Perovskite-polymer composite cross-linker approach for highly-stable and efficient perovskite solar cells.

Manipulation of grain boundaries in polycrystalline perovskite is an essential consideration for both the optoelectronic properties and environmental stability of solar cells as the solution-processing of perovskite films inevitably introduces many defects at grain boundaries. Though small molecule-based additives have proven to be effective defect passivating agents, their high volatility and diffusivity cannot render perovskite films robust enough against harsh environments. Here we suggest design rules for effective molecules by considering their molecular structure. From these, we introduce a strategy to form macromolecular intermediate phases using long chain polymers, which leads to the formation of a polymer-perovskite composite cross-linker. The cross-linker functions to bridge the perovskite grains, minimizing grain-to-grain electrical decoupling and yielding excellent environmental stability against moisture, light, and heat, which has not been attainable with small molecule defect passivating agents. Consequently, all photovoltaic parameters are significantly enhanced in the solar cells and the devices also show excellent stability

Serum Amino Acids in Association with Prevalent and Incident Type 2 Diabetes in A Chinese Population

We aimed to simultaneously examine the associations of both essential and non-essential amino acids with both prevalent and incident type 2 diabetes in a Chinese population. A case-control study was nested within the Singapore Chinese Health Study. Participants included 144 cases with prevalent and 160 cases with incident type 2 diabetes and 304 controls. Cases and controls were individually matched on age, sex, and date of blood collection. Baseline serum levels of 9 essential and 10 non-essential amino acids were measured using liquid chromatography tandem mass spectrometry. We identified that five essential (isoleucine, leucine, lysine, phenylalanine, and valine) and five non-essential (alanine, glutamic acid, glutamine, glycine, and tyrosine) amino acids were associated with the prevalence of type 2 diabetes; four essential (isoleucine, leucine, tryptophan, and valine) and two non-essential (glutamine and tyrosine) amino acids were associated with the incidence of type 2 diabetes. Of these, valine and tyrosine independently led to a significant improvement in risk prediction of incident type 2 diabetes. This study demonstrates that both essential and non-essential amino acids were associated with the risk for prevalent and incident type 2 diabetes, and the findings could aid in diabetes risk assessment in this Chinese population

Effect of Selective Encapsulation of Hydroxypropyl-β-cyclodextrin on Components and Antibacterial Properties of Star Anise Essential Oil

Star anise essential oil (SAEO) is a plant essential oil with good antibacterial activity, but its applications are limited due to its high volatility, strong smell, and unstable physical and chemical properties. The effect of selective encapsulation of SAEO by hydroxypropyl-β-cyclodextrin (HPCD) on its compositions, volatility stability and antibacterial activity was investigated. The GC-MS results indicated that the compositions reduced and content of the compositions of SAEO changed after encapsulation. Most of the components in SAEO were successfully encapsulated by HPCD, which can be supported by data from FTIR and 1H NMR. According to the molecular modeling results, the three guest molecules (trans-anethole, estragole and trans-foeniculin) were all docked in the cavity of HPCD on the isoallyl (or allyl) side. The volatile stability of SAEO before and after encapsulation was evaluated by electronic nose, and the results confirmed that encapsulation significantly reduced the irritating smell of SAEO and makes the clathrate have a sustained release effect. Furthermore, in the antibacterial test, the selective encapsulation of HPCD improved the inhibition effect of SAEO on Rhizopus stolonoifer, Saccharomyces cerevisiae, and E. coli and its antibacterial stability in 24 h

Enhanced continental weathering and its marine environmental effects in the late Devonian: Constraints from strontium isotopes of carbonate rocks in South China

The Frasnian-Famennian extinction in the late Devonian was one of the largest mass extinction during Earth's history, which was believed to be caused by the plant landing-indued intensification of terrestrial chemical weathering and the consequent hypoxia of marine water. However, direct evidence remains limited. Here, we apply strontium (Sr) concentrations and isotopes (87Sr/86Sr) as well as uranium-thorium ratios (U/Th) of shallow marine carbonate rocks that are widely developed in the Guangxi area to explore the rate of continental chemical weathering and the redox condition of seawater from the middle devonian to lower Carboniferous. The results show that, the intensification of terrestrial chemical weathering in the late Devonian (early Famennian) caused the increase of Sr concentration and the enrichment of heavy Sr isotopes in seawater. The low U/Th ratio in carbonate also suggests that the water was highly hypoxia during this period. Uranium in seawater was reduced and deposited in sediments, resulting in the decrease of U concentration in seawater. The intensification of chemical weathering on land surface has a significant influence on the fluctuation of redox conditions and the extinction of marine organisms in the late Devonian

Ultimate Bearing Capacity of Bottom Sealing Concrete in Underwater Deep Foundation Pit: Theoretical Calculation and Numerical Analysis

The cofferdam method is generally applied in the construction of underwater pier foundation in bridge engineering, and the pouring of bottom sealing concrete is one of the important links in the construction of the cofferdam. The bottom sealing concrete can prevent water seepage and balance the main body of the cofferdam, and its structural size and construction quality have a great influence on the above functions. Under the condition of large water level difference, it is difficult to determine the reasonable thickness of the bottom sealing concrete. There are few related studies in this field, and there is a lack of systematic summary of calculation theory. This work theoretically deduces the approximate solution of ultimate bending moment and ultimate stress of the bottom sealing concrete, introduces two different calculation methods, systematically summarizes the calculation methods of three kinds of ultimate stress, analyzes the calculation methods of ultimate bonding force, and uses ANSYS finite element software to simulate a specific bottom sealing concrete model, and compares it with the theoretical calculation results. The maximum stress obtained by the approximate solution is closer to the actual monitoring data than the traditional method, and the calculation method of the bonding force can be used to make a rough estimate

Analysis and Comparison of Digestive, Antioxidant, Nonspecific Immunity and Metabolic Enzyme Activities of Coilia nasus Cultured in Brackish Water and Freshwater

Coilia nasus is a precious migratory fish typical to the Yangtze River Basin of China. It is locally referred to as the "Three delicious fish of the Yangtze River, " with its fresh meat being particularly delicious and popular. In recent years, wild C. nasus numbers in the Yangtze River Basin have been decreasing due to environmental changes and illegal overfishing, among other reasons. To attenuate the availability of C. nasus, the Shanghai Fisheries Research Institute has successfully established an indoor artificial breeding and pond culture program in 2011. The research and development of C. nasus artificial breeding technologies have steadily progressed, though the artificial breeding yield of C. nasus remains relatively low. In addition, related research on the artificial cultivation of C. nasus is still in its infancy. Research on C. nasus in China and abroad mainly focuses on gonad development, breeding technology, muscle nutrient composition, and growth performance. No reports exist on the effects of brackish water culture conditions on the physiology of C. nasus. Given its economic importance, it would be of great value to evaluate the changes in the digestive, antioxidant, nonspecific immune capacity, and metabolic rates of C. nasus from brackish water (natural seawater in Hangzhou Bay, salinity 8.7~12.5) to freshwater aquaculture, to determine the breeding conditions of C. nasus, and to improve the artificial breeding yield and related technology. To investigate the differences in digestive capacity, antioxidant capacity, nonspecific immune capacity, and metabolic rates of C. nasus in brackish water and freshwater aquaculture conditions, the experiment adopted the pond interbreeding method. Two groups were established: A brackish aquaculture group and a freshwater aquaculture group (control group). Each group was housed in a single aquaculture pond with an area of 0.17 hm2. 500 C. nasus were stocked in each pond and moved to a Takifugu obscurus pond for a seven-month aquaculture experiment. At the end of the experiment, 12 C. nasus were randomly selected from each group and randomly divided into three replicates. Four C. nasus samples were selected from each replicate. The liver, intestine, stomach, and cecum of C. nasus were dissected on an ice plate and carefully removed to prepare a 10% homogenate. The activities of digestive enzymes, antioxidant enzymes, nonspecific immune enzymes, and metabolic enzymes and the total protein content were measured using a kit produced by the Nanjing Jiancheng Bioengineering Institute. The activities of digestive enzymes, antioxidant enzymes, nonspecific immunity enzymes, and metabolic enzymes in brackish water and freshwater aquaculture environments were compared and analyzed in a seven-month aquaculture experiment using the same batch of artificially bred C. nasus. The growth and survival rates of C. nasus cultured in brackish water (hereafter referred to as brackish water C. nasus) were significantly higher than that in the freshwater (hereafter referred to as freshwater C. nasus) (P 0.05). The activities of protease in the liver and stomach were significantly higher than those in freshwater C. nasus (P intestine > stomach > liver, while the order of LPS activity was intestine > cecum > stomach > liver. The order of AMS, protease, and LPS activity of freshwater C. nasus was: cecum > intestine > stomach > liver. Brackish water had significant effects on antioxidant, nonspecific immunity, and metabolic abilities, and the activities of superoxide dismutase (SOD), glutathione peroxidase (GSH-PX), and malondialdehyde (MDA) in the liver of C. nasus were significantly increased, while the activity of catalase (CAT) was significantly decreased (P < 0.05). The activities of alkaline phosphatase (AKP) and acid phosphatase (ACP) in the liver of C. nasus in brackish water were significantly lower than those in freshwater (P < 0.05). Brackish water had no significant effect on the activity of aspartate aminotransferase (AST), but it significantly reduced the activity of alanine aminotransferase (ALT). In summary, brackish water aquaculture conditions promoted the growth of C. nasus; increased the survival rate; improved the ability of C. nasus to digest protein and starch; improved the immunity of fish; and reduced the influence of external stresses by decreasing the activities of AKP, ACP, and ALT enzymes and increasing the activities of SOD and GSH-PX enzymes. This study also found that C. nasus living in brackish water, as a result of maintaining the internal osmotic balance, significantly reduced ALT enzyme activity and reduced urea production and emission, thereby reducing the pollution of the direct environment. Therefore, brackish water is more suitable for the aquaculture of C. nasus, and it is recommended that brackish water (salinity of 8.7~12.5) be used for aquaculture of 1+ age C. nasus individuals in the future. The results of this study provide a scientific basis for the improvement of artificial breeding technology, improving the yield of C. nasus, and the development of special compound feed for C. nasus

NaCa4V5O17: A low-firing microwave dielectric ceramic with low permittivity and chemical compatibility with silver for LTCC applications

Phase formation, crystal structure and dielectric properties of NaCa4V5O17 ceramics fabricated via a solid state reaction route at relatively low temperatures (780-860 °C) were investigated. NaCa4V5O17 crystallizes in a triclinic structure. Dielectric properties were measured based on the Hakki-Coleman post resonator method at microwave frequency. Specially, a specimen sintered at 840 °C demonstrated balanced dielectric properties with a permittivity εr = 9.72, a quality factor Q×f = 51,000 GHz, and a temperature coefficient of resonance frequency τf = -84 ppm/°C. NaCa4V5O17 ceramics showed excellent chemical compatibility with Ag metal electrodes. Besides, the thermal stability of resonance frequency was effectively adjusted through formation of composite ceramics between NaCa4V5O17 and TiO2 and a near-zero τf ∼ 1.3 ppm/°C accompanied with εr = 14.9 and Q×f = 19,600 GHz was achieved when 50% mol TiO2 was added. All the merits render NaCa4V5O17 a potential candidate for multilayer electronic devices