Kinematic-mapping-model-guided analysis and optimization of 2-PSS&1-RR circular-rail parallel mechanism for fully steerable phased array antennas

This paper presents a systematic methodology for analyzing and optimizing an innovative antenna mount designed for phased array antennas, implemented through a novel 2-PSS&1-RR circular-rail parallel mechanism. Initially, a comparative motion analysis between the 3D model of the mount and its full-scale prototype is conducted to validate effectiveness. Given the inherent complexity, a kinematic mapping model is established between the mount and the crank-slider linkage, providing a guiding framework for subsequent analysis and optimization. Guided by this model, feasible inverse and forward solutions are derived, enabling precise identification of stiffness singularities. The concept of singularity distance is thus introduced to reflect the structural stiffness of the mount. Subsequently, also guided by the mapping model, a heuristic algorithm incorporating two backtracking procedures is developed to reduce the mount's mass. Additionally, a parametric finite-element model is employed to explore the relation between singularity distance and structural stiffness. The results indicate a significant reduction(about 16%) in the antenna mount's mass through the developed algorithm, while highlighting the singularity distance as an effective stiffness indicator for this type of antenna mount.

TiO_(2)@C catalyzed hydrogen storage performance of Mg-Ni-Y alloy with LPSO and ternary eutectic structure

A designed Mg_(88.7)Ni_(6.3)Y_(5)hydrogen storage alloy containing 14H type LPSO(long-period stacking ordered)and ternary eutectic structure was prepared by regulating the alloy composition and casting.The hydrogen storage performance of the alloy was improved by adding nano-flower-like TiO_(2)@C catalyst.The decomposition of the LPSO structure during hydrogenation led to the formation of plenty of nanocrystals which provided abundant interphase boundaries and activation sites.The nanoscale TiO_(2)@C catalyst was uniformly dispersed on the surface of alloy particles,and the"hydrogen overflow''effect of TiO_(2)@C accelerated the dissociation and diffusion of hydrogen on the surface of the alloy particles.As a result,the in-situ endogenous nanocrystals of the LPSO structure decomposition and the externally added flower-like TiO_(2)@C catalyst uniformly dispersed on the surface of the nanoparticles played a synergistic catalytic role in improving the hydrogen storage performance of the Mg-based alloy.With the addition of the TiO_(2)@C catalyst,the beginning hydrogen desorption temperature was reduced to 200℃.Furthermore,the saturated hydrogen absorption capacity of the sample was 5.32 wt.%,and it reached 4.25 wt.%H_(2) in 1 min at 200℃and 30 bar.

A Two-step Inverse Method for Quantitative Damage Evaluation of Plate-like Structures Using Vibration Approach

This study presents a novel two-step approach to assess plate-like structural laminar damages,particularly for delamination damage detection of composite structures.Firstly,a 2-D continuous wavelet transform is employed to identify the damage location and sizes from vibration curvature data.An inverse method is subsequently then used to determine the bending stiffness reduction ratio along a specified direction,enabling the quantification of the delamination severity.The method employed in this study is an extension of the one-dimensional inverse method developed in a previous work of the authors.The applicability of the two-step inverse approach is demonstrated in a simulation analysis and by an experimental study on a cantilever composite plate containing a single delamination.The inverse method is shown to have the capacity to reveal the detailed damage information of delamination within a constrained searching space and can be used to determine the effective flexural stiffness of composite plate structures,even in cases of complex delamination damage.

Clinical Study on the Effect of Acupuncture and Moxibustion with the Method of Acupoints on the Treatment of Chronic Gastritis with Sleep Disorder

Objective:To explore the clinical effect of acupuncture and moxibustion with acupoints on the treatment of chronic gastritis with sleep disorders.Methods:Sixty patients with chronic gastritis and sleep disorders in our hospital from January 2018 to January 2019 were selected and recruited.These patients were divided into two groups,namely the control group and experimental group by using random number table method.Each group consisted of 30 cases.The control group was treated with conventional drugs,whereas the observation group was treated with acupuncture and moxibustion with acupoints on top of the treatment prescribed for the patients in control group.The TCM syndrome score,gastrin level,and sleep quality level were compared between the two groups.Results:After four weeks of treatment,the Traditional Chinese Medicine(TCM)symptom score,gastrin level,and Pittsburgh Sleep Quality Index(PSQI)score in the observation group were lower than those in the control group,and the differences were statistically significant(P<0.05).Conclusion:Acupuncture and moxibustion with acupoints can improve TCM symptom scores,reduce gastrin levels,and improve sleep quality in patients with chronic gastritis and sleep disorders.

Impacts of silencing CD105 and Ki67 gene expression on the biological behavior of ovarian cancer OVCAR3 cells

Objective: To investigate the effect of silencing CD105 and Ki67 gene expression on OVCAR3 cell line in ovarian cancer. Methods: According to cell transfection results, OVCAR3 cells were divided into CD105-siRNA, Ki67-siRNA, CD105-siRNA+ Ki67-siRNA, negative control (NC1 and NC2) and control (non-transfection) groups. The effect of silencing CD105, Ki67 and their combined gene on proliferation, migration, invasion and apoptosis of human ovarian cancer cells can be studied and analyzed with MTT assay, wound-healing assay, Transwell chamber and flow cytometry. Results: Compared with their respective negative control and liposome control groups, proliferation, migration and invasion abilities of OVCAR3 cells were decreased obviously in CD105-siRNA, Ki67-siRNA and CD105-siRNA + Ki67-siRNA groups after gene silencing. Whereas, the most significant change was detected in CD105-siRNA + Ki67-siRNA group along with obviously increased apoptosis rate of cancer cells, and the differences were of statistical significance (p < .01, p < .05). Conclusions: Expression vectors of CD105-siRNA and Ki67-siRNA can inhibit the proliferation of OVCAR3 cells, reduce their abilities of migration and invasion, and induce apoptosis of tumor cells. The effect of combined gene silence will be more significant.

Unveiling the innovative green synthesis mechanism of selenium nanoparticles by exploiting intracellular protein elongation factor Tu from Bacillus paramycoides

Selenium nanoparticles(SeNPs)have garnered extensive research interest and shown promising applications across diverse fields owing to their distinctive properties,including antioxidant,anticancer,and antibacterial activity(Ojeda et al.,2020;Qu et al.,2023;Zambonino et al.,2021,2023).Among the various approaches employed for SeNP synthesis,green synthesis has emerged as a noteworthy and eco-friendly methodology.Keshtmand et al.(2023)underscored the significance of green-synthesized SeNPs,presenting a compelling avenue in this domain.This innovative strategy harnesses the potential of natural resources,such as plant extracts or microorganisms,to facilitate the production of SeNPs.

A novel surgical technique of internal limiting membrane peeling for high myopic foveoschisis:a wide range of whole piece consecutive peeling without preservation of epi-fovea

AIM:To demonstrate an improved surgical technique of whole piece consecutive internal limiting membrane(ILM) peeling without preservation of the epi-fovea to treat high myopic foveoschisis(MF).METHODS:A 23-gauge 3-port pars plana vitrectomy was performed on 16 patients with high MF.A parallel arc line along the vascular arcades was scraped out with a curved membrane scraper DSP.Next,an ILM forceps was used to catch hold of the incisal edge of the ILM flap,and the action of releasing and separating was subsequently taken toward the direction of the macular fovea.Next,the ILM forceps was used to grasp the released area,and the whole area coherent ILM peeling covering the macular fovea was implemented thereafter.Finally,the ILM was folded backwards and peeled off in the arc direction.RESULTS:At the final visit,the average central macular thickness decreased remarkably from 423.76±177.67 to 178.24±66.21 μm.The mean logarithm of the minimum angle of resolution best-corrected visual acuity of 1.37±0.59 was significantly alleviated to 0.74±0.59.CONCLUSION:The wide range of whole piece consecutive ILM peeling without preservation of the epifovea is proven to be effective and significantly reduced the occurrence of retinal tear and macular hole.

氨氢融合新能源交叉科学前沿战略研究

2022年3月23日,国家发展和改革委员会、国家能源局联合印发《氢能产业发展中长期规划(2021~2035年)》,明确了氢能是国家能源体系的重要组成部分.最近20多年来,氢能基础设施建设、氢能关键材料与核心部件、氢能汽车产业发展、氢能储运技术等方面国内外取得了长足的进展.但目前在世界范围内,氢能产业发展仍然面临着氢跨区域、高安全、低成本、大规模储运难的重大瓶颈^([1~4]).

The effect of surface electronic structures of Au/TiO_2 on sonophotochemical reactions

Sonophotocatalysis combines ultrasonic and light irradiations to drastically boost the chemical reaction rate and has attracted many interests for its potential applications in the environmental remediation and protection. However, it still remains unclear whether the light irradiation could couple with the ultrasound to prompt the sonophotocatalytic process. Here, we selectively excited the TiO2 and Au to manipulate the electronic structures of Au/TiO2 and studied their influence in sonophotocatalytic water（H2 O） reduction. Surprisingly, no significant increase of the hydrogen（H2） production rate was observed under either the UV light irradiation or the visible light irradiation, suggesting that the change in electronic structures of Au/TiO2 does not prompt the generation of free radicals under sonication and the reaction is dominated by the recovery of active sites through ultrasound. Our findings established an indepth understanding of the origin of the enhanced catalytic activity in sonophotocatalysis.

A critical review of key materials and issues in solid oxide cells

Solid oxide cells(SOCs)are all solid ceramic devices with the dual functionality of solid oxide fuel cells(SOFCs)to convert the chemical energy of fuels like H2,natural gas and other hydrocarbons to electricity and of solid oxide electrolysis cells(SOECs)to store renewable electric energy of sun and wind in hydrogen fuel.Among the electrochemical energy conversion and storage devices,SOCs are the most clean and efficient technology with unique dual functionality.Due to the high operation temperature(typically 600–800°C),SOCs exhibit many advantages over other energy conversion devices,such as low material cost,high efficiency and fuel flexibility.There has been rapid development of SOC technologies over the last decade with significant advantages and progress in key materials and a fundamental understanding of key issues such as an electrode,electrolyte,performance degradation,poisoning,and stack design.The reversible polarization also has a critical effect on the surface segregation and stability of the electrode and electrode/electrolyte interface.This critical review starts with a brief introduction,working principles and thermodynamics of SOC technology to readers with interests in this rapidly developing and emerging field.Then the key materials currently used in SOCs are summarized,followed by the discussion of the most advanced electrode modification methods and critical issues of SOCs,including the surface chemistry,segregation,electrode/electrolyte interface and varying material degradation mechanisms under reversible operations.The challenges and prospects of SOC technology for future developments are discussed.

Double-uncertainty optimal operation of hybrid AC/DC microgrids with high proportion of intermittent energy sources

This paper applies double-uncertainty optimization theory to the operation of AC/DC hybrid microgrids to deal with uncertainties caused by a high proportion of intermittent energy sources.A fuzzy stochastic expectation economic model for day-ahead scheduling based on uncertain optimization theory is proposed to minimize the operational costs of hybrid AC/DC microgrids.The fuzzy stochastic alternating direction multiplier method is proposed to solve the double-uncertainty optimization problem.A real-time intra-day unbalanced power adjustment model is established to minimize real-time adjustment costs.Through comparative analysis of deterministic optimization,stochastic optimization and fuzzy stochastic optimization of day-ahead scheduling and real-time adjustment,the validity of fuzzy stochastic optimization based on a fuzzy stochastic expectation model is proved.

Deformation Behavior of Fe-36Ni Steel during Cryogenic( 123-173 K) Rolling

Microstructural evolution and mechanical properties of cryogenic rolled Fe-36Ni steel were investigated. The annealed Fe-36Ni steel was rolled at cryogenic temperature（ 123-173 K） with 20%- 90% rolling reduction in thickness.The deformation process was accompanied by twinning at cryogenic temperature,and the mean thickness of deformation twins was about 200 nm with 20% rolling reduction. When the rolling reduction was above 40%,twinning was suppressed due to the stress concentration in the tested steel. Deformation microstructure of Fe-36Ni steel consisted of both twin boundaries and dislocations by cryogenic rolling（ CR）,while it only contained dislocations after rolling at room temperature（ RT）. The tensile strength of Fe-36Ni steel was improved to 930 MPa after 90% reduction at cryogenic temperature,while the tensile strength after 90% reduction at RT was only 760 MPa. More dislocations could be produced as the nucleation sites of recrystallization during CR process.

Quantifying Hypochlorous Acid Concentration in Environmental Water Using Smartphone Colorimetry

In this study,we developed an eff ective method to detect hypochlorite acid(HClO)by using methylene blue(MB)derivative(BPY1).BPY1 was selectively oxidized through HClO,and the solution color changed from colorless to blue.In the presence of HClO,the ultraviolet–visible(UV–vis)spectra and concentration of HClO had a linear relationship with a detection limit of 0.5μM.Furthermore,a test paper for HClO monitoring was successfully prepared using the BPY1 probe,and the observed detection limit by the naked eye was estimated at 5μM.Additionally,using the BPY1 probe,HClO could also be detected through smartphone colorimetry,and the method showed a good recovery ranging from 98.7 to 104.0%for HClO detection in an actual water sample.Especially for developing countries,such a low-cost and highly sensitive detection method provides a simple and practical method for monitoring HClO in water.

RNA-binding motif protein RBM47 promotes tumorigenesis in nasopharyngeal carcinoma through multiple pathways

RNA binding motif proteins(RBMs)have been widely implicated in the tumorigenesis of multiple human cancers but scarcely studied in nasopharyngeal carcinoma(NPC).Here,we compare the m RNA levels of 29 RBMs between 87 NPC and 10 control samples.We find that RBM47 is frequently upregulated in NPC specimens,and its high expression is associated with the poor prognosis of patients with NPC.Biological experiments show that RBM47 plays an oncogenic role in NPC cells.Mechanically,RBM47 binds to the promoter and regulates the transcription of BCAT1,and its overexpression partially rescues the inhibitory effects of RBM47-knockdown on NPC cells.Moreover,transcriptome analysis reveals that RBM47 regulates alternative splicing of pre-m RNA,including those cancer-related,to a large extent in NPC cells.Furthermore,RBM47 binds to hnRNPM and cooperatively regulates multiple splicing events in NPC cells.In addition,we find that knockdown of hnRNPM inhibits proliferation and migration of NPC cells.Our study,taken together,shows that RBM47 promotes the progression of NPC through multiple pathways,acting as a transcriptional factor and a modulator of alternative splicing in cooperation with hnRNPM.Our study also highlights that RBM47 and hnRNPM could be prognostic factors and potential therapeutic targets for NPC.

The stability of FKBP9 maintained by BiP is crucial for glioma progression

FK506-binding protein 9(FKBP9)is involved in tumor malignancy by resistance to endoplasmic reticulum(ER)stress,and the up-regulation of FKBP9 is associated with patients'poor prognosis.The current knowledge of the molecular mechanisms is still limited.One pre-vious study showed that FKBP9 could confer glioblastoma cell resistance to ER stress through ASK1-p38 signaling.However,the upstream regulatory mechanism of FKBP9 expression is still indistinct.In this study,we identified the FKBP9 binding proteins using co-immunoprecipitation followed by mass spectrometry.Results showed that FKBP9 interacted with the binding immu-noglobulin protein(BiP).BiP bound directly to FKBP9 with high affinity.BiP prolonged the half-life of the FKBP9 protein and stabilized the FKBP9 protein.BiP and FKBP9 protein levels were positively correlated in patients with glioma,and patients with high expression of BiP and FKBP9 showed a worse prognosis.Further studies showed that FKBP9 knockout in genetically engineered mice inhibited intracranial glioblastoma formation and prolonged survival by decreasing cellular proliferation and ER stress-induced CHOP-related apoptosis.Moreover,normal cells may depend less on FKBP9,as shown by the absence of apoptosis upon FKBP9 knockdown in a non-transformed human cell line and overall normal development in homozygous knockout mice.These findings suggest an important role of BiP-regulated FKBP9-associated signaling in glioma progression and the BiP-FKBP9 axis may be a potential therapeutic target forglioma.

A positive feedback loop between PLD1 and NF-κB signaling promotes tumorigenesis of nasopharyngeal carcinoma

Phospholipase D(PLD)lipid-signaling enzyme superfamily has been widely implicated in various human malignancies,but its role and underlying mechanism remain unclear in nasopharyngeal carcinoma(NPC).Here,we analyze the expressions of 6 PLD family members between 87 NPC and 10 control samples through transcriptome analysis.Our findings reveal a notable upregulation of PLD1 in both NPC tumors and cell lines,correlating with worse disease-free and overall survival in NPC patients.Functional assays further elucidate the oncogenic role of PLD1,demonstrating its pivotal promotion of critical tumorigenic processes such as cellproliferation and migration in vitro,as well as tumor growth in vivo.Notably,our study uncovers a positive feedback loop between PLD1 and the NF-κB signaling pathway to render NPC progression.Specifically,PLD1 enhances NF-kB activity by facilitating the phosphorylation and nuclear translocation of RELA,which in turn binds to the promoter of PLD1,augmenting its expression.Moreover,RELA over-expression markedly rescues the inhibitory effects in PLD1-depleted NPC cells.Importantly,the application of the PLD1 inhibitor,VU0155069,substantially inhibits NPC tumorigenesis in a patient-derived xenograft model.Together,our findings identify PLD1/NF-κB signaling as a positive feedback loop with promising therapeutic and prognostic potential in NPC.