By manipulating the distribution of surface electrons,defect engineering enables effective control over the adsorption energy between adsorbates and active sites in the CO_(2)reduction reaction(CO_(2)RR).Herein,we rep...By manipulating the distribution of surface electrons,defect engineering enables effective control over the adsorption energy between adsorbates and active sites in the CO_(2)reduction reaction(CO_(2)RR).Herein,we report a hollow indium oxide nanotube containing both oxygen vacancy and sulfur doping(V_o-Sx-In_(2)O_(3))for improved CO_(2)-to-HCOOH electroreduction and Zn-CO_(2)battery.The componential synergy significantly reduces the*OCHO formation barrier to expedite protonation process and creates a favorable electronic micro-environment for*HCOOH desorption.As a result,the CO_(2)RR performance of Vo-Sx-In_(2)O_(3)outperforms Pure-In_(2)O_(3)and V_o-In_(2)O_(3),where V_o-S53-In_(2)O_(3)exhibits a maximal HCOOH Faradaic efficiency of 92.4%at-1,2 V vs.reversible hydrogen electrode(RHE)in H-cell and above 92%over a wide window potential with high current density(119.1 mA cm^(-2)at-1.1 V vs.RHE)in flow cell.Furthermore,the rechargeable Zn-CO_(2)battery utilizing V_o-S53-In_(2)O_(3)as cathode shows a high power density of 2.29 mW cm^(-2)and a long-term stability during charge-discharge cycles.This work provides a valuable perspective to elucidate co-defective catalysts in regulating the intermediates for efficient CO_(2)RR.展开更多
Photodegradation of nonylphenol ethoxylates (NPloEO) was investigated in laboratory scale under UV irradiation. The intermediate photodegradation products were analyzed by LC-ESI-MS. Three kinds of intermediate prod...Photodegradation of nonylphenol ethoxylates (NPloEO) was investigated in laboratory scale under UV irradiation. The intermediate photodegradation products were analyzed by LC-ESI-MS. Three kinds of intermediate products including aldehydic compounds, carboxylic compounds and cyclohexanyl compounds were identified. Five main degradation routes involving the oxidation of the alkyl chain and ethoxylate unit, shortening of the alkyl chain and ethoxylate unit, hydrogenation of the benzene ring were proposed.展开更多
In two cases that upstream and downstream firms have the decision power of intermediate product prices in a two-level supply chain,the dynamic pricing mechanism of intermediate products is studied.When a party who has...In two cases that upstream and downstream firms have the decision power of intermediate product prices in a two-level supply chain,the dynamic pricing mechanism of intermediate products is studied.When a party who has the decision power of pricing gives prices of intermediate products,the other side will give the supply or demand quantity of intermediate products which maximizes its own profits,then the party who decides price has two pricing strategies.One uses the matching price which meets the other party's demand or supply needs according to the prices of intermediate products in the next cycle.The other uses the convex combinations of the current price and the matching price which satisfies the other party's demand or supply as the price of the intermediate product in the next cycle.No matter which side has the decision power of intermediate product prices between upstream and downstream firms,results show that in the first pricing strategy,only in one case of the pricing of intermediate products stable;but in the second pricing strategy,both of the cases of pricing of intermediate products are stable in a certain field of combined parameters.展开更多
Electrochemical CO2 reduction is a promising strategy for the utilization of CO2 and intermittent excess electricity.Cu is the only single metal catalyst that can electrochemically convert CO2 into multicarbon product...Electrochemical CO2 reduction is a promising strategy for the utilization of CO2 and intermittent excess electricity.Cu is the only single metal catalyst that can electrochemically convert CO2 into multicarbon products.However,Cu exhibits an unfavorable activity and selectivity for the generation of C2 products because of the insufficient amount of CO*provided for the C‐C coupling.Based on the strong CO2 adsorption and ultrafast reaction kinetics of CO*formation on Pd,an intimate CuPd(100)interface was designed to lower the intermediate reaction barriers and improve the efficiency of C2 product formation.Density functional theory(DFT)calculations showed that the CuPd(100)interface enhanced the CO2 adsorption and decreased the CO2*hydrogenation energy barrier,which was beneficial for the C‐C coupling.The potential‐determining step(PDS)barrier of CO2 to C2 products on the CuPd(100)interface was 0.61 eV,which was lower than that on Cu(100)(0.72 eV).Encouraged by the DFT calculation results,the CuPd(100)interface catalyst was prepared by a facile chemical solution method and characterized by transmission electron microscopy.CO2 temperature‐programmed desorption and gas sensor experiments further confirmed the enhancement of the CO2 adsorption and CO2*hydrogenation ability of the CuPd(100)interface catalyst.Specifically,the obtained CuPd(100)interface catalyst exhibited a C2 Faradaic efficiency of 50.3%±1.2%at‒1.4 VRHE in 0.1 M KHCO3,which was 2.1 times higher than that of the Cu catalyst(23.6%±1.5%).This study provides the basis for the rational design of Cu‐based electrocatalysts for the generation of multicarbon products by fine‐tuning the intermediate reaction barriers.展开更多
Production of biodiesel with supercritical methanol is a green synthesis process.A study was carried out in a vertical tubular reactor with a length of 3700 mm and a diameter of 20 mm at 275-375°C,15 MPa,and mola...Production of biodiesel with supercritical methanol is a green synthesis process.A study was carried out in a vertical tubular reactor with a length of 3700 mm and a diameter of 20 mm at 275-375°C,15 MPa,and molar ratio of methanol to soybean oil of 40︰1.The phase holdup,intermediate product,yield and axial distribution of methyl ester(ME) were investigated.Methanol and oil were mixed non-uniformly due to the formation of biodiesel and difference in their densities,even when the reaction system was in the supercritical state.From top to bottom,the phase holdup of methanol increased and that of oil decreased.As temperature increased,the concentrations of monoglyceride and diglyceride decreased gradually and the ME yield increased.When the temperature reached 300°C,the critical temperature of the system,the ME yield was 50%.Further increase in temperature led to a sharp in-crease of ME yield.However,at 375°C after 1200 s of reaction time,the decomposition rate of ME was greater than its formation rate,reducing the ME yield.展开更多
Excess greenhouse gas emissions,primarily carbon dioxide(CO_(2)),have caused major environmental concerns worldwide.The electroreduction of CO_(2)into valuable chemicals using renewable energy is an ecofriendly approa...Excess greenhouse gas emissions,primarily carbon dioxide(CO_(2)),have caused major environmental concerns worldwide.The electroreduction of CO_(2)into valuable chemicals using renewable energy is an ecofriendly approach to achieve carbon neutrality.In this regard,copper(Cu)has attracted considerable attention as the only known metallic catalyst available for converting CO_(2)to high-value multicarbon(C_(2+))products.The production of C_(2+)involves complicated C-C coupling steps and thus imposes high demands on intermediate regulation.In this review,we discuss multiple strategies for modulating intermediates to facilitate C_(2+)formation on Cu-based catalysts.Furthermore,several sophisticated in situ characterization techniques are outlined for elucidating the mechanism of C-C coupling.Lastly,the challenges and future directions of CO_(2)electroreduction to C_(2+)are envisioned.展开更多
Metal Sm has been widely used in making Al–Sm magnet alloy materials.Conventional distillation technology to produce Sm has the disadvantages of low productivity,high costs,and pollution generation.The objective of t...Metal Sm has been widely used in making Al–Sm magnet alloy materials.Conventional distillation technology to produce Sm has the disadvantages of low productivity,high costs,and pollution generation.The objective of this study was to develop a molten salt electrolyte system to produce Al–Sm alloy directly,with focus on the electrical conductivity and optimal operating conditions to minimize the energy consumption.The continuously varying cell constant(CVCC)technique was used to measure the conductivity for the Na3AlF6–AlF3–LiF–MgF2–Al2O3–Sm2O3electrolysis medium in the temperature range from 905 to 1055°C.The temperature(t)and the addition of Al2O3(W(Al2O3)),Sm2O3(W(Sm2O3)),and a combination of Al2O3and Sm2O3into the basic fluoride system were examined with respect to their effects on the conductivity(κ)and activation energy.The experimental results showed that the molten electrolyte conductivity increases with increasing temperature(t)and decreases with the addition of Al2O3or Sm2O3or both.We concluded that the optimal operation conditions for Al–Sm intermediate alloy production in the Na3AlF6–AlF3–LiF–MgF2–Al2O3–Sm2O3system are W(Al2O3)+W(Sm2O3)=3wt%,W(Al2O3):W(Sm2O3)=7:3,and a temperature of 965 to 995°C,which results in satisfactory conductivity,low fluoride evaporation losses,and low energy consumption.展开更多
Fracture(fault)reactivation can lead to dynamic geological hazards including earthquakes,rock collapses,landslides,and rock bursts.True triaxial compression tests were conducted to analyze the fracture reactivation pr...Fracture(fault)reactivation can lead to dynamic geological hazards including earthquakes,rock collapses,landslides,and rock bursts.True triaxial compression tests were conducted to analyze the fracture reactivation process under two different orientations of σ_(2),i.e.σ_(2) parallel to the fracture plane(Scheme 2)and σ_(2) cutting through the fracture plane(Scheme 3),under varying σ_(3) from 10 MPa to 40 MPa.The peak or fracture reactivation strength,deformation,failure mode,and post-peak mechanical behavior of intact(Scheme 1)and pre-fractured(Schemes 2 and 3)specimens were also compared.Results show that for intact specimens,the stress remains nearly constant in the residual sliding stage with no stick-slip,and the newly formed fracture surface only propagates along the σ_(2) direction when σ_(3) ranges from 10 MPa to 30 MPa,while it extends along both σ_(2) and σ_(3) directions when σ_(3) increases to 40 MPa;for the pre-fractured specimens,the fractures are usually reactivated under all the σ_(3) levels in Scheme 2,but fracture reactivation only occurs when σ_(3) is greater than 25 MPa in Scheme 3,below which new faulting traversing the original macro fracture occurs.In all the test schemes,both ε_(2) and ε_(3) experience an accumulative process of elongation,after which an abrupt change occurs at the point of the final failure;the degree of this change is dependent on the orientation of the new faulting or the slip direction of the original fracture,and it is generally more than 10 times larger in the slip direction of the original fracture than in the non-slip direction.Besides,the differential stress(peak stress)required for reactivation and the post-peak stress drop increase with increasing σ_(3).Post-peak stress drop and residual strength in Scheme 3 are generally greater than those in Scheme 2 at the same σ_(3) value.Our study clearly shows that intermediate principal stress orientation not only affects the fracture reactivation strength but also influences the slip deformation and failure modes.These new findings facilitate the mitigation of dynamic geological hazards associated with fracture and fault slip.展开更多
A series of true triaxial unloading tests are conducted on sandstone specimens with a single structural plane to investigate their mechanical behaviors and failure characteristics under different in situ stress states...A series of true triaxial unloading tests are conducted on sandstone specimens with a single structural plane to investigate their mechanical behaviors and failure characteristics under different in situ stress states.The experimental results indicate that the dip angle of structural plane(θ)and the intermediate principal stress(σ2)have an important influence on the peak strength,cracking mode,and rockburst severity.The peak strength exhibits a first increase and then decrease as a function ofσ2 for a constantθ.However,whenσ2 is constant,the maximum peak strength is obtained atθof 90°,and the minimum peak strength is obtained atθof 30°or 45°.For the case of an inclined structural plane,the crack type at the tips of structural plane transforms from a mix of wing and anti-wing cracks to wing cracks with an increase inσ2,while the crack type around the tips of structural plane is always anti-wing cracks for the vertical structural plane,accompanied by a series of tensile cracks besides.The specimens with structural plane do not undergo slabbing failure regardless ofθ,and always exhibit composite tensile-shear failure whatever theσ2 value is.With an increase inσ2 andθ,the intensity of the rockburst is consistent with the tendency of the peak strength.By analyzing the relationship between the cohesion(c),internal friction angle(φ),andθin sandstone specimens,we incorporateθinto the true triaxial unloading strength criterion,and propose a modified linear Mogi-Coulomb criterion.Moreover,the crack propagation mechanism at the tips of structural plane,and closure degree of the structural plane under true triaxial unloading conditions are also discussed and summarized.This study provides theoretical guidance for stability assessment of surrounding rocks containing geological structures in deep complex stress environments.展开更多
A TTT diagram for th ie precipitation formed at some intermediate temperatures through cooling from high lemperalure parenl phase in a Cu-27 27Zn-3.73Al allay is established by means of dilatormetric measurement.The m...A TTT diagram for th ie precipitation formed at some intermediate temperatures through cooling from high lemperalure parenl phase in a Cu-27 27Zn-3.73Al allay is established by means of dilatormetric measurement.The morphology and structure of transformation products formed at some intermediate tem peratures isothermally through cooling from high temperature parent phase and up-quenching from DO_(3) parent phase are studied by metallographic.X-ray and electron microscopy analyses.Three regions in the two separate C curves are obtained according to different morphology of precipitate:rod-like a,plate-like bainite and a rods,and bainite plates.Prolonged aging makes bainite plate change gradually into a whose lattice parameters are no different from that of a formed equilibriumly from parent phase.The structure is almost orthorhombic long period structure for bainites formed from B_(2) and DO_(3) parent phase,but monoclinic for martensite from DO_(3).They correspond to the overlapping and separating of(1210)and(2010)diffraction peaks respectively,showing the lower degree of ordering in bainite.展开更多
Intermediate filaments(IFs)in human cells are the products of six distinct gene families,all sharing homology in a core rod domain.These IFs assemble into non-polar polymers,providing cytoplasmic and nuclear mechanica...Intermediate filaments(IFs)in human cells are the products of six distinct gene families,all sharing homology in a core rod domain.These IFs assemble into non-polar polymers,providing cytoplasmic and nuclear mechanical support.Recent research has revealed the active and dynamic properties of IFs and their binding partners.This regulation extends beyond cell mechanics to include migration,mechanotransduction,and tumor growth.Therefore,this comprehensive review aims to catalog all human IF genes and IF-associated proteins(IFAPs),detailing their names,sizes,functions,associated human diseases,relevant literature,and links to resources like UniProt and the Protein Atlas database.These links provide access to additional information such as protein structure,subcellular localization,disease-causing mutations,and pathology.Using this catalog,we will provide an overview of the current understanding of the biological functions of IFs and IFAPs.This overview is crucial for identifying gaps in their characterization and understanding IF-mediated mechanotransduction.Additionally,we will consider potential future research directions.展开更多
Proton conducting ceramic cells(PCCs)are an attractive emerging technology operating in the intermediate temperature range of 500 to 700℃.In this work,we evaluate the production of hydrogen at intermediate temperatur...Proton conducting ceramic cells(PCCs)are an attractive emerging technology operating in the intermediate temperature range of 500 to 700℃.In this work,we evaluate the production of hydrogen at intermediate temperatures by proton conducting ceramic cell electrolysis(PCCEL).We demonstrate a highperformance steam electrolysis owing to a composite positrode based on BaGd_(0.8)La_(0.2)Co_(2)O_(6-δ)(BGLC1082)and BaZr0.5Ce0.4Y0.1O3-δ(BZCY541).The high reliability of PCCEL is demonstrated for 1680 h at a current density as high as-0.8 A cm^(-2)close to the thermoneutral cell voltage at 600℃.The electrolysis cell showed a specific energy consumption ranging from 54 to 66 kW h kg^(-1)that is comparable to state-of-the-art low temperature electrolysis technologies,while showing hydrogen production rates systematically higher than commercial solid oxide ceramic cells(SOCs).Compared to SOCs,the results verified the higher performances of PCCs at the relevant operating temperatures,due to the lower activation energy for proton transfer comparing with oxygen ion conduction.However,because of the p-type electronic conduction in protonic ceramics,the energy conversion rate of PCCs is relatively lower in steam electrolysis.The faradaic efficiency of the PCC in electrolysis mode can be increased at lower operating temperatures and in endothermic conditions,making PCCEL a technology of choice to valorize high temperature waste heat from industrial processes into hydrogen.To increase the faradaic efficiency by optimizing the materials,the cell design,or the operating strategy is a key challenge to address for future developments of PCCEL in order to achieve even more superior techno-economic merits.展开更多
Maintaining thermal stability is a key concern for the potential application of multi-principal-element alloys(MPEAs)at elevated temperatures,particularly in the intermediate temperature range.In this regime,the therm...Maintaining thermal stability is a key concern for the potential application of multi-principal-element alloys(MPEAs)at elevated temperatures,particularly in the intermediate temperature range.In this regime,the thermodynamic dominance of the entropy term over enthalpy may diminish,while atomic migration remains kinetically active.In this study,the stability of a series of refractory MPEAs(RMPEAs)from the subsystems of Ti-V-Zr-Nb-Hf-Ta is investigated at 550℃for 2-28 days.Although all eleven alloys exhibit a single solid solution phase with a body-centered cubic structure at their homogenized states,only two alloys,VNbTa and TiVNbTa,remain stable after annealing.Decomposition occurs in the other nine alloys under the spinodal manner or the nucleation and growth mechanism,including all three quinary alloys,demonstrating that configurational entropy is not a dominant factor.The phase stabilities can be well understood from the enthalpy perspectives,by combining first-principles calculations and semi-empirical models.By comparing the different contributors of formation enthalpy,the lattice distortion energy is found to be the most critical factor for this alloy system.Furthermore,the phases formed after long-term annealing are generally located at different regions in the space with the axes of chemical,structural,and lattice distortion energies.This work provides a way to interpret and control the stability of RMPEAs in the intermediate temperature regime.展开更多
This study investigates the dynamical behavior of two parallel fluid-conveying pipes by developing a non-planar dynamical model of the two pipes coupled with an intermediate spring. A systematic analysis is conducted ...This study investigates the dynamical behavior of two parallel fluid-conveying pipes by developing a non-planar dynamical model of the two pipes coupled with an intermediate spring. A systematic analysis is conducted to evaluate the effects of spring parameters on the non-planar vibration characteristics and buckling behaviors of the coupled system. The nonlinear governing equations are derived with Hamilton's principle,subsequently discretized through Galerkin's method, and finally numerically solved by the Runge-Kutta algorithm. Based on the linearized equations, an eigenvalue analysis is performed to obtain the coupled frequencies, modal shapes, and critical flow velocities for buckling instability. Quantitative assessments further elucidate the effects of the spring position and stiffness coefficient on the coupled frequencies and critical flow velocities.Nonlinear dynamic analyses reveal the evolution of buckling patterns and bifurcation behaviors between the lateral displacements of the two pipes and the flow velocity. Numerical results indicate that the intermediate spring increases the susceptibility to buckling instability in the out-of-plane direction compared with the in-plane direction. Furthermore, synchronized lateral displacements emerge in both pipes when the flow velocity of one pipe exceeds the critical threshold. This work is expected to provide a theoretical foundation for the stability assessment and vibration analysis in coupled fluid-conveying pipe systems.展开更多
BACKGROUND Diabetes and its associated microvascular complications,such as nephropathy and retinopathy,significantly impact global health.These complications often begin in the prediabetic stage,emphasizing the import...BACKGROUND Diabetes and its associated microvascular complications,such as nephropathy and retinopathy,significantly impact global health.These complications often begin in the prediabetic stage,emphasizing the importance of early detection and intervention.Inflammatory pathways are key contributors to these conditions,and recent research has identified members of the tumor necrosis factor(TNF)receptor superfamily as potential biomarkers.However,their association with renal and retinal dysfunction in individuals with intermediate hyperglycemia(IH)remains underexplored.The Early Prevention of Diabetes Complications(ePREDICE)trial provides a valuable cohort to investigate these associations and improve risk assessment strategies.AIM To identify inflammatory biomarkers associated with early renal and retinal dysfunction in individuals with IH.Specifically,we evaluate the diagnostic and prognostic potential of TNF receptor superfamily members[TNF receptor 1(TNF-R1),TNF receptor 2(TNF-R2)],T-cell immunoglobulin and mucin domain 3(TIM-3)/HAVCR2,galectin-3,and interleukin-6(IL-6)in detecting kidney dysfunction and retinopathy in this high-risk population.By understanding their roles,we seek to enhance early screening methods and inform personalized intervention strategies.METHODS A cross-sectional analysis of 967 individuals with IH from the ePREDICE trial was conducted.Participants underwent comprehensive anthropometric and biochemical assessments.Key inflammatory biomarkers,including TNF-R1,TNF-R2,TIM-3/HAVCR2,galectin-3,and IL-6,were quantified using immunoassays.Renal function was assessed using estimated glomerular filtration rate(eGFR)and albuminuria,while retinopathy was evaluated through fundoscopic examination.Statistical analyses included adjusted mean comparisons,correlation studies,and receiver operating characteristic curve analysis to assess biomarker diagnostic accuracy.RESULTS TNF-R1,TNF-R2,and TIM-3/HAVCR2 were significantly associated with reduced filtration function(eGFR<60 mL/minute/1.73 m^(2))and albuminuria,with area under the curve(AUC)values between 0.815 and 0.845.TIM-3/HAVCR2 emerged as the strongest predictor of retinopathy(AUC=0.737).Strong correlations(r>0.75)were observed among TNF-R1,TNF-R2,and TIM-3/HAVCR2,suggesting a coordinated role in inflammatory pathways.CONCLUSION Our findings highlight the potential of TNF receptor superfamily members as biomarkers for early-stage renal and retinal complications in individuals with IH.Their integration into clinical screening protocols could facilitate earlier detection,improving patient stratification and personalized management strategies.Further longitudinal studies are necessary to validate their predictive value and potential for guiding therapeutic interventions in IH and early diabetes management.展开更多
This article proposes an adaptive extended Kalman filter(EKF)for nonlinear cyber-physical systems(CPSs)under unknown inputs and non-Gaussian noises.It is known that the traditional extended Kalman filter is applicable...This article proposes an adaptive extended Kalman filter(EKF)for nonlinear cyber-physical systems(CPSs)under unknown inputs and non-Gaussian noises.It is known that the traditional extended Kalman filter is applicable to nonlinear systems with Gaussian white noise.The system is reformulated with intermediate variables to expand the application of nonlinear systems under unknown inputs and non-Gaussian noises,which help decompose unknown input estimation into residual tracking and state observation subproblems.By introducing the orthogonal principle of innovation and attenuation factor,the intermediate variables-based filter can improve the estimation performance under non-Gaussian noises and unknown inputs.Simulation results validate the effectiveness of the proposed method.展开更多
The deformation of Cu–20 wt.%Fe alloy wires leads to a significant improvement in mechanical properties and a decrease in electrical conductivity.Simultaneous improvements in strength and conductivity were achieved b...The deformation of Cu–20 wt.%Fe alloy wires leads to a significant improvement in mechanical properties and a decrease in electrical conductivity.Simultaneous improvements in strength and conductivity were achieved by intermediate annealing of drawn Cu–20 wt.%Fe wires.As the annealing temperature increased,the strength of Cu–20 wt.%Fe alloy wire decreased monotonically,but the electrical conductivity first increased and then decreased,reaching its peak value after annealing at 500℃.The decrease in strength is related to dislocation recovery and static recrystallization of Cu and Fe phases,and the increase in electrical conductivity mainly results from the aging precipitation of solid solution Fe.After annealing at 500℃,there was no obvious recrystallization of Cu phase,and many of the nano-Fe particles precipitated from Cu matrix.An annealing temperature of 600℃ induced the recrystallization of Cu matrix and an increase in Fe solid solubility,resulting in a decrease in strength and electrical conductivity.Subsequently,the wires annealed at 500℃ were drawn to 2 mm.Compared with those of the continuously drawn Cu–20 wt.%Fe alloy wires,the deformation ability,strength,and electrical conductivity of Cu–20 wt.%Fe alloy wires subjected to intermediate annealing treatment are significantly greater.This is mainly related to the sufficient precipitation of Fe in Cu matrix and the strengthening of refined Fe fibers parallel to the drawing direction.展开更多
Quasi-solid-state electrolytes,which integrate the safety characteristics of inorganic materials,the flexibility of polymers,and the high ionic conductivity of liquid electrolytes,represent a transitional solution for...Quasi-solid-state electrolytes,which integrate the safety characteristics of inorganic materials,the flexibility of polymers,and the high ionic conductivity of liquid electrolytes,represent a transitional solution for high-energy-density lithium batteries.However,the mechanisms by which inorganic fillers enhance multiphase interfacial conduction remain inadequately understood.In this work,we synthesized composite quasi-solid-state electrolytes with high inorganic content to investigate interfacial phenomena and achieve enhanced electrode interface stability.Li_(1.3)Al_(0.3)Ti_(1.7)(PO_(4))_(3)particles,through surface anion anchoring,improve Li^(+)transference numbers and facilitate partial dissociation of solvated Li^(+)structures,resulting in superior ion transport kinetics that achieve an ionic conductivity of 0.51 mS cm^(−1)at room temperature.The high mass fraction of inorganic components additionally promotes the formation of more stable interfacial layers,enabling lithium-symmetric cells to operate without short-circuiting for 6000 h at 0.1 mA cm^(−2).Furthermore,this system demonstrates exceptional stability in 5 V-class lithium metal full cells,maintaining 80.5%capacity retention over 200 cycles at 0.5C.These findings guide the role of inorganic interfaces in composite electrolytes and demonstrate their potential for advancing high-voltage lithium battery technology.展开更多
Addressing inadequate OH^(*)adsorption in Ru Co alloy catalysts is crucial for boosting intermediate coverage and redirecting the water-splitting pathway.Herein,the adaptive P sites were strategically incorporated to ...Addressing inadequate OH^(*)adsorption in Ru Co alloy catalysts is crucial for boosting intermediate coverage and redirecting the water-splitting pathway.Herein,the adaptive P sites were strategically incorporated to overcome the aforementioned challenge.The P sites,as potent OH^(*)adsorption centers,synergize with Co sites to promote water dissociation and enrich surrounding Ru sites with H*intermediates,thus triggering the Volmer-Tafel route for hydrogen evolution reaction(HER).Besides,during the oxygen evolution reaction(OER),the surface of P-Ru Co was reconstructed into Ru-doped Co OOH with anchored PO_(4)^(3-).These PO_(4)^(3-)not only circumvent the intrinsic OH^(*)adsorption limitations of Ru-Co OOH in the adsorbate evolution mechanism(AEM)by rerouting to a more expeditious lattice oxygen oxidation mechanism(LOM)but also improve the coverage of key oxygen-containing intermediates,significantly accelerating OER kinetics.Consequently,the P-Ru Co demonstrates exceptional bifunctional performance,with overpotentials of 29 m V for HER and 222 m V for OER at 10 m A cm^(-2).Remarkably,the mass activities of PRu Co for HER(5.48 A mg^(-1))and OER(2.13 A mg^(-1))are 6.2 and 11.2 times higher than those of its commercial counterparts(Ru/C for HER and RuO_(2)for OER),respectively.When integrated into an anionexchange-membrane electrolyzer,this catalyst achieves ampere-level current densities of 1.32 A cm^(-2)for water electrolysis and 1.23 A cm^(-2)for seawater electrolysis at 2.1 V,with a 500-h durability.展开更多
Background:Intermediate-risk prostate cancer(IR-PC)represents a heterogeneous group requiring nuanced treatment approaches,and recent advancements in radiotherapy(RT),androgen deprivation therapy(ADT),and prostatespec...Background:Intermediate-risk prostate cancer(IR-PC)represents a heterogeneous group requiring nuanced treatment approaches,and recent advancements in radiotherapy(RT),androgen deprivation therapy(ADT),and prostatespecific membrane antigen positron emission tomography(PSMA-PET/CT)imaging have prompted growing interest in personalized,risk-adapted management strategies.This study by the Turkish Society for Radiation Oncology aims to examine radiation oncologists’practices in managing IR-PC,focusing on RT and imaging modalities to identify trends for personalized treatments.Methods:A cross-sectional survey was conducted among Turkish radiation oncologists treating at least 50 prostate cancer(PC)cases annually.The 22-item questionnaire covered IR-PC management aspects such as risk stratification,imaging preferences,androgen deprivation therapy(ADT)use and duration,RT techniques,and treatment combinations.Anonymous responses were analyzed using descriptive statistics.Results:Thirty radiation oncologists participated,57%with over 20 years of experience.The median annual number of PC cases treated was 130.For risk stratification,43% followed the National Comprehensive Cancer Network(NCCN)guidelines,while 30%used the D’Amico classification.Imaging preferences revealed 47% favored PSMA-PET/CT.External beam RT was universally preferred,with 60% adopting ultra-hypofractionation.ADT was used by 97%,with 73% recommending it for unfavorable IR-PC cases.Short-term ADT(4–6 months)was the standard,administered concurrently with RT by 57%.Cardiovascular status influenced decisions for 97% of respondents,while 37% also considered patient age,preferences,and sexual health.Conclusions:This national survey demonstrates a shift toward personalized care in intermediate-risk prostate cancer in Turkey,marked by selective PSMA-PET/CT use,tailored ADT,and evolving radiotherapy practices.The findings underscore the importance of multidisciplinary collaboration—particularly between urologists and radiation oncologists—to optimize imaging integration and treatment outcomes.展开更多
基金supported by the Fundamental Research Funds for the Central Universities(22120230104).
文摘By manipulating the distribution of surface electrons,defect engineering enables effective control over the adsorption energy between adsorbates and active sites in the CO_(2)reduction reaction(CO_(2)RR).Herein,we report a hollow indium oxide nanotube containing both oxygen vacancy and sulfur doping(V_o-Sx-In_(2)O_(3))for improved CO_(2)-to-HCOOH electroreduction and Zn-CO_(2)battery.The componential synergy significantly reduces the*OCHO formation barrier to expedite protonation process and creates a favorable electronic micro-environment for*HCOOH desorption.As a result,the CO_(2)RR performance of Vo-Sx-In_(2)O_(3)outperforms Pure-In_(2)O_(3)and V_o-In_(2)O_(3),where V_o-S53-In_(2)O_(3)exhibits a maximal HCOOH Faradaic efficiency of 92.4%at-1,2 V vs.reversible hydrogen electrode(RHE)in H-cell and above 92%over a wide window potential with high current density(119.1 mA cm^(-2)at-1.1 V vs.RHE)in flow cell.Furthermore,the rechargeable Zn-CO_(2)battery utilizing V_o-S53-In_(2)O_(3)as cathode shows a high power density of 2.29 mW cm^(-2)and a long-term stability during charge-discharge cycles.This work provides a valuable perspective to elucidate co-defective catalysts in regulating the intermediates for efficient CO_(2)RR.
文摘Photodegradation of nonylphenol ethoxylates (NPloEO) was investigated in laboratory scale under UV irradiation. The intermediate photodegradation products were analyzed by LC-ESI-MS. Three kinds of intermediate products including aldehydic compounds, carboxylic compounds and cyclohexanyl compounds were identified. Five main degradation routes involving the oxidation of the alkyl chain and ethoxylate unit, shortening of the alkyl chain and ethoxylate unit, hydrogenation of the benzene ring were proposed.
基金The National Key Technology R&D Program of China during the 11th Five-Year Plan Period(No.2006BAH02A06)
文摘In two cases that upstream and downstream firms have the decision power of intermediate product prices in a two-level supply chain,the dynamic pricing mechanism of intermediate products is studied.When a party who has the decision power of pricing gives prices of intermediate products,the other side will give the supply or demand quantity of intermediate products which maximizes its own profits,then the party who decides price has two pricing strategies.One uses the matching price which meets the other party's demand or supply needs according to the prices of intermediate products in the next cycle.The other uses the convex combinations of the current price and the matching price which satisfies the other party's demand or supply as the price of the intermediate product in the next cycle.No matter which side has the decision power of intermediate product prices between upstream and downstream firms,results show that in the first pricing strategy,only in one case of the pricing of intermediate products stable;but in the second pricing strategy,both of the cases of pricing of intermediate products are stable in a certain field of combined parameters.
文摘Electrochemical CO2 reduction is a promising strategy for the utilization of CO2 and intermittent excess electricity.Cu is the only single metal catalyst that can electrochemically convert CO2 into multicarbon products.However,Cu exhibits an unfavorable activity and selectivity for the generation of C2 products because of the insufficient amount of CO*provided for the C‐C coupling.Based on the strong CO2 adsorption and ultrafast reaction kinetics of CO*formation on Pd,an intimate CuPd(100)interface was designed to lower the intermediate reaction barriers and improve the efficiency of C2 product formation.Density functional theory(DFT)calculations showed that the CuPd(100)interface enhanced the CO2 adsorption and decreased the CO2*hydrogenation energy barrier,which was beneficial for the C‐C coupling.The potential‐determining step(PDS)barrier of CO2 to C2 products on the CuPd(100)interface was 0.61 eV,which was lower than that on Cu(100)(0.72 eV).Encouraged by the DFT calculation results,the CuPd(100)interface catalyst was prepared by a facile chemical solution method and characterized by transmission electron microscopy.CO2 temperature‐programmed desorption and gas sensor experiments further confirmed the enhancement of the CO2 adsorption and CO2*hydrogenation ability of the CuPd(100)interface catalyst.Specifically,the obtained CuPd(100)interface catalyst exhibited a C2 Faradaic efficiency of 50.3%±1.2%at‒1.4 VRHE in 0.1 M KHCO3,which was 2.1 times higher than that of the Cu catalyst(23.6%±1.5%).This study provides the basis for the rational design of Cu‐based electrocatalysts for the generation of multicarbon products by fine‐tuning the intermediate reaction barriers.
基金Supported by the National Natural Science Foundation of China(20576105) the Natural Science Foundation of Hubei Province(2008CDA024) the Project of Academic Leaders in Wuhan(200851430490)
文摘Production of biodiesel with supercritical methanol is a green synthesis process.A study was carried out in a vertical tubular reactor with a length of 3700 mm and a diameter of 20 mm at 275-375°C,15 MPa,and molar ratio of methanol to soybean oil of 40︰1.The phase holdup,intermediate product,yield and axial distribution of methyl ester(ME) were investigated.Methanol and oil were mixed non-uniformly due to the formation of biodiesel and difference in their densities,even when the reaction system was in the supercritical state.From top to bottom,the phase holdup of methanol increased and that of oil decreased.As temperature increased,the concentrations of monoglyceride and diglyceride decreased gradually and the ME yield increased.When the temperature reached 300°C,the critical temperature of the system,the ME yield was 50%.Further increase in temperature led to a sharp in-crease of ME yield.However,at 375°C after 1200 s of reaction time,the decomposition rate of ME was greater than its formation rate,reducing the ME yield.
基金support of the National Natural Science Foundation of China(Nos.51972223,51932005 and 22109116)the Natural Science Foundation of Tianjin(No.20JCYBJC01550)+1 种基金the Fundamental Research Funds for the Cen-tral Universitiesthe Haihe Laboratory of Sustainable Chemical Transformations.
文摘Excess greenhouse gas emissions,primarily carbon dioxide(CO_(2)),have caused major environmental concerns worldwide.The electroreduction of CO_(2)into valuable chemicals using renewable energy is an ecofriendly approach to achieve carbon neutrality.In this regard,copper(Cu)has attracted considerable attention as the only known metallic catalyst available for converting CO_(2)to high-value multicarbon(C_(2+))products.The production of C_(2+)involves complicated C-C coupling steps and thus imposes high demands on intermediate regulation.In this review,we discuss multiple strategies for modulating intermediates to facilitate C_(2+)formation on Cu-based catalysts.Furthermore,several sophisticated in situ characterization techniques are outlined for elucidating the mechanism of C-C coupling.Lastly,the challenges and future directions of CO_(2)electroreduction to C_(2+)are envisioned.
基金financially supported by the National Natural Science Foundation of China(Nos.51564015 and 51674126)the Graduate Student Innovation Special Fund of Jiangxi Province(YC2015-B064)+2 种基金the Science and Technology Research Project of Jiangxi Department of Education(GJJ150664)the Outstanding Doctoral Dissertation Project Fund of JXUST(YB2016007)the Scientific Research Fund of JXUST(NSFJ2014-G09)
文摘Metal Sm has been widely used in making Al–Sm magnet alloy materials.Conventional distillation technology to produce Sm has the disadvantages of low productivity,high costs,and pollution generation.The objective of this study was to develop a molten salt electrolyte system to produce Al–Sm alloy directly,with focus on the electrical conductivity and optimal operating conditions to minimize the energy consumption.The continuously varying cell constant(CVCC)technique was used to measure the conductivity for the Na3AlF6–AlF3–LiF–MgF2–Al2O3–Sm2O3electrolysis medium in the temperature range from 905 to 1055°C.The temperature(t)and the addition of Al2O3(W(Al2O3)),Sm2O3(W(Sm2O3)),and a combination of Al2O3and Sm2O3into the basic fluoride system were examined with respect to their effects on the conductivity(κ)and activation energy.The experimental results showed that the molten electrolyte conductivity increases with increasing temperature(t)and decreases with the addition of Al2O3or Sm2O3or both.We concluded that the optimal operation conditions for Al–Sm intermediate alloy production in the Na3AlF6–AlF3–LiF–MgF2–Al2O3–Sm2O3system are W(Al2O3)+W(Sm2O3)=3wt%,W(Al2O3):W(Sm2O3)=7:3,and a temperature of 965 to 995°C,which results in satisfactory conductivity,low fluoride evaporation losses,and low energy consumption.
基金funding support from the National Nature Science Foundation of China(Grant No.42272334)the National Key Research and Development Program of China(Grant No.2022YFE0137200)the Taishan Scholars Program(Grant No.2019RKB01083).
文摘Fracture(fault)reactivation can lead to dynamic geological hazards including earthquakes,rock collapses,landslides,and rock bursts.True triaxial compression tests were conducted to analyze the fracture reactivation process under two different orientations of σ_(2),i.e.σ_(2) parallel to the fracture plane(Scheme 2)and σ_(2) cutting through the fracture plane(Scheme 3),under varying σ_(3) from 10 MPa to 40 MPa.The peak or fracture reactivation strength,deformation,failure mode,and post-peak mechanical behavior of intact(Scheme 1)and pre-fractured(Schemes 2 and 3)specimens were also compared.Results show that for intact specimens,the stress remains nearly constant in the residual sliding stage with no stick-slip,and the newly formed fracture surface only propagates along the σ_(2) direction when σ_(3) ranges from 10 MPa to 30 MPa,while it extends along both σ_(2) and σ_(3) directions when σ_(3) increases to 40 MPa;for the pre-fractured specimens,the fractures are usually reactivated under all the σ_(3) levels in Scheme 2,but fracture reactivation only occurs when σ_(3) is greater than 25 MPa in Scheme 3,below which new faulting traversing the original macro fracture occurs.In all the test schemes,both ε_(2) and ε_(3) experience an accumulative process of elongation,after which an abrupt change occurs at the point of the final failure;the degree of this change is dependent on the orientation of the new faulting or the slip direction of the original fracture,and it is generally more than 10 times larger in the slip direction of the original fracture than in the non-slip direction.Besides,the differential stress(peak stress)required for reactivation and the post-peak stress drop increase with increasing σ_(3).Post-peak stress drop and residual strength in Scheme 3 are generally greater than those in Scheme 2 at the same σ_(3) value.Our study clearly shows that intermediate principal stress orientation not only affects the fracture reactivation strength but also influences the slip deformation and failure modes.These new findings facilitate the mitigation of dynamic geological hazards associated with fracture and fault slip.
基金supports from the National Natural Science Foundation of China (Grant Nos.52004143 and 52374095)the open fund for the Laboratory of Mining Response and Disaster Prevention and Control in Deep Coal Mines (Grant No.SKLMRDPC21KF06).
文摘A series of true triaxial unloading tests are conducted on sandstone specimens with a single structural plane to investigate their mechanical behaviors and failure characteristics under different in situ stress states.The experimental results indicate that the dip angle of structural plane(θ)and the intermediate principal stress(σ2)have an important influence on the peak strength,cracking mode,and rockburst severity.The peak strength exhibits a first increase and then decrease as a function ofσ2 for a constantθ.However,whenσ2 is constant,the maximum peak strength is obtained atθof 90°,and the minimum peak strength is obtained atθof 30°or 45°.For the case of an inclined structural plane,the crack type at the tips of structural plane transforms from a mix of wing and anti-wing cracks to wing cracks with an increase inσ2,while the crack type around the tips of structural plane is always anti-wing cracks for the vertical structural plane,accompanied by a series of tensile cracks besides.The specimens with structural plane do not undergo slabbing failure regardless ofθ,and always exhibit composite tensile-shear failure whatever theσ2 value is.With an increase inσ2 andθ,the intensity of the rockburst is consistent with the tendency of the peak strength.By analyzing the relationship between the cohesion(c),internal friction angle(φ),andθin sandstone specimens,we incorporateθinto the true triaxial unloading strength criterion,and propose a modified linear Mogi-Coulomb criterion.Moreover,the crack propagation mechanism at the tips of structural plane,and closure degree of the structural plane under true triaxial unloading conditions are also discussed and summarized.This study provides theoretical guidance for stability assessment of surrounding rocks containing geological structures in deep complex stress environments.
基金supported by the National Natural Science Foundation
文摘A TTT diagram for th ie precipitation formed at some intermediate temperatures through cooling from high lemperalure parenl phase in a Cu-27 27Zn-3.73Al allay is established by means of dilatormetric measurement.The morphology and structure of transformation products formed at some intermediate tem peratures isothermally through cooling from high temperature parent phase and up-quenching from DO_(3) parent phase are studied by metallographic.X-ray and electron microscopy analyses.Three regions in the two separate C curves are obtained according to different morphology of precipitate:rod-like a,plate-like bainite and a rods,and bainite plates.Prolonged aging makes bainite plate change gradually into a whose lattice parameters are no different from that of a formed equilibriumly from parent phase.The structure is almost orthorhombic long period structure for bainites formed from B_(2) and DO_(3) parent phase,but monoclinic for martensite from DO_(3).They correspond to the overlapping and separating of(1210)and(2010)diffraction peaks respectively,showing the lower degree of ordering in bainite.
基金the National Natural Science Foundation of China(Grant No.32070777 to F.N.).
文摘Intermediate filaments(IFs)in human cells are the products of six distinct gene families,all sharing homology in a core rod domain.These IFs assemble into non-polar polymers,providing cytoplasmic and nuclear mechanical support.Recent research has revealed the active and dynamic properties of IFs and their binding partners.This regulation extends beyond cell mechanics to include migration,mechanotransduction,and tumor growth.Therefore,this comprehensive review aims to catalog all human IF genes and IF-associated proteins(IFAPs),detailing their names,sizes,functions,associated human diseases,relevant literature,and links to resources like UniProt and the Protein Atlas database.These links provide access to additional information such as protein structure,subcellular localization,disease-causing mutations,and pathology.Using this catalog,we will provide an overview of the current understanding of the biological functions of IFs and IFAPs.This overview is crucial for identifying gaps in their characterization and understanding IF-mediated mechanotransduction.Additionally,we will consider potential future research directions.
基金The China Scholarship Council is acknowledged for the doctoral scholarship of Haoyu Zheng(201806160173)The German Federal Ministry for Education and Research is acknowledged for funding via the Project ARCADE(03SF0580A)。
文摘Proton conducting ceramic cells(PCCs)are an attractive emerging technology operating in the intermediate temperature range of 500 to 700℃.In this work,we evaluate the production of hydrogen at intermediate temperatures by proton conducting ceramic cell electrolysis(PCCEL).We demonstrate a highperformance steam electrolysis owing to a composite positrode based on BaGd_(0.8)La_(0.2)Co_(2)O_(6-δ)(BGLC1082)and BaZr0.5Ce0.4Y0.1O3-δ(BZCY541).The high reliability of PCCEL is demonstrated for 1680 h at a current density as high as-0.8 A cm^(-2)close to the thermoneutral cell voltage at 600℃.The electrolysis cell showed a specific energy consumption ranging from 54 to 66 kW h kg^(-1)that is comparable to state-of-the-art low temperature electrolysis technologies,while showing hydrogen production rates systematically higher than commercial solid oxide ceramic cells(SOCs).Compared to SOCs,the results verified the higher performances of PCCs at the relevant operating temperatures,due to the lower activation energy for proton transfer comparing with oxygen ion conduction.However,because of the p-type electronic conduction in protonic ceramics,the energy conversion rate of PCCs is relatively lower in steam electrolysis.The faradaic efficiency of the PCC in electrolysis mode can be increased at lower operating temperatures and in endothermic conditions,making PCCEL a technology of choice to valorize high temperature waste heat from industrial processes into hydrogen.To increase the faradaic efficiency by optimizing the materials,the cell design,or the operating strategy is a key challenge to address for future developments of PCCEL in order to achieve even more superior techno-economic merits.
基金supported by the National Natural Science Foundation of China(Nos.12375266 and 12435016)。
文摘Maintaining thermal stability is a key concern for the potential application of multi-principal-element alloys(MPEAs)at elevated temperatures,particularly in the intermediate temperature range.In this regime,the thermodynamic dominance of the entropy term over enthalpy may diminish,while atomic migration remains kinetically active.In this study,the stability of a series of refractory MPEAs(RMPEAs)from the subsystems of Ti-V-Zr-Nb-Hf-Ta is investigated at 550℃for 2-28 days.Although all eleven alloys exhibit a single solid solution phase with a body-centered cubic structure at their homogenized states,only two alloys,VNbTa and TiVNbTa,remain stable after annealing.Decomposition occurs in the other nine alloys under the spinodal manner or the nucleation and growth mechanism,including all three quinary alloys,demonstrating that configurational entropy is not a dominant factor.The phase stabilities can be well understood from the enthalpy perspectives,by combining first-principles calculations and semi-empirical models.By comparing the different contributors of formation enthalpy,the lattice distortion energy is found to be the most critical factor for this alloy system.Furthermore,the phases formed after long-term annealing are generally located at different regions in the space with the axes of chemical,structural,and lattice distortion energies.This work provides a way to interpret and control the stability of RMPEAs in the intermediate temperature regime.
基金supported by the National Natural Science Foundation of China(Nos.12325201,12272140,and 12322201)。
文摘This study investigates the dynamical behavior of two parallel fluid-conveying pipes by developing a non-planar dynamical model of the two pipes coupled with an intermediate spring. A systematic analysis is conducted to evaluate the effects of spring parameters on the non-planar vibration characteristics and buckling behaviors of the coupled system. The nonlinear governing equations are derived with Hamilton's principle,subsequently discretized through Galerkin's method, and finally numerically solved by the Runge-Kutta algorithm. Based on the linearized equations, an eigenvalue analysis is performed to obtain the coupled frequencies, modal shapes, and critical flow velocities for buckling instability. Quantitative assessments further elucidate the effects of the spring position and stiffness coefficient on the coupled frequencies and critical flow velocities.Nonlinear dynamic analyses reveal the evolution of buckling patterns and bifurcation behaviors between the lateral displacements of the two pipes and the flow velocity. Numerical results indicate that the intermediate spring increases the susceptibility to buckling instability in the out-of-plane direction compared with the in-plane direction. Furthermore, synchronized lateral displacements emerge in both pipes when the flow velocity of one pipe exceeds the critical threshold. This work is expected to provide a theoretical foundation for the stability assessment and vibration analysis in coupled fluid-conveying pipe systems.
基金Supported by the Instituto de Salud Carlos Ⅲ(ISCⅢ)Through the Project Co-Funded by the European Union,No.PI20-00487,No.PI23-00119 and No.PI24-01630.
文摘BACKGROUND Diabetes and its associated microvascular complications,such as nephropathy and retinopathy,significantly impact global health.These complications often begin in the prediabetic stage,emphasizing the importance of early detection and intervention.Inflammatory pathways are key contributors to these conditions,and recent research has identified members of the tumor necrosis factor(TNF)receptor superfamily as potential biomarkers.However,their association with renal and retinal dysfunction in individuals with intermediate hyperglycemia(IH)remains underexplored.The Early Prevention of Diabetes Complications(ePREDICE)trial provides a valuable cohort to investigate these associations and improve risk assessment strategies.AIM To identify inflammatory biomarkers associated with early renal and retinal dysfunction in individuals with IH.Specifically,we evaluate the diagnostic and prognostic potential of TNF receptor superfamily members[TNF receptor 1(TNF-R1),TNF receptor 2(TNF-R2)],T-cell immunoglobulin and mucin domain 3(TIM-3)/HAVCR2,galectin-3,and interleukin-6(IL-6)in detecting kidney dysfunction and retinopathy in this high-risk population.By understanding their roles,we seek to enhance early screening methods and inform personalized intervention strategies.METHODS A cross-sectional analysis of 967 individuals with IH from the ePREDICE trial was conducted.Participants underwent comprehensive anthropometric and biochemical assessments.Key inflammatory biomarkers,including TNF-R1,TNF-R2,TIM-3/HAVCR2,galectin-3,and IL-6,were quantified using immunoassays.Renal function was assessed using estimated glomerular filtration rate(eGFR)and albuminuria,while retinopathy was evaluated through fundoscopic examination.Statistical analyses included adjusted mean comparisons,correlation studies,and receiver operating characteristic curve analysis to assess biomarker diagnostic accuracy.RESULTS TNF-R1,TNF-R2,and TIM-3/HAVCR2 were significantly associated with reduced filtration function(eGFR<60 mL/minute/1.73 m^(2))and albuminuria,with area under the curve(AUC)values between 0.815 and 0.845.TIM-3/HAVCR2 emerged as the strongest predictor of retinopathy(AUC=0.737).Strong correlations(r>0.75)were observed among TNF-R1,TNF-R2,and TIM-3/HAVCR2,suggesting a coordinated role in inflammatory pathways.CONCLUSION Our findings highlight the potential of TNF receptor superfamily members as biomarkers for early-stage renal and retinal complications in individuals with IH.Their integration into clinical screening protocols could facilitate earlier detection,improving patient stratification and personalized management strategies.Further longitudinal studies are necessary to validate their predictive value and potential for guiding therapeutic interventions in IH and early diabetes management.
基金Supported by the Foreign Experts Project of the Belt and Road Innovative Talent Exchange(No.DL2023016005L).
文摘This article proposes an adaptive extended Kalman filter(EKF)for nonlinear cyber-physical systems(CPSs)under unknown inputs and non-Gaussian noises.It is known that the traditional extended Kalman filter is applicable to nonlinear systems with Gaussian white noise.The system is reformulated with intermediate variables to expand the application of nonlinear systems under unknown inputs and non-Gaussian noises,which help decompose unknown input estimation into residual tracking and state observation subproblems.By introducing the orthogonal principle of innovation and attenuation factor,the intermediate variables-based filter can improve the estimation performance under non-Gaussian noises and unknown inputs.Simulation results validate the effectiveness of the proposed method.
基金support provided by National Natural Science Foundation of China(Nos.52405364 and 52171110)Jiangsu Funding Program for Excellent Postdoctoral Talent+3 种基金JITRI Advanced Materials R&D Co.Ltdsupport by European Union Horizon 2020 Research and Innovation Program(857470)European Regional Development Fund via the Foundation for Polish Science International Research Agenda PLUS program(MAB PLUS/2018/8)The publication was created within the framework of the project of the Minister of Science and Higher Education,Support for the Activities of Centres of Excellence established in Poland under Horizon 2020,under contract No.MEiN/2023/DIR/3795.
文摘The deformation of Cu–20 wt.%Fe alloy wires leads to a significant improvement in mechanical properties and a decrease in electrical conductivity.Simultaneous improvements in strength and conductivity were achieved by intermediate annealing of drawn Cu–20 wt.%Fe wires.As the annealing temperature increased,the strength of Cu–20 wt.%Fe alloy wire decreased monotonically,but the electrical conductivity first increased and then decreased,reaching its peak value after annealing at 500℃.The decrease in strength is related to dislocation recovery and static recrystallization of Cu and Fe phases,and the increase in electrical conductivity mainly results from the aging precipitation of solid solution Fe.After annealing at 500℃,there was no obvious recrystallization of Cu phase,and many of the nano-Fe particles precipitated from Cu matrix.An annealing temperature of 600℃ induced the recrystallization of Cu matrix and an increase in Fe solid solubility,resulting in a decrease in strength and electrical conductivity.Subsequently,the wires annealed at 500℃ were drawn to 2 mm.Compared with those of the continuously drawn Cu–20 wt.%Fe alloy wires,the deformation ability,strength,and electrical conductivity of Cu–20 wt.%Fe alloy wires subjected to intermediate annealing treatment are significantly greater.This is mainly related to the sufficient precipitation of Fe in Cu matrix and the strengthening of refined Fe fibers parallel to the drawing direction.
基金supported by the Science and Technology Commission of Shanghai Municipality(No.2024ZDSYS2),China.
文摘Quasi-solid-state electrolytes,which integrate the safety characteristics of inorganic materials,the flexibility of polymers,and the high ionic conductivity of liquid electrolytes,represent a transitional solution for high-energy-density lithium batteries.However,the mechanisms by which inorganic fillers enhance multiphase interfacial conduction remain inadequately understood.In this work,we synthesized composite quasi-solid-state electrolytes with high inorganic content to investigate interfacial phenomena and achieve enhanced electrode interface stability.Li_(1.3)Al_(0.3)Ti_(1.7)(PO_(4))_(3)particles,through surface anion anchoring,improve Li^(+)transference numbers and facilitate partial dissociation of solvated Li^(+)structures,resulting in superior ion transport kinetics that achieve an ionic conductivity of 0.51 mS cm^(−1)at room temperature.The high mass fraction of inorganic components additionally promotes the formation of more stable interfacial layers,enabling lithium-symmetric cells to operate without short-circuiting for 6000 h at 0.1 mA cm^(−2).Furthermore,this system demonstrates exceptional stability in 5 V-class lithium metal full cells,maintaining 80.5%capacity retention over 200 cycles at 0.5C.These findings guide the role of inorganic interfaces in composite electrolytes and demonstrate their potential for advancing high-voltage lithium battery technology.
基金supported by the National Natural Science Foundation of China(Nos.52301279 and 51901115)the Shandong Provincial Natural Science Foundation,China(ZR2023MB122 and ZR2019PEM001)+1 种基金the Outstanding Youth Innovation Team of Universities in Shandong Province(2024KJH067)the Innovation fund project for graduate student of China University of Petroleum(East China)supported by the Fundamental Research Funds for the Central Universities(No.23CX04010A)。
文摘Addressing inadequate OH^(*)adsorption in Ru Co alloy catalysts is crucial for boosting intermediate coverage and redirecting the water-splitting pathway.Herein,the adaptive P sites were strategically incorporated to overcome the aforementioned challenge.The P sites,as potent OH^(*)adsorption centers,synergize with Co sites to promote water dissociation and enrich surrounding Ru sites with H*intermediates,thus triggering the Volmer-Tafel route for hydrogen evolution reaction(HER).Besides,during the oxygen evolution reaction(OER),the surface of P-Ru Co was reconstructed into Ru-doped Co OOH with anchored PO_(4)^(3-).These PO_(4)^(3-)not only circumvent the intrinsic OH^(*)adsorption limitations of Ru-Co OOH in the adsorbate evolution mechanism(AEM)by rerouting to a more expeditious lattice oxygen oxidation mechanism(LOM)but also improve the coverage of key oxygen-containing intermediates,significantly accelerating OER kinetics.Consequently,the P-Ru Co demonstrates exceptional bifunctional performance,with overpotentials of 29 m V for HER and 222 m V for OER at 10 m A cm^(-2).Remarkably,the mass activities of PRu Co for HER(5.48 A mg^(-1))and OER(2.13 A mg^(-1))are 6.2 and 11.2 times higher than those of its commercial counterparts(Ru/C for HER and RuO_(2)for OER),respectively.When integrated into an anionexchange-membrane electrolyzer,this catalyst achieves ampere-level current densities of 1.32 A cm^(-2)for water electrolysis and 1.23 A cm^(-2)for seawater electrolysis at 2.1 V,with a 500-h durability.
文摘Background:Intermediate-risk prostate cancer(IR-PC)represents a heterogeneous group requiring nuanced treatment approaches,and recent advancements in radiotherapy(RT),androgen deprivation therapy(ADT),and prostatespecific membrane antigen positron emission tomography(PSMA-PET/CT)imaging have prompted growing interest in personalized,risk-adapted management strategies.This study by the Turkish Society for Radiation Oncology aims to examine radiation oncologists’practices in managing IR-PC,focusing on RT and imaging modalities to identify trends for personalized treatments.Methods:A cross-sectional survey was conducted among Turkish radiation oncologists treating at least 50 prostate cancer(PC)cases annually.The 22-item questionnaire covered IR-PC management aspects such as risk stratification,imaging preferences,androgen deprivation therapy(ADT)use and duration,RT techniques,and treatment combinations.Anonymous responses were analyzed using descriptive statistics.Results:Thirty radiation oncologists participated,57%with over 20 years of experience.The median annual number of PC cases treated was 130.For risk stratification,43% followed the National Comprehensive Cancer Network(NCCN)guidelines,while 30%used the D’Amico classification.Imaging preferences revealed 47% favored PSMA-PET/CT.External beam RT was universally preferred,with 60% adopting ultra-hypofractionation.ADT was used by 97%,with 73% recommending it for unfavorable IR-PC cases.Short-term ADT(4–6 months)was the standard,administered concurrently with RT by 57%.Cardiovascular status influenced decisions for 97% of respondents,while 37% also considered patient age,preferences,and sexual health.Conclusions:This national survey demonstrates a shift toward personalized care in intermediate-risk prostate cancer in Turkey,marked by selective PSMA-PET/CT use,tailored ADT,and evolving radiotherapy practices.The findings underscore the importance of multidisciplinary collaboration—particularly between urologists and radiation oncologists—to optimize imaging integration and treatment outcomes.
