Commercial phosphor-converted white LEDs(pc-WLEDs)face two inherent limitations,namely blue light hazard and low color rendering index,due to the use of blue LEDs as excitation source.To address these challenges,viole...Commercial phosphor-converted white LEDs(pc-WLEDs)face two inherent limitations,namely blue light hazard and low color rendering index,due to the use of blue LEDs as excitation source.To address these challenges,violet LEDs are proposed as an alternative solution.Currently,phosphors that can be efficiently excited by violet light(with wavelengths from 400 to 420 nm)remain under development still.In this study,we utilize large language models to construct a comprehensive database of Eu^(2+)and Ce^(3+)doped phosphors for discovering novel violet-excited phosphors.A total of 822 phosphor data entries,including elemental compositions,crystal structures and excitation/emission wavelengths,have been extracted and validated from 9551 research papers.Compared with Ce^(3+)doped phosphors,the Eu^(2+)are in general more suited for violet-excited phosphors,as well as red-emitting phosphors.In particular,Eu^(2+)doped nitrides and sulfides are worth of exploration for violet-excited phosphors.This database is expected to be useful in the future development of phosphors for pc-WLEDs based on artificial intelligence methods.The datasets in this article are listed in Science Data Bank at http://doi.org/10.57760/sciencedb.34314.展开更多
The newly identified Jinlin crater in southern China lies on a hillside covered by a thick granite weathering crust.It appears as a slightly elliptical bowl-shaped depression with a diameter of 820-900 m.The structure...The newly identified Jinlin crater in southern China lies on a hillside covered by a thick granite weathering crust.It appears as a slightly elliptical bowl-shaped depression with a diameter of 820-900 m.The structure is a tilted impact crater,showing a maximum rim height difference of about 200 m and an apparent depth of 90 m.The crater rim is composed mainly of granite weathered soil and a small amount of granite fragments,while the bottom of the crater is filled with the same mixture of granite weathered soil and granite fragments.Planar deformation features in quartz grains from the rock fragments of the crater provide decisive evidence for its impact origin.The impact event is inferred to have taken place during the Holocene.展开更多
In the image fusion field,fusing infrared images(IRIs)and visible images(VIs)excelled is a key area.The differences between IRIs and VIs make it challenging to fuse both types into a high-quality image.Accordingly,eff...In the image fusion field,fusing infrared images(IRIs)and visible images(VIs)excelled is a key area.The differences between IRIs and VIs make it challenging to fuse both types into a high-quality image.Accordingly,efficiently combining the advantages of both images while overcoming their shortcomings is necessary.To handle this challenge,we developed an end-to-end IRI andVI fusionmethod based on frequency decomposition and enhancement.By applying concepts from frequency domain analysis,we used the layering mechanism to better capture the salient thermal targets from the IRIs and the rich textural information from the VIs,respectively,significantly boosting the image fusion quality and effectiveness.In addition,the backbone network combined Restormer Blocks and Dense Blocks;Restormer blocks utilize global attention to extract shallow features.Meanwhile,Dense Blocks ensure the integration between shallow and deep features,thereby avoiding the loss of shallow attributes.Extensive experiments on TNO and MSRS datasets demonstrated that the suggested method achieved state-of-the-art(SOTA)performance in various metrics:Entropy(EN),Mutual Information(MI),Standard Deviation(SD),The Structural Similarity Index Measure(SSIM),Fusion quality(Qabf),MI of the pixel(FMI_(pixel)),and modified Visual Information Fidelity(VIF_(m)).展开更多
Hydraulic fracturing serves as a critical technology for reservoir stimulation in deep coalbed methane(CBM)development,where the mechanical properties of gangue layers exert a significant control on fracture propagati...Hydraulic fracturing serves as a critical technology for reservoir stimulation in deep coalbed methane(CBM)development,where the mechanical properties of gangue layers exert a significant control on fracture propagation behavior.To address the unclear mechanisms governing fracture penetration across coal-gangue interfaces,this study employs the Continuum-Discontinuum Element Method(CDEM)to simulate and analyze the vertical propagation of hydraulic fractures initiating within coal seams,based on geomechanical parameters derived from the deep Benxi Formation coal seams in the southeastern Ordos Basin.The investigation systematically examines the influence of geological and operational parameters on cross-interfacial fracture growth.Results demonstrate that vertical stress difference,elastic modulus contrast between coal and gangue layers,interfacial stress differential,and interfacial cohesion at coal-gangue interfaces are critical factors governing hydraulic fracture penetration through these interfaces.High vertical stress differences(>3 MPa)inhibit interfacial dilation,promoting predominant crosslayer fracture propagation.Reduced interfacial stress contrasts and enhanced interfacial cohesion facilitate fracture penetration across interfaces.Furthermore,smaller elastic modulus contrasts between coal and gangue correlate with increased interfacial aperture.Finally,lower injection rates effectively suppress vertical fracture propagation in deep coal reservoirs.This study elucidates the characteristics and mechanisms governing cross-layer fracture propagation in coal–rock composites with interbedded partings,and delineates the dynamic evolution laws and dominant controlling factors involved.Thefindings provide critical theoretical insights for the optimization of fracture design and the efficient development of deep coalbed methane reservoirs.展开更多
The real-time monitoring of fracture propagation during hydraulic fracturing is crucial for obtaining a deeper understanding of fracture morphology and optimizing hydraulic fracture designs.Accurate measurements of ke...The real-time monitoring of fracture propagation during hydraulic fracturing is crucial for obtaining a deeper understanding of fracture morphology and optimizing hydraulic fracture designs.Accurate measurements of key fracture parameters,such as the fracture height and width,are particularly important to ensure efficient oilfield development and precise fracture diagnosis.This study utilized the optical frequency domain reflectometer(OFDR)technique in physical simulation experiments to monitor fractures during indoor true triaxial hydraulic fracturing experiments.The results indicate that the distributed fiber optic strain monitoring technology can efficiently capture the initiation and expansion of fractures.In horizontal well monitoring,the fiber strain waterfall plot can be used to interpret the fracture width,initiation location,and expansion speed.The fiber response can be divided into three stages:strain contraction convergence,strain band formation,and postshutdown strain rate reversal.When the fracture does not contact the fiber,a dual peak strain phenomenon occurs in the fiber and gradually converges as the fracture approaches.During vertical well monitoring in adjacent wells,within the effective monitoring range of the fiber,the axial strain produced by the fiber can represent the fracture height with an accuracy of 95.6%relative to the actual fracture height.This study provides a new perspective on real-time fracture monitoring.The response patterns of fiber-induced strain due to fractures can help us better understand and assess the dynamic fracture behavior,offering significant value for the optimization of oilfield development and fracture diagnostic techniques.展开更多
Natural gas hydrates(hereinafter referred to as hydrates)are a promising clean energy source.However,their current development is far from reaching commercial exploitation.Reservoir stimulation tech-nology provides ne...Natural gas hydrates(hereinafter referred to as hydrates)are a promising clean energy source.However,their current development is far from reaching commercial exploitation.Reservoir stimulation tech-nology provides new approaches to enhance hydrate development effectiveness.Addressing the current lack of quantitative and objective methods for evaluating the fracability of hydrate reservoirs,this study clarifies the relationship between geological and engineering fracability and proposes a comprehensive evaluation model for hydrate reservoir fracability based on grey relational analysis and the criteria importance through intercriteria correlation method.By integrating results from hydraulic fracturing experiments on hydrate sediments,the fracability of hydrate reservoirs is assessed.The concept of critical construction parameter curves for hydrate reservoirs is introduced for the first time.Additionally,two-dimensional fracability index evaluation charts and three-dimensional fracability construction condition discrimination charts are established.The results indicate that as the comprehensive fracability index increases,the feasibility of forming fractures in hydrate reservoirs improves,and the required normalized fracturing construction parameters gradually decrease.The accuracy rate of the charts in judging experimental results reached 89.74%,enabling quick evaluations of whether hydrate reservoirs are worth fracturing,easy to fracture,and capable of being fractured.This has significant engineering implications forthehydraulicfracturingof hydratereservoirs.展开更多
A uniquely shaped impact structure,the Hailin impact crater,has been discovered in northeast China.The crater was formed on a granodiorite hillside and is an oval depression with asymmetric rim height and a maximum di...A uniquely shaped impact structure,the Hailin impact crater,has been discovered in northeast China.The crater was formed on a granodiorite hillside and is an oval depression with asymmetric rim height and a maximum diameter of 1360 m.The bottom of the crater is filled by Quaternary sediments with large amounts of rock fragments underneath.The discovery of quartz planar deformation features in rock clasts on the crater floor provides diagnostic evidence for the impact origin of the structure.The shape of the crater is largely due to the impact having occurred on a ridge terrain.The impact event probably occurred in the late Cenozoic Era.The Hailin impact crater is the fourth confirmed Chinese impact crater.展开更多
Systematic bone and muscle loss is a complex metabolic disease,which is frequently linked to gut dysfunction,yet its etiology and treatment remain elusive.While probiotics show promise in managing diseases through mic...Systematic bone and muscle loss is a complex metabolic disease,which is frequently linked to gut dysfunction,yet its etiology and treatment remain elusive.While probiotics show promise in managing diseases through microbiome modulation,their therapeutic impact on gut dysfunction-induced bone and muscle loss remains to be elucidated.Employing dextran sulfate sodium(DSS)-induced gut dysfunction model and wide-spectrum antibiotics(ABX)-treated mice model,our study revealed that gut dysfunction instigates muscle and bone loss,accompanied by microbial imbalances.Importantly,Bifidobacterium animalis subsp.lactis A6(B.lactis A6)administration significantly ameliorated muscle and bone loss by modulating gut microbiota composition and enhancing butyrate-producing bacteria.This intervention effectively restored depleted butyrate levels in serum,muscle,and bone tissues caused by gut dysfunction.Furthermore,butyrate supplementation mitigated musculoskeletal loss by repairing the damaged intestinal barrier and enriching beneficial butyrate-producing bacteria.Importantly,butyrate inhibited the NF-κB pathway activation,and reduced the secretion of corresponding inflammatory factors in T cells.Our study highlights the critical role of dysbiosis in gut dysfunction-induced musculoskeletal loss and underscores the therapeutic potential of B.lactis A6.These discoveries offer new microbiome directions for translational and clinical research,providing promising strategies for preventing and managing musculoskeletal diseases.展开更多
Loneliness is a complex and usually unpleasant emotional response to isolation,which has been considered the latest global health epidemic exacerbated by the coronavirus disease 2019 pandemic,affecting nearly twothird...Loneliness is a complex and usually unpleasant emotional response to isolation,which has been considered the latest global health epidemic exacerbated by the coronavirus disease 2019 pandemic,affecting nearly twothirds of older adults.Some profound health implications carried by loneliness include depression,cognitive impairment,hypertension and frailty.Across the world,there is no consensus definition of loneliness,and its measure is based on the phenomenological perspective of the individual.The 20-item University of California Los Angeles Loneliness Scale version 3(UCLA-20)is the most common measure.This scale demonstrates acceptable psychometric properties but is too long and complex for a phone interview.This paper addresses the increasing need to shorten this scale by adopting classical item response theory and network psychometrics to advance scale development.Through an item reduction analysis,we trimmed the original scale into an effective short form,which is as valid as the original one.With respondents’time at a premium in most research nowadays,this shortform scale is an efficient and practical alternative to the original UCLA-20.展开更多
In the face of the escalating global prevalence of chronic kidney disease(CKD),early diagnosis and effective management have become crucial imperatives[1].The article“Development of a smartphone-integrated handheld a...In the face of the escalating global prevalence of chronic kidney disease(CKD),early diagnosis and effective management have become crucial imperatives[1].The article“Development of a smartphone-integrated handheld automated biochemical analyzer for point-of-care testing of urinary albumin”by Wu et al.[2]presents a novel smartphone-integrated handheld automated biochemical analyzer(sHABA),which offers new possibilities for the early diagnosis and management of CKD,holding great significance for improving patients’health.展开更多
The reduction of carbon emissions in the steel industry is a significant challenge,and utilizing CO_(2) from carbon intensive steel industry off-gases for methanol production is a promising strategy for decarbonizatio...The reduction of carbon emissions in the steel industry is a significant challenge,and utilizing CO_(2) from carbon intensive steel industry off-gases for methanol production is a promising strategy for decarbonization.However,steelwork off-gases typically contain various impurities,including H_(2)S,which can deactivate commercial methanol synthesis catalysts,Cu/ZnO/Al_(2)O_(3)(CZA).Reverse water-gas shift(RWGS)reaction is the predominant side reaction in CO_(2) hydrogenation to methanol which can occur at ambient pressure,enabling the decouple of RWGS from methanol production at high pressure.Then,a series of activated CZA catalysts has been in-situ pretreated in 400 ppm H_(2)S/Ar at 250℃and tested for both RWGS reaction at ambient pressure and CO_(2) hydrogenation to methanol at high pressure.An innovative decoupling strategy was employed to isolate the RWGS reaction from the methanol synthesis process,enabling the investigation of the evolution of active site structures and the poisoning mechanism through elemental analysis,X-ray Diffraction,X-ray Photoelectron Spectroscopy,Fourier Transform Infrared Spectroscopy,Temperature Programmed Reduction and CO_(2) Temperature Programmed Desorption.The results indicate that there are different dynamic migration behaviors of ZnO_(x) in the two reaction systems,leading to different poisoning mechanisms.These interesting findings are beneficial to develop sulfur resistant and durable highly efficient catalysts for CO_(2) hydrogenation to methanol,promoting the carbon emission reduction in steel industry.展开更多
Elucidating the microbial mechanisms that trigger Fusarium wilt represents a key step in addressing the barriers to sustainable cropping.However,from the perspective of the complete microbiome,the integrated role of s...Elucidating the microbial mechanisms that trigger Fusarium wilt represents a key step in addressing the barriers to sustainable cropping.However,from the perspective of the complete microbiome,the integrated role of soil nutrients and microbial community in the fields with different rates of wilt disease remains unclear.In this study,we examined the potential interrelationships among the nutrients,bacteria,fungi,and protists in rhizospheric soils collected from the fields with watermelon cropping for 7 years at the Zhuanghang Experimental Station of Shanghai Academy of Agricultural Sciences,China.The soils collected were characterized by a high(HW,81.25%)or low(LW,6.25%)wilting rate.The HW soil was found to contain a higher abundance of Fusarium oxysporum(1.30-fold higher)than the LW soil,along with higher contents of available phosphorus(1.31-fold higher)and available potassium(2.39-fold higher).In addition,the interkingdom correlation between protists and bacteria in the HW soil was 2.08-fold higher than that in the LW soil.Furthermore,structural equation modeling revealed that an excess of soil available potassium enhanced the predation by potentially detrimental phagotrophic protists on potentially beneficial bacteria.In summary,our findings indicated that a balanced nutrient input and the interactions between protists(Cercomonas and Colpoda)and beneficial bacteria(Bacillus)played important roles in controlling the incidence of watermelon Fusarium wilt.展开更多
To achieve high production of arachidonic acid(ARA)through industrial fermentation of Mortierella alpina,the correlation between metal ions,mycelium pellet morphology and ARA production was investigated.By adding diff...To achieve high production of arachidonic acid(ARA)through industrial fermentation of Mortierella alpina,the correlation between metal ions,mycelium pellet morphology and ARA production was investigated.By adding different metal ions to the culture medium,observing the morphological differences of mycelium pellet,total oil production and ARA content and established a correlation between them.The results showed that adding sodium ions increase the density of mycelium pellet,while reducing the diameter of mycelium pellet,resulting in a 41.59%increase in ARA production.Potassium ions,magnesium ions,calcium ions and iron ions slightly reduce the diameter of fungal hyphae and increase ARA production by 7.47%,17.81%,36.05%and 9.37%,respectively.At the same time,calcium ions promoted the branching growth of mycelium,which solve the problem of excessive free mycelium in fermentation broth within a certain concentration range.Zinc ions had a negative impact on bacterial growth,leading to the formation of mycelium clumps in the fermentation broth.Manganese ions and ferrous ions could transform the morphology of fungal mycelium into a smooth spherical surface,which was not conducive to the growth of M.alpina and the accumulation of oil.The comprehensive results showed that the optimal fermentation mycelium form for M.alpina was a dense central and loosely packed mycelium pellet.The yield of ARA was directly proportional to the density of mycelium pellet and inversely proportional to the diameter of mycelium pellet.展开更多
This review systematically elucidates the core mechanisms and research advancements regarding the role of autophagy in immune evasion in Renal Cell Carcinoma(RCC).Accumulating evidence indicates that autophagy exhibit...This review systematically elucidates the core mechanisms and research advancements regarding the role of autophagy in immune evasion in Renal Cell Carcinoma(RCC).Accumulating evidence indicates that autophagy exhibits a typical“context-dependent”dual role in RCC pathogenesis:it may suppress tumorigenesis in early stages,while primarily promoting cell survival and immunosuppressive functions within the established tumor microenvironment(TME).Autophagy facilitates immune escape through multi-dimensional mechanisms,including the precise regulation of PD-L1 stability,degradation of MHC-I molecules and the antigenic peptide pool,remodeling of the metabolic microenvironment,induction of T cell exhaustion,and enhancement of immunosuppressive cell functions.Therapeutically,combining autophagy inhibitors with immune checkpoint inhibitors has demonstrated significant synergistic effects in preclinical studies,and several clinical trials have provided preliminary validation of its safety and efficacy.Future research should focus on integrating multi-omics technologies and advanced disease models to deeply elucidate the autophagy regulatory network,explore its crosstalk with other cell death pathways such as pyroptosis and ferroptosis,and promote the development of personalized treatment strategies based on precise stratification of autophagy activity,thereby offering new avenues to overcome immunotherapy resistance in RCC.展开更多
Efficient,safe,and economical hydrogen storage technology is vital for hydrogen’s broad use as an energy carrier,with V-based BCC alloys standing out for their high theoretical storage capacity.However,the high cost ...Efficient,safe,and economical hydrogen storage technology is vital for hydrogen’s broad use as an energy carrier,with V-based BCC alloys standing out for their high theoretical storage capacity.However,the high cost of V has restricted their practical application.In this work,a cost-effective Ti–Cr–(Fe V80)alloy was successfully synthesized through a pre-refinement process involving the addition of Y/Zr to the Fe V80 alloy.The resulting Ti_(27)Cr_(27)(Fe V80+Y)_(46)alloy exhibited an effective dehydriding capacity of 2.3 wt%,with a capacity retention rate of 97.2%after 200 cycles.Through the analysis of HSC Chemistry 6.0 software and backscattered electron(BSE),it has been discovered that the prerefinement process significantly reduces the presence of Al,Si,and O impurities,leading to improved compositional uniformity.After the re-refinement,the formation of the Ti–rich phases had been notably curbed.This,along with a marked decrease in the pressure–composition–temperature(PCT)curve’s slope factor from 1.58 to 0.36,results in enhanced hydriding capacity(from 3.2 wt%to 3.7 wt%),reversible dehydriding capacity(from 2.0 wt%to 2.3 wt%),and a remarkable increase in the capacity retention rate(from 75.8%to 97.2%).The kinetics and thermodynamic properties of the alloys were calculated using the Arrhenius and Van’t Hoff equations,providing insights into their performance characteristics.The mechanism behind the alloy’s improved cyclic stability has been elucidated through an analysis of lattice distortion and X-ray photoelectron spectroscopy(XPS).These findings open new routes for the development of cost-effective Fe V80-based hydrogen storage materials.展开更多
基金National Key Research and Development Program of China(2021YFB3500501)。
文摘Commercial phosphor-converted white LEDs(pc-WLEDs)face two inherent limitations,namely blue light hazard and low color rendering index,due to the use of blue LEDs as excitation source.To address these challenges,violet LEDs are proposed as an alternative solution.Currently,phosphors that can be efficiently excited by violet light(with wavelengths from 400 to 420 nm)remain under development still.In this study,we utilize large language models to construct a comprehensive database of Eu^(2+)and Ce^(3+)doped phosphors for discovering novel violet-excited phosphors.A total of 822 phosphor data entries,including elemental compositions,crystal structures and excitation/emission wavelengths,have been extracted and validated from 9551 research papers.Compared with Ce^(3+)doped phosphors,the Eu^(2+)are in general more suited for violet-excited phosphors,as well as red-emitting phosphors.In particular,Eu^(2+)doped nitrides and sulfides are worth of exploration for violet-excited phosphors.This database is expected to be useful in the future development of phosphors for pc-WLEDs based on artificial intelligence methods.The datasets in this article are listed in Science Data Bank at http://doi.org/10.57760/sciencedb.34314.
基金financial support from Shanghai Key Laboratory Novel Extreme Condition Materials,China(Grant No.22dz2260800)the Shanghai Science and Technology Committee,China(Grant No.22JC1410300).
文摘The newly identified Jinlin crater in southern China lies on a hillside covered by a thick granite weathering crust.It appears as a slightly elliptical bowl-shaped depression with a diameter of 820-900 m.The structure is a tilted impact crater,showing a maximum rim height difference of about 200 m and an apparent depth of 90 m.The crater rim is composed mainly of granite weathered soil and a small amount of granite fragments,while the bottom of the crater is filled with the same mixture of granite weathered soil and granite fragments.Planar deformation features in quartz grains from the rock fragments of the crater provide decisive evidence for its impact origin.The impact event is inferred to have taken place during the Holocene.
基金funded by Anhui Province University Key Science and Technology Project(2024AH053415)Anhui Province University Major Science and Technology Project(2024AH040229)+3 种基金Talent Research Initiation Fund Project of Tongling University(2024tlxyrc019)Tongling University School-Level Scientific Research Project(2024tlxyptZD07)TheUniversity Synergy Innovation Programof Anhui Province(GXXT-2023-050)Tongling City Science and Technology Major Special Project(Unveiling and Commanding Model)(200401JB004).
文摘In the image fusion field,fusing infrared images(IRIs)and visible images(VIs)excelled is a key area.The differences between IRIs and VIs make it challenging to fuse both types into a high-quality image.Accordingly,efficiently combining the advantages of both images while overcoming their shortcomings is necessary.To handle this challenge,we developed an end-to-end IRI andVI fusionmethod based on frequency decomposition and enhancement.By applying concepts from frequency domain analysis,we used the layering mechanism to better capture the salient thermal targets from the IRIs and the rich textural information from the VIs,respectively,significantly boosting the image fusion quality and effectiveness.In addition,the backbone network combined Restormer Blocks and Dense Blocks;Restormer blocks utilize global attention to extract shallow features.Meanwhile,Dense Blocks ensure the integration between shallow and deep features,thereby avoiding the loss of shallow attributes.Extensive experiments on TNO and MSRS datasets demonstrated that the suggested method achieved state-of-the-art(SOTA)performance in various metrics:Entropy(EN),Mutual Information(MI),Standard Deviation(SD),The Structural Similarity Index Measure(SSIM),Fusion quality(Qabf),MI of the pixel(FMI_(pixel)),and modified Visual Information Fidelity(VIF_(m)).
文摘Hydraulic fracturing serves as a critical technology for reservoir stimulation in deep coalbed methane(CBM)development,where the mechanical properties of gangue layers exert a significant control on fracture propagation behavior.To address the unclear mechanisms governing fracture penetration across coal-gangue interfaces,this study employs the Continuum-Discontinuum Element Method(CDEM)to simulate and analyze the vertical propagation of hydraulic fractures initiating within coal seams,based on geomechanical parameters derived from the deep Benxi Formation coal seams in the southeastern Ordos Basin.The investigation systematically examines the influence of geological and operational parameters on cross-interfacial fracture growth.Results demonstrate that vertical stress difference,elastic modulus contrast between coal and gangue layers,interfacial stress differential,and interfacial cohesion at coal-gangue interfaces are critical factors governing hydraulic fracture penetration through these interfaces.High vertical stress differences(>3 MPa)inhibit interfacial dilation,promoting predominant crosslayer fracture propagation.Reduced interfacial stress contrasts and enhanced interfacial cohesion facilitate fracture penetration across interfaces.Furthermore,smaller elastic modulus contrasts between coal and gangue correlate with increased interfacial aperture.Finally,lower injection rates effectively suppress vertical fracture propagation in deep coal reservoirs.This study elucidates the characteristics and mechanisms governing cross-layer fracture propagation in coal–rock composites with interbedded partings,and delineates the dynamic evolution laws and dominant controlling factors involved.Thefindings provide critical theoretical insights for the optimization of fracture design and the efficient development of deep coalbed methane reservoirs.
基金supported by the National Natural Science Foundation of China(Grant No.52104060)the Natural Science Foundation of Shandong Province,China(Grant No.ZR2021QE015).
文摘The real-time monitoring of fracture propagation during hydraulic fracturing is crucial for obtaining a deeper understanding of fracture morphology and optimizing hydraulic fracture designs.Accurate measurements of key fracture parameters,such as the fracture height and width,are particularly important to ensure efficient oilfield development and precise fracture diagnosis.This study utilized the optical frequency domain reflectometer(OFDR)technique in physical simulation experiments to monitor fractures during indoor true triaxial hydraulic fracturing experiments.The results indicate that the distributed fiber optic strain monitoring technology can efficiently capture the initiation and expansion of fractures.In horizontal well monitoring,the fiber strain waterfall plot can be used to interpret the fracture width,initiation location,and expansion speed.The fiber response can be divided into three stages:strain contraction convergence,strain band formation,and postshutdown strain rate reversal.When the fracture does not contact the fiber,a dual peak strain phenomenon occurs in the fiber and gradually converges as the fracture approaches.During vertical well monitoring in adjacent wells,within the effective monitoring range of the fiber,the axial strain produced by the fiber can represent the fracture height with an accuracy of 95.6%relative to the actual fracture height.This study provides a new perspective on real-time fracture monitoring.The response patterns of fiber-induced strain due to fractures can help us better understand and assess the dynamic fracture behavior,offering significant value for the optimization of oilfield development and fracture diagnostic techniques.
基金support of the National Natural Science Foundation of China(Grant No.52074332).
文摘Natural gas hydrates(hereinafter referred to as hydrates)are a promising clean energy source.However,their current development is far from reaching commercial exploitation.Reservoir stimulation tech-nology provides new approaches to enhance hydrate development effectiveness.Addressing the current lack of quantitative and objective methods for evaluating the fracability of hydrate reservoirs,this study clarifies the relationship between geological and engineering fracability and proposes a comprehensive evaluation model for hydrate reservoir fracability based on grey relational analysis and the criteria importance through intercriteria correlation method.By integrating results from hydraulic fracturing experiments on hydrate sediments,the fracability of hydrate reservoirs is assessed.The concept of critical construction parameter curves for hydrate reservoirs is introduced for the first time.Additionally,two-dimensional fracability index evaluation charts and three-dimensional fracability construction condition discrimination charts are established.The results indicate that as the comprehensive fracability index increases,the feasibility of forming fractures in hydrate reservoirs improves,and the required normalized fracturing construction parameters gradually decrease.The accuracy rate of the charts in judging experimental results reached 89.74%,enabling quick evaluations of whether hydrate reservoirs are worth fracturing,easy to fracture,and capable of being fractured.This has significant engineering implications forthehydraulicfracturingof hydratereservoirs.
基金financial support from the Shanghai Key Laboratory Novel Extreme Condition Materials,China(Grant No.22dz2260800)the Shanghai Science and Technology Committee,China(Grant No.22JC1410300)。
文摘A uniquely shaped impact structure,the Hailin impact crater,has been discovered in northeast China.The crater was formed on a granodiorite hillside and is an oval depression with asymmetric rim height and a maximum diameter of 1360 m.The bottom of the crater is filled by Quaternary sediments with large amounts of rock fragments underneath.The discovery of quartz planar deformation features in rock clasts on the crater floor provides diagnostic evidence for the impact origin of the structure.The shape of the crater is largely due to the impact having occurred on a ridge terrain.The impact event probably occurred in the late Cenozoic Era.The Hailin impact crater is the fourth confirmed Chinese impact crater.
基金supported by funding from the National Natural Science Foundation of China(82272478,82002330,82202728)the National Key R&D Program of China(No.2022YFF1100100)the Natural Science Foundation of Beijing(L222086).
文摘Systematic bone and muscle loss is a complex metabolic disease,which is frequently linked to gut dysfunction,yet its etiology and treatment remain elusive.While probiotics show promise in managing diseases through microbiome modulation,their therapeutic impact on gut dysfunction-induced bone and muscle loss remains to be elucidated.Employing dextran sulfate sodium(DSS)-induced gut dysfunction model and wide-spectrum antibiotics(ABX)-treated mice model,our study revealed that gut dysfunction instigates muscle and bone loss,accompanied by microbial imbalances.Importantly,Bifidobacterium animalis subsp.lactis A6(B.lactis A6)administration significantly ameliorated muscle and bone loss by modulating gut microbiota composition and enhancing butyrate-producing bacteria.This intervention effectively restored depleted butyrate levels in serum,muscle,and bone tissues caused by gut dysfunction.Furthermore,butyrate supplementation mitigated musculoskeletal loss by repairing the damaged intestinal barrier and enriching beneficial butyrate-producing bacteria.Importantly,butyrate inhibited the NF-κB pathway activation,and reduced the secretion of corresponding inflammatory factors in T cells.Our study highlights the critical role of dysbiosis in gut dysfunction-induced musculoskeletal loss and underscores the therapeutic potential of B.lactis A6.These discoveries offer new microbiome directions for translational and clinical research,providing promising strategies for preventing and managing musculoskeletal diseases.
文摘Loneliness is a complex and usually unpleasant emotional response to isolation,which has been considered the latest global health epidemic exacerbated by the coronavirus disease 2019 pandemic,affecting nearly twothirds of older adults.Some profound health implications carried by loneliness include depression,cognitive impairment,hypertension and frailty.Across the world,there is no consensus definition of loneliness,and its measure is based on the phenomenological perspective of the individual.The 20-item University of California Los Angeles Loneliness Scale version 3(UCLA-20)is the most common measure.This scale demonstrates acceptable psychometric properties but is too long and complex for a phone interview.This paper addresses the increasing need to shorten this scale by adopting classical item response theory and network psychometrics to advance scale development.Through an item reduction analysis,we trimmed the original scale into an effective short form,which is as valid as the original one.With respondents’time at a premium in most research nowadays,this shortform scale is an efficient and practical alternative to the original UCLA-20.
文摘In the face of the escalating global prevalence of chronic kidney disease(CKD),early diagnosis and effective management have become crucial imperatives[1].The article“Development of a smartphone-integrated handheld automated biochemical analyzer for point-of-care testing of urinary albumin”by Wu et al.[2]presents a novel smartphone-integrated handheld automated biochemical analyzer(sHABA),which offers new possibilities for the early diagnosis and management of CKD,holding great significance for improving patients’health.
基金supported by the National Natural Science Foundation of China(Nos.22276060 and 21976059)Guangdong Basic and Applied Basic Research Foundation(No.2024A1515012636)China Scholarship Council Scholarship(No.201906155006)。
文摘The reduction of carbon emissions in the steel industry is a significant challenge,and utilizing CO_(2) from carbon intensive steel industry off-gases for methanol production is a promising strategy for decarbonization.However,steelwork off-gases typically contain various impurities,including H_(2)S,which can deactivate commercial methanol synthesis catalysts,Cu/ZnO/Al_(2)O_(3)(CZA).Reverse water-gas shift(RWGS)reaction is the predominant side reaction in CO_(2) hydrogenation to methanol which can occur at ambient pressure,enabling the decouple of RWGS from methanol production at high pressure.Then,a series of activated CZA catalysts has been in-situ pretreated in 400 ppm H_(2)S/Ar at 250℃and tested for both RWGS reaction at ambient pressure and CO_(2) hydrogenation to methanol at high pressure.An innovative decoupling strategy was employed to isolate the RWGS reaction from the methanol synthesis process,enabling the investigation of the evolution of active site structures and the poisoning mechanism through elemental analysis,X-ray Diffraction,X-ray Photoelectron Spectroscopy,Fourier Transform Infrared Spectroscopy,Temperature Programmed Reduction and CO_(2) Temperature Programmed Desorption.The results indicate that there are different dynamic migration behaviors of ZnO_(x) in the two reaction systems,leading to different poisoning mechanisms.These interesting findings are beneficial to develop sulfur resistant and durable highly efficient catalysts for CO_(2) hydrogenation to methanol,promoting the carbon emission reduction in steel industry.
基金supported by Ningbo Science and Technology Bureau,China(Nos.2021Z0472021Z04)+3 种基金the Department of Agriculture and Rural Development of Zhejiang Province,China(No.2022SNJF024)the Outstanding Team Program of Shanghai Academy of Agricultural Science 425,China(No.Hu-Nong-Ke-Zhuo 2022(008))the National Agricultural Experimental Station for Agricultural Environment,Fengxian,China(No.NAES035AE03)the K.C.Wong Magna Fund in Ningbo University,China。
文摘Elucidating the microbial mechanisms that trigger Fusarium wilt represents a key step in addressing the barriers to sustainable cropping.However,from the perspective of the complete microbiome,the integrated role of soil nutrients and microbial community in the fields with different rates of wilt disease remains unclear.In this study,we examined the potential interrelationships among the nutrients,bacteria,fungi,and protists in rhizospheric soils collected from the fields with watermelon cropping for 7 years at the Zhuanghang Experimental Station of Shanghai Academy of Agricultural Sciences,China.The soils collected were characterized by a high(HW,81.25%)or low(LW,6.25%)wilting rate.The HW soil was found to contain a higher abundance of Fusarium oxysporum(1.30-fold higher)than the LW soil,along with higher contents of available phosphorus(1.31-fold higher)and available potassium(2.39-fold higher).In addition,the interkingdom correlation between protists and bacteria in the HW soil was 2.08-fold higher than that in the LW soil.Furthermore,structural equation modeling revealed that an excess of soil available potassium enhanced the predation by potentially detrimental phagotrophic protists on potentially beneficial bacteria.In summary,our findings indicated that a balanced nutrient input and the interactions between protists(Cercomonas and Colpoda)and beneficial bacteria(Bacillus)played important roles in controlling the incidence of watermelon Fusarium wilt.
基金supported by the Scientific Research Fund Project of Education Department of Liaoning Province(LJKZZ20220060,LJKZ0514)Open Foundation of State Key Laboratory of Marine Food Processing&Safety Control(SKL202306).
文摘To achieve high production of arachidonic acid(ARA)through industrial fermentation of Mortierella alpina,the correlation between metal ions,mycelium pellet morphology and ARA production was investigated.By adding different metal ions to the culture medium,observing the morphological differences of mycelium pellet,total oil production and ARA content and established a correlation between them.The results showed that adding sodium ions increase the density of mycelium pellet,while reducing the diameter of mycelium pellet,resulting in a 41.59%increase in ARA production.Potassium ions,magnesium ions,calcium ions and iron ions slightly reduce the diameter of fungal hyphae and increase ARA production by 7.47%,17.81%,36.05%and 9.37%,respectively.At the same time,calcium ions promoted the branching growth of mycelium,which solve the problem of excessive free mycelium in fermentation broth within a certain concentration range.Zinc ions had a negative impact on bacterial growth,leading to the formation of mycelium clumps in the fermentation broth.Manganese ions and ferrous ions could transform the morphology of fungal mycelium into a smooth spherical surface,which was not conducive to the growth of M.alpina and the accumulation of oil.The comprehensive results showed that the optimal fermentation mycelium form for M.alpina was a dense central and loosely packed mycelium pellet.The yield of ARA was directly proportional to the density of mycelium pellet and inversely proportional to the diameter of mycelium pellet.
基金National Natural Science Foundation of China(Project No.:82205126)Scientific Research Project of Guangdong Provincial Administration of Traditional Chinese Medicine(Project No.:20251104)+2 种基金Guangdong Famous Traditional Chinese Medicine Studio(Jianxing Xie)Fourth batch of famous traditional Chinese medicine masterapprentice program in Guangdong Province in 2024(Jianxing Xie)Young and Middle-aged Key Talent Training Project of The First Affiliated Hospital of Guangzhou University of Chinese Medicine(Project No.:09005650043)。
文摘This review systematically elucidates the core mechanisms and research advancements regarding the role of autophagy in immune evasion in Renal Cell Carcinoma(RCC).Accumulating evidence indicates that autophagy exhibits a typical“context-dependent”dual role in RCC pathogenesis:it may suppress tumorigenesis in early stages,while primarily promoting cell survival and immunosuppressive functions within the established tumor microenvironment(TME).Autophagy facilitates immune escape through multi-dimensional mechanisms,including the precise regulation of PD-L1 stability,degradation of MHC-I molecules and the antigenic peptide pool,remodeling of the metabolic microenvironment,induction of T cell exhaustion,and enhancement of immunosuppressive cell functions.Therapeutically,combining autophagy inhibitors with immune checkpoint inhibitors has demonstrated significant synergistic effects in preclinical studies,and several clinical trials have provided preliminary validation of its safety and efficacy.Future research should focus on integrating multi-omics technologies and advanced disease models to deeply elucidate the autophagy regulatory network,explore its crosstalk with other cell death pathways such as pyroptosis and ferroptosis,and promote the development of personalized treatment strategies based on precise stratification of autophagy activity,thereby offering new avenues to overcome immunotherapy resistance in RCC.
基金financially supported by the National Key R&D Program of China(No.2022YFB3504700)the Strategic Priority Research Program of the Chinese Academy of Sciences(No.XDA0400304)the Research Fund of Key Laboratory of Rare Earth,Chinese Academy of Sciences(No.E32PF00116)。
文摘Efficient,safe,and economical hydrogen storage technology is vital for hydrogen’s broad use as an energy carrier,with V-based BCC alloys standing out for their high theoretical storage capacity.However,the high cost of V has restricted their practical application.In this work,a cost-effective Ti–Cr–(Fe V80)alloy was successfully synthesized through a pre-refinement process involving the addition of Y/Zr to the Fe V80 alloy.The resulting Ti_(27)Cr_(27)(Fe V80+Y)_(46)alloy exhibited an effective dehydriding capacity of 2.3 wt%,with a capacity retention rate of 97.2%after 200 cycles.Through the analysis of HSC Chemistry 6.0 software and backscattered electron(BSE),it has been discovered that the prerefinement process significantly reduces the presence of Al,Si,and O impurities,leading to improved compositional uniformity.After the re-refinement,the formation of the Ti–rich phases had been notably curbed.This,along with a marked decrease in the pressure–composition–temperature(PCT)curve’s slope factor from 1.58 to 0.36,results in enhanced hydriding capacity(from 3.2 wt%to 3.7 wt%),reversible dehydriding capacity(from 2.0 wt%to 2.3 wt%),and a remarkable increase in the capacity retention rate(from 75.8%to 97.2%).The kinetics and thermodynamic properties of the alloys were calculated using the Arrhenius and Van’t Hoff equations,providing insights into their performance characteristics.The mechanism behind the alloy’s improved cyclic stability has been elucidated through an analysis of lattice distortion and X-ray photoelectron spectroscopy(XPS).These findings open new routes for the development of cost-effective Fe V80-based hydrogen storage materials.
