil mixing (PM), and plow pan soil mixing and fertilizer (PMF). The treatments used 20 cm tillage, and the data were collected after 15, 25, and 35 days and at harvest. Integrative transcriptomic, proteomic, metabolomic, and soil microbiome profiling revealed that fertilizer positioned at 25 cm in the albic layer increased yield, restructured the rhizobiont community and promoted arbuscular mycorrhizal fungal colonization. Among the fertilizer treatments, CF had the best growth, and SMF was inhibited by a nutrient shortage. SMF and PMF lost water faster than CF. Abscisic acid (ABA) conveyed the subterranean fertilization signal to the leaf. The enrichment of Vicinamibacterales, Xanthobacteraceae, and Glomeromycota in soil lowered the ABA content in the roots, which upregulated thymidine kinase and peroxidase upon arrival in the leaf, increasing yield. These findings provide a transferable benchmark for any parent material exhibiting poor hydraulic conductivity.

During the magmatic stage, base and rarer metals segregate from silicate melts to form ore deposits. The usual case is the porphyry (PD) type (Cu, Mo, and W) above subduction zones. The metal grade increases from some ppb or ppm up to percent levels. A new type of trans-porphyry (TPD) deposits (Sn, Ta, Nb, and gems) results from large-scale shear between cratons within continental plates, internal decoupling, and vertical motion. The bulk ore generation process develops along three stages: from magma generation, emplacement, and the formation of an immiscible magmatic phase (MIP), fluids, and melt. However, in TPD, metals segregate from the crust during melting below 800 °C, biotites break down, and the melt remains below the critical point (731 °C). Fluid advection competes with chemical diffusion, yielding the required enrichment. The subcritical MIP splits into a silicate-rich and an aqueous-rich phase, which are both incompatible with each other. Granite, pegmatites, and greisen coexist in the magma chamber. Their respective extraction from a composite mush involves electron exchanges between charges, or orbitals, yielding metal oxides through chemical diffusion. In contrast, in metals (Nb and Ta) observed in pegmatites, and also in gems, electrons rearrange their electronic cloud through their polarizability. Lastly, gems independently grow under the influence of the extremely hard fluids (Li, Be, and B). Magma generation, involving the lower crust (garnet and pyroxene), results in melts that form the two observed pegmatite groups (NYF and LCT), with each being associated with alkaline (A-type) or continental (S-type) granitic melts.

This study adopts a biochemical approach to sequester CO₂ while producing biomass rich in protein and lipids, using an adapted strain of Chlorella vulgaris (ALE-Cv), which had previously evolved to tolerate a gas mixture containing 10% CO₂ and 90% air. The research studied the operating parameters of the batch photobioreactor for ALE-Cv to evaluate the effects of inoculum size, photoperiod, light intensity, pH of culture, and CO₂ supply rate on biomass productivity and CO₂ bio-fixation rate. The optimal conditions were identified as 16:8 h light–dark cycles, 5000 lux, pH 7, 20 mL of 10 g/L inoculum, and 0.6 VVM; the system achieved a maximum total biomass production of 7.03 ± 0.21 g/L with a specific growth rate of 0.712 day⁻¹, corresponding to a CO₂ bio-fixation of 13.4 ± 0.45 g/L in batch cultivation. While the pre-adapted strain of Chlorella vulgaris under the same operating conditions, except for the gas supply, which was air, achieved a maximum total biomass production of 0.52 ± 0.008 g/L, and the total CO₂ bio-fixation was 1.036 ± 0.021 g/L during 7-day cultivation. A novel semi-continuous harvesting process, with and without nutrient addition, was also investigated to maximise biomass yield and enable water recycling for culture media. The maximum biomass production in semi-continuous harvesting process with and without nutrition added was 5.29 ± 0.09 and 9.91 ± 0.11 g/L, while the total corresponding CO₂ bio-fixation was 9.70 ± 0.13 and 18.16 ± 0.11 g/L, respectively, during 15-day cultivation. The findings provide critical insights into enhancing CO₂ bio-fixation through adaptive evolution of ALE-Cv and offer optimal operational parameters for future large-scale microalgae cultivation. This research also links microalgae-based CO₂ sequestration to green technologies and the bioeconomy, highlighting its potential contribution to climate change mitigation while supporting environmental sustainability, food security, and ecosystem resilience.

The increasing use of automated feedback in education highlights the need for rigorous validation of AI-based assessment tools, particularly in performance-based domains such as dance. This study examined the validity of the Real-time Augmented Feedback in Learning Tool (ReAL-T), an AI-based scoring engine designed to support screen-based learning and assessment for beginner dancers. Twelve adult beginners completed a learning protocol involving four choreographies, generating 96 recall performances. Three expert choreographers independently rated each performance on a 1–5 scale for body line and form and precision, while ReAL-T generated parallel scores using the same criteria. Inter-rater reliability among choreographers was evaluated using intraclass correlation coefficients (ICCs) and Kendall’s coefficient of concordance (W). Agreement between expert ratings and ReAL-T was examined using ICCs and Kendall’s W on a combined overall score. Expert ratings demonstrated excellent agreement across both categories (single-rater ICCs ≥ 0.85; Kendall’s W ≥ 0.87). When ReAL-T was included as an additional rater, agreement remained high (single-measure ICC = 0.84; Kendall’s W = 0.89). These findings indicate that the ReAL-T minimum viable product produces automated scores that closely align with expert judgement, supporting its use as a validated automated feedback component for beginner dance education.