Bucket foundations have been widely used in marine engineering, such as offshore wind power, due to their anti-overturning performance and convenient installation. In China’s coastal areas, clay soil is widely distributed, and most of the seabed has layered clay. However, the bearing capacity of bucket foundations in layered soil is significantly different from that in homogeneous soil. Currently, there is relatively little research on the bearing capacity of bucket foundations in layered clay. Therefore, the finite element analysis method is adopted to establish a bearing capacity calculation method of bucket foundations in double-layer clay. The axial failure mechanisms and ultimate bearing capacity of bucket foundations in double-layer clay are deeply discussed, and the corresponding ultimate bearing capacity calculation method is given based on the numerical analysis results. The combined bearing capacity of bucket foundations in double-layer clay is fully analyzed, and the evolution method of V-H, V-M, H-M, and V-H-M failure envelopes is given.
The deep digitization of power system business faces three major challenges: computational resources are prone to crashes, business response is slow, and platform maintenance is unsustainable. To address these issues, this paper proposes a domain-specific cloud Business Operating System (BOS) for new power systems. BOS establishes a unified management paradigm for four core digital objects—Containers, Tasks, Programs, and Data—through their standardized definition and indexed organization. Building upon this foundation, it implements three dedicated plugins to enable synergistic task-container co-scheduling, plug-and-play program integration, and optimized data access. This paper elaborates on BOS’s architecture and its rationale as an operating system, detailing the key technologies for object management. Case studies on a real-world regional power grid demonstrate that BOS effectively ensures the efficient execution of large-scale computational tasks, supports the agile integration of domain-specific models and algorithms, achieves seamless and efficient data connectivity across business chains, thereby providing a robust foundation for next-generation power system digitization.
With the extension of average life expectancy, diseases accompanied by cognitive and memory impairments, such as dementia, are increasing. The risk of dementia has been suggested to decrease with an increase in the intake of milk and dairy products. Therefore, the present study investigated the effects of consuming test food containing lactononadecapeptide (LNDP) on memory and attention in healthy elderly Japanese subjects aged 65 years or older over 24 weeks. A placebo-controlled, double-blind, randomized trial was conducted, and memory function was evaluated using the Rey-Osterrieth Complex Figure (ROCF) test and the total score of the Symbol Digit Modalities Test (SDMT). Based on the results of the ROCF test and SDMT, the repeated intake of the test food significantly improved memory function in elderly subjects. Therefore, the repeated intake of test food containing LNDP may improve memory and attention in elderly Japanese individuals with mild cognitive decline.
Halide-chalcogenide compounds are promising candidates for thermoelectric applications owing to their low thermal conductivity and tunable electronic structures. Here, we systematically investigate Te-substituted BiSe1−xTexI (x = 0, 0.1, 0.3, 0.5). Structural and spectroscopic analyses confirm the successful incorporation of Te into the BiSeI-type framework, accompanied by lattice expansion, vibrational softening, and pronounced bandgap tuning. X-ray photoelectron spectroscopy verifies that Te occupies Se sites and modifies the local electronic environment, while electron microscopy reveals a morphology evolution from ribbon-like grains to plate-like and fragmented particles with increasing Te content. Thermoelectric measurements show that Te substitution simultaneously enhances electrical conductivity and suppresses thermal conductivity, arising from band-structure modulation, increased carrier concentration, mass fluctuation, and strengthened phonon scattering. Consequently, BiSe0.7Te0.3I achieves the highest ZT (~0.27 at 400 K), substantially higher than pristine BiSeI. This work demonstrates that heavy-element doping is an effective strategy for optimizing the thermoelectric performance of halide-chalcogenides.
Organic solar cells (OSCs) are attracting attention as a possible replacement for traditional photovoltaics because they are low-cost, lightweight, and have adjustable optoelectronic features. The commercialization of single-junction OSCs still faces challenges in achieving high power conversion efficiency (PCE) and operating stability. Recent developments in photonic crystals, plasmonics, nanophotonics, and metamaterials have significantly addressed these issues, especially in single-junction systems. This paper reviews the latest advancements in charge transport engineering, nanophotonic light-trapping methods, and nanostructured interfaces specifically designed for single-junction OSCs. It also highlights recent record-breaking efficiencies that exceed 20% PCE. We discussed integrating plasmonic nanoparticles, optical microcavities, nanostructured electrodes, and improved photonic materials to increase light absorption, exciton dissociation, and charge collection within the specific limitations of single-junction devices. Furthermore, we stress the important role of computational modeling and recent experimental breakthroughs in enhancing optical and electrical performance. Rather than treating optical and electrical processes independently, this review emphasizes the synergistic role of photonic enhancement strategies in simultaneously improving light trapping and charge transport, highlighting how nanophotonic designs influence carrier generation, recombination, and extraction in single-junction OSCs.
