Energy-saving buildings(ESBs)are an emerging green technology that can significantly reduce building-associated cooling and heating energy consumption,catering to the desire for carbon neutrality and sustainable devel...Energy-saving buildings(ESBs)are an emerging green technology that can significantly reduce building-associated cooling and heating energy consumption,catering to the desire for carbon neutrality and sustainable development of society.Smart photovoltaic windows(SPWs)offer a promising platform for designing ESBs because they present the capability to regulate and harness solar energy.With frequent outbreaks of extreme weather all over the world,the achievement of exceptional energy-saving effect under different weather conditions is an inevitable trend for the development of ESBs but is hardly achieved via existing SPWs.Here,we substantially reduce the driving voltage of polymerdispersed liquid crystals(PDLCs)by 28.1%via molecular engineering while maintaining their high solar transmittance(T_(sol)=83.8%,transparent state)and solar modulating ability(ΔT_(sol)=80.5%).By the assembly of perovskite solar cell and a broadband thermal-managing unit encompassing the electrical-responsive PDLCs,transparent high-emissivity SiO_(2) passive radiation-cooling,and Ag low-emissivity layers possesses,we present a tri-band regulation and split-type SPW possessing superb energy-saving effect in all-season.The perovskite solar cell can produce the electric power to stimulate the electrical-responsive behavior of the PDLCs,endowing the SPWs zero-energy input solar energy regulating characteristic,and compensate the daily energy consumption needed for ESBs.Moreover,the scalable manufacturing technology holds a great potential for the real-world applications.展开更多
Lead-halide perovskite solar cells(PSCs)have rapidly achieved certified efficiencies>27%,rivaling silicon photovoltaics.However,their commercialization is hindered by intrinsic material challenges:poor operational ...Lead-halide perovskite solar cells(PSCs)have rapidly achieved certified efficiencies>27%,rivaling silicon photovoltaics.However,their commercialization is hindered by intrinsic material challenges:poor operational stability under moisture,heat,and light;toxic lead leakage from degraded films.Metal-organic frameworks(MOFs),with their unique framework structure,large specific surface area,high heavy metal capturing capacity,and tunable conductivity,offer promising solutions to these issues.Recent studies have integrated MOFs into PSCs architectures to enhance performance and durability.This comprehensive review begins with an in-depth discussion of the structure,optical properties,electrical characteristics,and stability of MOFs,as well as their theoretical compatibility with perovskites.Subsequently,it provides a detailed analysis of how MOFs enhance charge carrier transport,promote perovskite crystallinity,improve device stability,and suppress lead leakage in PSCs.In summary,this review examines the research progress and potential of integrating MOFs with perovskites to address the critical PSCs challenges of efficiency,instability,and toxicity.展开更多
The past two years have witnessed remarkable progress in perovskite solar cells(PSCs),marked by breakthroughs in power conversion efficiency and strides in addressing long-term operational stability.At present,the cer...The past two years have witnessed remarkable progress in perovskite solar cells(PSCs),marked by breakthroughs in power conversion efficiency and strides in addressing long-term operational stability.At present,the certified power conversion efficiencies of singlejunction PSCs and silicon/perovskite tandem cells have surpassed 27%and 34%,respectively.Regarding stability,researchers begun to focus their attention on the challenges faced by PSCs when operated in outdoor environments.Furthermore,breakthroughs in the utilization of green solvents,fabrication in ambient air conditions,aqueous-phase synthesis of perovskite raw materials at kilogram scale,vacuum flash evaporation,and machine learning-assisted design are accelerating the commercialization of PSCs.The review summarizes the key advancements of PSCs during 2024-2025.It identifies a critical performance discrepancy between small-area devices and perovskite solar modules and delves into strategies aimed at bridging this gap.Finally,perspectives on the future directions of PSCs are presented,with a particular emphasis on improving photocurrent and environmental sustainability.展开更多
Hard carbon (HC) has been considered as promising anode material for sodium-ion batteries (SIBs).The optimization of hard carbon’s microstructure and solid electrolyte interface (SEI) property are demonstrated effect...Hard carbon (HC) has been considered as promising anode material for sodium-ion batteries (SIBs).The optimization of hard carbon’s microstructure and solid electrolyte interface (SEI) property are demonstrated effective in enhancing the Na+storage capability,however,a one-step regulation strategy to achieve simultaneous multi-scale structures optimization is highly desirable.Herein,we have systematically investigated the effects of boron doping on hard carbon’s microstructure and interface chemistry.A variety of structure characterizations show that appropriate amount of boron doping can increase the size of closed pores via rearrangement of carbon layers with improved graphitization degree,which provides more Na+storage sites.In-situ Fourier transform infrared spectroscopy/electrochemical impedance spectroscopy (FTIR/EIS) and X-ray photoelectron spectroscopy (XPS) analysis demonstrate the presence of more BC3and less B–C–O structures that result in enhanced ion diffusion kinetics and the formation of inorganic rich and robust SEI,which leads to facilitated charge transfer and excellent rate performance.As a result,the hard carbon anode with optimized boron doping content exhibits enhanced rate and cycling performance.In general,this work unravels the critical role of boron doping in optimizing the pore structure,interface chemistry and diffusion kinetics of hard carbon,which enables rational design of sodium-ion battery anode with enhanced Na+storage performance.展开更多
Controlling surface chemistry is critically important for improving the initial Coulombic efficiency(ICE)and adsorption capacity of hard carbon anode used in Li/Na/K-ion batteries.However,accurately identifying the ty...Controlling surface chemistry is critically important for improving the initial Coulombic efficiency(ICE)and adsorption capacity of hard carbon anode used in Li/Na/K-ion batteries.However,accurately identifying the types and concentrations of hydrogen/oxygen terminated functional groups(HTFG/OTFGs)and distinguishing their functionalities remain challenge.Herein,we quantitatively investigated the surface chemistry on hard carbon via ultra-high temperature programed desorption measurements,and uncovered the role of HTFG/OTFGs in influencing ICE and adsorption capacity in Li/Na/K-ions cells.The C-H group is found to be dominant species on the surface of hard carbon,and presents a positive correlation with ICE values and adsorption capacity.The low reactivity of C-H group with both electrolyte salt and solvent results in the formation of thinner and highly conducive solid electrolyte interphase(SEI)layer,which benefit for the enhanced ICE and improved Li/Na/K-ions diffusion across SEI layer.Additionally,the pimping trapping effect of C-H groups allows the adsorbed Li/Na/K-ions to migrate into graphitic interlayer quickly,enhancing the slope capacity.By fabricating a C-H group-rich surface chemistry on hard carbon,a high ICE value and satisfactory specific capacity have been realized.These findings enrich our understanding of the surface chemistry-induced interfacial reaction,which effectively guides the rational design of high-performance hard carbon.展开更多
As one of the most important industrially viable methods for carbon dioxide(CO_(2))utilization,methanol synthesis serves as a platform for production of green fuels and commodity chemicals.For sustainable methanol syn...As one of the most important industrially viable methods for carbon dioxide(CO_(2))utilization,methanol synthesis serves as a platform for production of green fuels and commodity chemicals.For sustainable methanol synthesis,In_(2)O_(3)is an ideal catalyst and has garnered significant attention.Herein,cubic In_(2)O_(3)nanoparticles were prepared via the precipitation method and evaluated for CO_(2)hydrogenation to produce methanol.During the initial 10 h of reaction,CO_(2)conversion gradually increased,accompanied by a slow decrease of methanol selectivity,and the reaction reached equilibrium after 10-20 h on stream.This activation and induction stage may be attributed to the sintering of In_(2)O_(3)nanoparticles and the creation of more oxygen vacancies on In_(2)O_(3)surfaces.Further experimental studies demonstrate that hydrogen induction created additional oxygen vacancies during the catalyst activation stage,enhancing the performance of In_(2)O_(3)catalyst for CO_(2)hydrogenation.Density functional theory calculations and microkinetic simulations further demonstrated that surfaces with higher oxygen vacancy coverages or hydroxylated surfaces formed during this induction period can enhance the reaction rate and increase the CO_(2)conversion.However,they predominantly promote the formation of CO instead of methanol,leading to reduced methanol selectivity.These predictions align well with the above-mentioned experimental observations.Our work thus provides an in-depth analysis of the induction stage of the CO_(2)hydrogenation process on In_(2)O_(3)nano-catalyst,and offers valuable insights for significantly improving the CO_(2)reactivity of In_(2)O_(3)-based catalysts while maintaining long-term stability.展开更多
The storage of solid waste in Bayan Obo has resulted in significant resource wastage and environmental concerns.In this study,an efficient process was developed to recover iron and rare earth elements(REEs)from this w...The storage of solid waste in Bayan Obo has resulted in significant resource wastage and environmental concerns.In this study,an efficient process was developed to recover iron and rare earth elements(REEs)from this waste by processes of hydrogen-based mineral phase transformation(HMPT),magnetic separation,and flotation.Under optimal HMPT conditions(525℃,12.5 min,and 30%H_(2)concentration),an iron concentrate with a TFe grade of 64.09%and a recovery of 95.33%was obtained.The magnetic properties of the solid waste were greatly enhanced by HMPT,allowing the effective magnetic separation of iron minerals.Further optimization of the flotation process resulted in a REEs concentrate with a rare earth oxide(REO)grade of 65%-70%and a REEs recovery of 60%-65%.Hematite was reduced to magnetite during HMPT,and bastnaesite was decomposed to REEs oxides and fluorides,and the particle structure was significantly destroyed.However,changes in monazite,fluorite,and barite were minimal.展开更多
Chronic hepatitis B virus(HBV)infection affects approximately 254 million individuals globally,contributing to significant morbidity and mortality due to HBV-related liver failure and cirrhosis,which result in million...Chronic hepatitis B virus(HBV)infection affects approximately 254 million individuals globally,contributing to significant morbidity and mortality due to HBV-related liver failure and cirrhosis,which result in millions of fatalities each year.Although approved antiviral nucleos(t)ide analogues can effectively suppress HBV replication,their ability to reduce hepatitis B surface antigen(HBsAg)levels in plasma remains limited.The clinical application of the immunomodulator interferon-alpha is restricted by concerns regarding its safety and the severity of associated adverse reactions,rendering long-term administration challenging.Therefore,current drug development efforts for chronic hepatitis B aim to achieve a functional cure,which is defined as HBsAg serological clearance and sustained suppression of HBV DNA.This review discusses recent advancements in novel direct-acting therapeutic strategies for the treatment of chronic hepatitis B by focusing on the progresses in HBV entry inhibitors,monoclonal antibodies,RNA interferences,and other agents that directly target the virus.Furthermore,we discuss the development of immunomodulatory therapies,including TLR-7/8 agonists,immune checkpoint inhibitors,and therapeutic vaccines.In the end,we conclude by highlighting the importance of the rational combination-strategy design to improve the functional cure rate of HBV.展开更多
Thermoelectric water spitting to hydrogen systems has great potential in the production of environment-friendly fuel using renewable solar energy in the future.In this work,we prepared porous nanosheet Mo doping Ni_(5...Thermoelectric water spitting to hydrogen systems has great potential in the production of environment-friendly fuel using renewable solar energy in the future.In this work,we prepared porous nanosheet Mo doping Ni_(5)P_(4)catalysts on nickel foam with efficient hydrogen evolution reaction(HER)and oxygen evolution reaction(OER)performance in alkaline media.Density Functional Theory(DFT)calculations and experimental studies have shown that Mo doping deadeneds the interaction between H and O atomic orbitals of transition state water molecules,effectively weakening the activation energy of H_(2)O dissociation.Therefore,Mo doping is favorable for enhancing HER activity with overpotential at 10 mA cm^(-2)of 93 mV and Tafel slope of 40.1 mV dec^(-1)in 1 M KOH.Besides,it exhibits high alkaline OER activity with an ultra-low overpotential of 200 mV at 10 mA cm^(-2).Moreover,this catalyst only needs 1.537 V in a dual-electrode configuration of the electrolytic cell,which is much lower than the commercial Pt/C-RuO_(2)couple(1.614 V).In addition,we have developed and constructed a solar thermoelectric generator(TEG)that is capable of floating on water.This TEG has a continuous power output and an exceptionally long lifespan,providing a stable power supply to the synthesized catalyst electrolyzer.It can produce a maximum power output of over 90 mW,meeting the requirement of converting solar radiation heat into usable electricity.As a result,the system achieves productivity of 0.11 mL min^(-1)H_(2).This solar thermal energy conversion technology shows the possibility of large-scale industrial production of H_(2)and provides a new idea for exploring heat source utilization.展开更多
Hydrogen-based mineral phase transformation(HMPT)technology has demonstrated its effectiveness in separating iron and enriching rare earths from Bayan Obo refractory ores.However,further research is needed to clarify ...Hydrogen-based mineral phase transformation(HMPT)technology has demonstrated its effectiveness in separating iron and enriching rare earths from Bayan Obo refractory ores.However,further research is needed to clarify the phase composition and floatability of rare earths obtained after HMPT owing to the associated phase transformations.This study explored the mineralogical characteristics and separation behavior of rare earths in HMPT-treated iron tailings.Process mineralogy studies conducted via BGRIMM process mineralogy analysis and X-ray diffraction revealed that the main valuable minerals in the tailings included rare-earth oxides(9.15wt%),monazite(5.31wt%),and fluorite(23.52wt%).The study also examined the impact of mineral liberation and gangue mineral intergrowth on flotation performance.Flotation tests achieved a rare-earth oxide(REO)grade of 74.12wt% with a recovery of 34.17% in open-circuit flotation,whereas closed-circuit flotation resulted in a REO grade of 60.27wt% with a recovery of 73%.Transmission electron microscopy and scanning electron microscopy coupled with energy-dispersive spectroscopy revealed that monazite remained stable during the HMPT process,while bastnaesite was transformed into Ce_(7)O_(12)and CeF_(3),leading to increased collector consumption.Nonetheless,the HMPT process did not significantly affect the flotation performance of rare earths.The enrichment of fluorite in the tailings highlighted its further recovery potential.The integration of HMPT with magnetic separation and flotation presents an efficient strategy for recovering rare earths,iron,and fluorite from Bayan Obo ores.展开更多
Nanoscale defects such as dislocations have a significant impact on the phonon thermal transport properties in non-metallic materials.To unravel these effects,an understanding of defect phonon modes is essential.Herei...Nanoscale defects such as dislocations have a significant impact on the phonon thermal transport properties in non-metallic materials.To unravel these effects,an understanding of defect phonon modes is essential.Herein,at the atomic scale,the localized phonons of individual dislocations at a Si/Ge interface are measured via monochromated electron energy loss spectroscopy in a scanning transmission electron microscope.These modes are then correlated with the local microstructure,further revealing the dislocation effects on the local thermal transport properties.The dislocation causes a phonon redshift of several milli-electron-volts within about two to four nanometers of the core,where both the strain field and Ge segregation play roles.With the presence of dislocation,the local interfacial thermal conductance can be either enhanced or reduced,depending on the complex interaction and competition between lattice disorder(dislocation)and element disorder(heterointerface mixing and Ge-segregation)at the interface.These findings provide valuable insights to improve the thermal properties of thermoelectric generators and thermal management systems through proper defect engineering.展开更多
Rapid technological advancements drive miniaturization and high energy density in devices,thereby increasing nanoscale thermal management demands and urging development of higher spatial resolution technologies for th...Rapid technological advancements drive miniaturization and high energy density in devices,thereby increasing nanoscale thermal management demands and urging development of higher spatial resolution technologies for thermal imaging and transport research.Here,we introduce an approach to measure nanoscale thermal resistance using in situ inelastic scanning transmission electron microscopy.By constructing unidirectional heating flux with controlled temperature gradients and analyzing electron energy-loss/gain signals under optimized acquisition conditions,nanometer-resolution in mapping phonon apparent temperature is achieved.Thus,interfacial thermal resistance is determined by calculating the ratio of interfacial temperature difference to bulk temperature gradient.This methodology enables direct measurement of thermal transport properties for atomic-scale structural features(e.g.,defects and heterointerfaces),resolving critical structure-performance relationships,providing a useful tool for investigating thermal phenomena at the(sub-)nanoscale.展开更多
The infinite-layer nickelates,proposed as analogs to superconducting cuprates,provide a promising platform for exploring the mechanisms of unconventional superconductivity.However,the superconductivity has been exclus...The infinite-layer nickelates,proposed as analogs to superconducting cuprates,provide a promising platform for exploring the mechanisms of unconventional superconductivity.However,the superconductivity has been exclusively observed in thin films under atmospheric pressure,underscoring the critical role of the heterointerface.展开更多
Although African swine fever(ASF) has been prevalent for more than a century, it remains the number one swine disease that seriously endangers the global pig industry, and there is no effective means of prevention and...Although African swine fever(ASF) has been prevalent for more than a century, it remains the number one swine disease that seriously endangers the global pig industry, and there is no effective means of prevention and treatment(Wang et al. 2023). Due to its enormous economic and social impact, it is listed as a notifiable animal disease by the World Organization for Animal Health(Costard et al. 2013). Although ASF has been present in Sub-Saharan Africa since its first discovery in Kenya.展开更多
SrRuO_(3)is a canonical itinerant ferromagnet,yet its properties in the extreme two-dimensional limit on a(111)crystal plane remain largely unexplored.Here,we demonstrate a complete transformation of its ground state ...SrRuO_(3)is a canonical itinerant ferromagnet,yet its properties in the extreme two-dimensional limit on a(111)crystal plane remain largely unexplored.Here,we demonstrate a complete transformation of its ground state driven by dimensional reduction.As the thickness of(111)-oriented SrRuO_(3)films is reduced to a few unit cells,the system transitions from a metallic ferromagnet to a semiconducting antiferromagnet.This emergent antiferromagnetism is evidenced by a vanishing magnetic remanence and most strikingly,by the appearance of an unconventional twelve-fold anisotropic magnetoresistance.First-principles calculations confirm that an A-type antiferromagnetic order is the stable ground state in the ultrathin limit.Our findings establish(111)dimensional engineering as a powerful route to manipulate correlated electron states and uncover novel functionalities for antiferromagnetic spintronics.展开更多
This article discusses a recent study by Wang et al that sheds light on the metabolic and immunological mechanisms driving the progression of metabolic dysfunction-associated fatty liver disease(MAFLD)to hepatocellula...This article discusses a recent study by Wang et al that sheds light on the metabolic and immunological mechanisms driving the progression of metabolic dysfunction-associated fatty liver disease(MAFLD)to hepatocellular carcinoma(HCC).The study highlights the role of mitochondrial carnitine palmitoyltransferase Ⅱ(CPT Ⅱ)inactivity,which activates liver cancer stem cells marked by cluster of differentiation 44(CD44)and CD24 expression,promoting HCC development.Using dynamic mouse models and clinical samples,Wang et al identified CPT Ⅱ downregulation,mitochondrial membrane potential alterations,and reduced intrahepatic CD4^(+)T cell as key drivers of disease progression.The findings link these changes to steroid biosynthesis and p53 signaling,contributing to T-cell dysfunction and immunosuppression.This article emphasizes the relevance of these results in understanding MAFLD pathogenesis and discusses potential therapeutic strategies targeting CPT Ⅱ activity,mitochondrial function,and immune surveillance to prevent or mitigate HCC development in advanced MAFLD.展开更多
Illegal hunting and trafficking of wildlife and their derivatives extort unprecedented population decline of relatively many species pushing them towards extinction.Notwithstanding contemporary counteracting intervent...Illegal hunting and trafficking of wildlife and their derivatives extort unprecedented population decline of relatively many species pushing them towards extinction.Notwithstanding contemporary counteracting interventions at international,regional,national and local levels,wildlife farming is advocated as an alternative approach to minimize pressure on wild populations.For wildlife farming to be an effective conservation tool,the integration of wildlife forensics is inevitable to allow distinction between captive-bred and wild-caught species.To this end,we analyzed methylation rates of skeletal muscle samples(pectoralis major,triceps brachii,gastrocnemius,biceps femoris,and neck muscles)from 60 captive-bred and 30 wild-caught Common Pheasant.A total of 13,507 differentially methylated regions were identified between five wild-caught and five captive-bred individuals through whole-genome methylation sequencing(WGBS).Based on the selected five methylation sites,LOC116231076,LOC116242223,ATAD2B,EGFL6,and HS2ST,quantitative detection technique was developed using methylation-sensitive high-resolution melting curve(MS-HRM)to measure methylation rates.The results showed significant differences in methylation rates at all differential sites between wild-caught and captive-bred individuals(|t|=0.67–33.10,P=0.000–0.042).The discrimination accuracy rate of each locus was highest in the gastrocnemius muscle and lowest in the neck muscle.The discrimination accuracy rate on LOC116231076,LOC116242223,ATAD2B,EGFL6,and HS2ST methylation sites for gastrocnemius muscle was 64.98%,100.00%,68.54%,63.79%,and 63.70%,respectively;and for neck muscle it was 67.42%,68.06%,83.61%,65.04%,and68.85%,respectively.The united discrimination accuracy rate of the five loci were 100.00%for gastrocnemius muscle,99.78%for biceps femoris muscle,97.52%for pectoralis major muscle,93.96%for triceps brachii muscle,and 91.63%for neck muscle,respectively.The panel also revealed excellent repeatability,reproducibility,sensitivity and universality to mammals and avian species.This study establishes an effective,accurate and low-cost identification technology for the identification of wild and farmed Common Pheasant,and also provides a reference for the development of identification methods for other species.展开更多
基金supported by Natural Science Foundation of China(Grant No.52372076,52073081,52203322,5252200843)Ministry of Science and Technology of the People’s Republic of China(2023YFB3812800)Fundamental Research Funds for the Central Universities(FRF-TP-25-073)。
文摘Energy-saving buildings(ESBs)are an emerging green technology that can significantly reduce building-associated cooling and heating energy consumption,catering to the desire for carbon neutrality and sustainable development of society.Smart photovoltaic windows(SPWs)offer a promising platform for designing ESBs because they present the capability to regulate and harness solar energy.With frequent outbreaks of extreme weather all over the world,the achievement of exceptional energy-saving effect under different weather conditions is an inevitable trend for the development of ESBs but is hardly achieved via existing SPWs.Here,we substantially reduce the driving voltage of polymerdispersed liquid crystals(PDLCs)by 28.1%via molecular engineering while maintaining their high solar transmittance(T_(sol)=83.8%,transparent state)and solar modulating ability(ΔT_(sol)=80.5%).By the assembly of perovskite solar cell and a broadband thermal-managing unit encompassing the electrical-responsive PDLCs,transparent high-emissivity SiO_(2) passive radiation-cooling,and Ag low-emissivity layers possesses,we present a tri-band regulation and split-type SPW possessing superb energy-saving effect in all-season.The perovskite solar cell can produce the electric power to stimulate the electrical-responsive behavior of the PDLCs,endowing the SPWs zero-energy input solar energy regulating characteristic,and compensate the daily energy consumption needed for ESBs.Moreover,the scalable manufacturing technology holds a great potential for the real-world applications.
基金financially supported by the National Natural Science foundation of China(grants nos.52272176)。
文摘Lead-halide perovskite solar cells(PSCs)have rapidly achieved certified efficiencies>27%,rivaling silicon photovoltaics.However,their commercialization is hindered by intrinsic material challenges:poor operational stability under moisture,heat,and light;toxic lead leakage from degraded films.Metal-organic frameworks(MOFs),with their unique framework structure,large specific surface area,high heavy metal capturing capacity,and tunable conductivity,offer promising solutions to these issues.Recent studies have integrated MOFs into PSCs architectures to enhance performance and durability.This comprehensive review begins with an in-depth discussion of the structure,optical properties,electrical characteristics,and stability of MOFs,as well as their theoretical compatibility with perovskites.Subsequently,it provides a detailed analysis of how MOFs enhance charge carrier transport,promote perovskite crystallinity,improve device stability,and suppress lead leakage in PSCs.In summary,this review examines the research progress and potential of integrating MOFs with perovskites to address the critical PSCs challenges of efficiency,instability,and toxicity.
基金the financial support of the National Natural Science Foundation of China(Nos.U21A20171,12074245,52102281)National Key R&D Program of China(Nos.2021YFB3800068 and 2020YFB1506400)+1 种基金Shanghai Sailing Program(No.21YF1421600)Young Elite Scientists Sponsorship Program by China Association for Science and Technology(No.2021QNRC001)。
文摘The past two years have witnessed remarkable progress in perovskite solar cells(PSCs),marked by breakthroughs in power conversion efficiency and strides in addressing long-term operational stability.At present,the certified power conversion efficiencies of singlejunction PSCs and silicon/perovskite tandem cells have surpassed 27%and 34%,respectively.Regarding stability,researchers begun to focus their attention on the challenges faced by PSCs when operated in outdoor environments.Furthermore,breakthroughs in the utilization of green solvents,fabrication in ambient air conditions,aqueous-phase synthesis of perovskite raw materials at kilogram scale,vacuum flash evaporation,and machine learning-assisted design are accelerating the commercialization of PSCs.The review summarizes the key advancements of PSCs during 2024-2025.It identifies a critical performance discrepancy between small-area devices and perovskite solar modules and delves into strategies aimed at bridging this gap.Finally,perspectives on the future directions of PSCs are presented,with a particular emphasis on improving photocurrent and environmental sustainability.
基金National Key Research and Development Program of China (2022YFE0206300)National Natural Science Foundation of China (U21A2081,22075074, 22209047)+3 种基金Guangdong Basic and Applied Basic Research Foundation (2024A1515011620)Hunan Provincial Natural Science Foundation of China (2024JJ5068)Foundation of Yuelushan Center for Industrial Innovation (2023YCII0119)Student Innovation Training Program (S202410532594,S202410532357)。
文摘Hard carbon (HC) has been considered as promising anode material for sodium-ion batteries (SIBs).The optimization of hard carbon’s microstructure and solid electrolyte interface (SEI) property are demonstrated effective in enhancing the Na+storage capability,however,a one-step regulation strategy to achieve simultaneous multi-scale structures optimization is highly desirable.Herein,we have systematically investigated the effects of boron doping on hard carbon’s microstructure and interface chemistry.A variety of structure characterizations show that appropriate amount of boron doping can increase the size of closed pores via rearrangement of carbon layers with improved graphitization degree,which provides more Na+storage sites.In-situ Fourier transform infrared spectroscopy/electrochemical impedance spectroscopy (FTIR/EIS) and X-ray photoelectron spectroscopy (XPS) analysis demonstrate the presence of more BC3and less B–C–O structures that result in enhanced ion diffusion kinetics and the formation of inorganic rich and robust SEI,which leads to facilitated charge transfer and excellent rate performance.As a result,the hard carbon anode with optimized boron doping content exhibits enhanced rate and cycling performance.In general,this work unravels the critical role of boron doping in optimizing the pore structure,interface chemistry and diffusion kinetics of hard carbon,which enables rational design of sodium-ion battery anode with enhanced Na+storage performance.
基金financially supported by the National Key Research and Development Program of China(2022YFE0206300)the National Natural Science Foundation of China(U21A2081,22075074,22209047)+4 种基金the National College Students Innovation and Entrepreneurship Training Program(S202410532594,S202410532357)the Macao Science and Technology Development Fund(File No.0013/2021/AMJ)the Foundation of Yuelushan Center for Industrial Innovation(2023YCII0119)JST SICORP(JPMJSC2112)JST PRESTO(JPMJPR23QA)。
文摘Controlling surface chemistry is critically important for improving the initial Coulombic efficiency(ICE)and adsorption capacity of hard carbon anode used in Li/Na/K-ion batteries.However,accurately identifying the types and concentrations of hydrogen/oxygen terminated functional groups(HTFG/OTFGs)and distinguishing their functionalities remain challenge.Herein,we quantitatively investigated the surface chemistry on hard carbon via ultra-high temperature programed desorption measurements,and uncovered the role of HTFG/OTFGs in influencing ICE and adsorption capacity in Li/Na/K-ions cells.The C-H group is found to be dominant species on the surface of hard carbon,and presents a positive correlation with ICE values and adsorption capacity.The low reactivity of C-H group with both electrolyte salt and solvent results in the formation of thinner and highly conducive solid electrolyte interphase(SEI)layer,which benefit for the enhanced ICE and improved Li/Na/K-ions diffusion across SEI layer.Additionally,the pimping trapping effect of C-H groups allows the adsorbed Li/Na/K-ions to migrate into graphitic interlayer quickly,enhancing the slope capacity.By fabricating a C-H group-rich surface chemistry on hard carbon,a high ICE value and satisfactory specific capacity have been realized.These findings enrich our understanding of the surface chemistry-induced interfacial reaction,which effectively guides the rational design of high-performance hard carbon.
文摘As one of the most important industrially viable methods for carbon dioxide(CO_(2))utilization,methanol synthesis serves as a platform for production of green fuels and commodity chemicals.For sustainable methanol synthesis,In_(2)O_(3)is an ideal catalyst and has garnered significant attention.Herein,cubic In_(2)O_(3)nanoparticles were prepared via the precipitation method and evaluated for CO_(2)hydrogenation to produce methanol.During the initial 10 h of reaction,CO_(2)conversion gradually increased,accompanied by a slow decrease of methanol selectivity,and the reaction reached equilibrium after 10-20 h on stream.This activation and induction stage may be attributed to the sintering of In_(2)O_(3)nanoparticles and the creation of more oxygen vacancies on In_(2)O_(3)surfaces.Further experimental studies demonstrate that hydrogen induction created additional oxygen vacancies during the catalyst activation stage,enhancing the performance of In_(2)O_(3)catalyst for CO_(2)hydrogenation.Density functional theory calculations and microkinetic simulations further demonstrated that surfaces with higher oxygen vacancy coverages or hydroxylated surfaces formed during this induction period can enhance the reaction rate and increase the CO_(2)conversion.However,they predominantly promote the formation of CO instead of methanol,leading to reduced methanol selectivity.These predictions align well with the above-mentioned experimental observations.Our work thus provides an in-depth analysis of the induction stage of the CO_(2)hydrogenation process on In_(2)O_(3)nano-catalyst,and offers valuable insights for significantly improving the CO_(2)reactivity of In_(2)O_(3)-based catalysts while maintaining long-term stability.
基金supported by the National Key R&D Program of China(No.2021YFC2901000)the Key Program of National Natural Science Foundation of China(No.52130406)+1 种基金the Natural Science Foundation Innovation Group Project of Hubei Province(No.2023AFA044)the Fundamental Research Funds for the Central Universities(No.N2301002)。
文摘The storage of solid waste in Bayan Obo has resulted in significant resource wastage and environmental concerns.In this study,an efficient process was developed to recover iron and rare earth elements(REEs)from this waste by processes of hydrogen-based mineral phase transformation(HMPT),magnetic separation,and flotation.Under optimal HMPT conditions(525℃,12.5 min,and 30%H_(2)concentration),an iron concentrate with a TFe grade of 64.09%and a recovery of 95.33%was obtained.The magnetic properties of the solid waste were greatly enhanced by HMPT,allowing the effective magnetic separation of iron minerals.Further optimization of the flotation process resulted in a REEs concentrate with a rare earth oxide(REO)grade of 65%-70%and a REEs recovery of 60%-65%.Hematite was reduced to magnetite during HMPT,and bastnaesite was decomposed to REEs oxides and fluorides,and the particle structure was significantly destroyed.However,changes in monazite,fluorite,and barite were minimal.
文摘Chronic hepatitis B virus(HBV)infection affects approximately 254 million individuals globally,contributing to significant morbidity and mortality due to HBV-related liver failure and cirrhosis,which result in millions of fatalities each year.Although approved antiviral nucleos(t)ide analogues can effectively suppress HBV replication,their ability to reduce hepatitis B surface antigen(HBsAg)levels in plasma remains limited.The clinical application of the immunomodulator interferon-alpha is restricted by concerns regarding its safety and the severity of associated adverse reactions,rendering long-term administration challenging.Therefore,current drug development efforts for chronic hepatitis B aim to achieve a functional cure,which is defined as HBsAg serological clearance and sustained suppression of HBV DNA.This review discusses recent advancements in novel direct-acting therapeutic strategies for the treatment of chronic hepatitis B by focusing on the progresses in HBV entry inhibitors,monoclonal antibodies,RNA interferences,and other agents that directly target the virus.Furthermore,we discuss the development of immunomodulatory therapies,including TLR-7/8 agonists,immune checkpoint inhibitors,and therapeutic vaccines.In the end,we conclude by highlighting the importance of the rational combination-strategy design to improve the functional cure rate of HBV.
基金supported by the Hainan Provincial Natural Science Foundation of China(Nos.522MS038 and 522QN282)the National Natural Science Foundation of China(Nos.52172086 and 52301268)the Start-up Research Foundation of Hainan University(No.KYQD(ZR)-22019).
文摘Thermoelectric water spitting to hydrogen systems has great potential in the production of environment-friendly fuel using renewable solar energy in the future.In this work,we prepared porous nanosheet Mo doping Ni_(5)P_(4)catalysts on nickel foam with efficient hydrogen evolution reaction(HER)and oxygen evolution reaction(OER)performance in alkaline media.Density Functional Theory(DFT)calculations and experimental studies have shown that Mo doping deadeneds the interaction between H and O atomic orbitals of transition state water molecules,effectively weakening the activation energy of H_(2)O dissociation.Therefore,Mo doping is favorable for enhancing HER activity with overpotential at 10 mA cm^(-2)of 93 mV and Tafel slope of 40.1 mV dec^(-1)in 1 M KOH.Besides,it exhibits high alkaline OER activity with an ultra-low overpotential of 200 mV at 10 mA cm^(-2).Moreover,this catalyst only needs 1.537 V in a dual-electrode configuration of the electrolytic cell,which is much lower than the commercial Pt/C-RuO_(2)couple(1.614 V).In addition,we have developed and constructed a solar thermoelectric generator(TEG)that is capable of floating on water.This TEG has a continuous power output and an exceptionally long lifespan,providing a stable power supply to the synthesized catalyst electrolyzer.It can produce a maximum power output of over 90 mW,meeting the requirement of converting solar radiation heat into usable electricity.As a result,the system achieves productivity of 0.11 mL min^(-1)H_(2).This solar thermal energy conversion technology shows the possibility of large-scale industrial production of H_(2)and provides a new idea for exploring heat source utilization.
基金the financial support received from the Key Program of National Natural Science Foundation of China(No.52130406)the National Key R&D Program of China(Nos.2021YFC2901000 and 2022YFC2905800)+1 种基金the General Program of National Natural Science Foundation of China(No.52274253)Natural Science Foundation Innovation Group Project of Hubei Province,China(No.2023AFA044)。
文摘Hydrogen-based mineral phase transformation(HMPT)technology has demonstrated its effectiveness in separating iron and enriching rare earths from Bayan Obo refractory ores.However,further research is needed to clarify the phase composition and floatability of rare earths obtained after HMPT owing to the associated phase transformations.This study explored the mineralogical characteristics and separation behavior of rare earths in HMPT-treated iron tailings.Process mineralogy studies conducted via BGRIMM process mineralogy analysis and X-ray diffraction revealed that the main valuable minerals in the tailings included rare-earth oxides(9.15wt%),monazite(5.31wt%),and fluorite(23.52wt%).The study also examined the impact of mineral liberation and gangue mineral intergrowth on flotation performance.Flotation tests achieved a rare-earth oxide(REO)grade of 74.12wt% with a recovery of 34.17% in open-circuit flotation,whereas closed-circuit flotation resulted in a REO grade of 60.27wt% with a recovery of 73%.Transmission electron microscopy and scanning electron microscopy coupled with energy-dispersive spectroscopy revealed that monazite remained stable during the HMPT process,while bastnaesite was transformed into Ce_(7)O_(12)and CeF_(3),leading to increased collector consumption.Nonetheless,the HMPT process did not significantly affect the flotation performance of rare earths.The enrichment of fluorite in the tailings highlighted its further recovery potential.The integration of HMPT with magnetic separation and flotation presents an efficient strategy for recovering rare earths,iron,and fluorite from Bayan Obo ores.
基金supported by the National Natural Science Foundation of China(Grant No.52125307)the National Key R&D Program of China(Grant No.2021YFB3501500)the support from the New Cornerstone Science Foundation through the XPLORER PRIZE。
文摘Nanoscale defects such as dislocations have a significant impact on the phonon thermal transport properties in non-metallic materials.To unravel these effects,an understanding of defect phonon modes is essential.Herein,at the atomic scale,the localized phonons of individual dislocations at a Si/Ge interface are measured via monochromated electron energy loss spectroscopy in a scanning transmission electron microscope.These modes are then correlated with the local microstructure,further revealing the dislocation effects on the local thermal transport properties.The dislocation causes a phonon redshift of several milli-electron-volts within about two to four nanometers of the core,where both the strain field and Ge segregation play roles.With the presence of dislocation,the local interfacial thermal conductance can be either enhanced or reduced,depending on the complex interaction and competition between lattice disorder(dislocation)and element disorder(heterointerface mixing and Ge-segregation)at the interface.These findings provide valuable insights to improve the thermal properties of thermoelectric generators and thermal management systems through proper defect engineering.
基金supported by the National Natural Science Foundation of China(Grant No.52125307)the National Key R&D Program of China(Grant No.2021YFB3501500)the support from the New Cornerstone Science Foundation through the XPLORER PRIZE。
文摘Rapid technological advancements drive miniaturization and high energy density in devices,thereby increasing nanoscale thermal management demands and urging development of higher spatial resolution technologies for thermal imaging and transport research.Here,we introduce an approach to measure nanoscale thermal resistance using in situ inelastic scanning transmission electron microscopy.By constructing unidirectional heating flux with controlled temperature gradients and analyzing electron energy-loss/gain signals under optimized acquisition conditions,nanometer-resolution in mapping phonon apparent temperature is achieved.Thus,interfacial thermal resistance is determined by calculating the ratio of interfacial temperature difference to bulk temperature gradient.This methodology enables direct measurement of thermal transport properties for atomic-scale structural features(e.g.,defects and heterointerfaces),resolving critical structure-performance relationships,providing a useful tool for investigating thermal phenomena at the(sub-)nanoscale.
基金supported by the National Natural Science Foundation of China[52125307(to P.G.),12404192(to R.C.S),12274061(to L.Q.)]Key Research and Development Program from the Ministry of Science and Technology(2023YFA1406301)the support from the New Cornerstone Science Foundation through the XPLORER PRIZE。
文摘The infinite-layer nickelates,proposed as analogs to superconducting cuprates,provide a promising platform for exploring the mechanisms of unconventional superconductivity.However,the superconductivity has been exclusively observed in thin films under atmospheric pressure,underscoring the critical role of the heterointerface.
基金supported by the National Key Research and Development Program of China (2021YFD1800100)the earmarked fund for China Agriculture Research System (CARS-35)。
文摘Although African swine fever(ASF) has been prevalent for more than a century, it remains the number one swine disease that seriously endangers the global pig industry, and there is no effective means of prevention and treatment(Wang et al. 2023). Due to its enormous economic and social impact, it is listed as a notifiable animal disease by the World Organization for Animal Health(Costard et al. 2013). Although ASF has been present in Sub-Saharan Africa since its first discovery in Kenya.
基金supported by the National Natural Science Foundation of China(Grant Nos.12204521,12250710675,and 12504198)the National Key R&D Program of China(Grant No.2022YFA1403000)。
文摘SrRuO_(3)is a canonical itinerant ferromagnet,yet its properties in the extreme two-dimensional limit on a(111)crystal plane remain largely unexplored.Here,we demonstrate a complete transformation of its ground state driven by dimensional reduction.As the thickness of(111)-oriented SrRuO_(3)films is reduced to a few unit cells,the system transitions from a metallic ferromagnet to a semiconducting antiferromagnet.This emergent antiferromagnetism is evidenced by a vanishing magnetic remanence and most strikingly,by the appearance of an unconventional twelve-fold anisotropic magnetoresistance.First-principles calculations confirm that an A-type antiferromagnetic order is the stable ground state in the ultrathin limit.Our findings establish(111)dimensional engineering as a powerful route to manipulate correlated electron states and uncover novel functionalities for antiferromagnetic spintronics.
文摘This article discusses a recent study by Wang et al that sheds light on the metabolic and immunological mechanisms driving the progression of metabolic dysfunction-associated fatty liver disease(MAFLD)to hepatocellular carcinoma(HCC).The study highlights the role of mitochondrial carnitine palmitoyltransferase Ⅱ(CPT Ⅱ)inactivity,which activates liver cancer stem cells marked by cluster of differentiation 44(CD44)and CD24 expression,promoting HCC development.Using dynamic mouse models and clinical samples,Wang et al identified CPT Ⅱ downregulation,mitochondrial membrane potential alterations,and reduced intrahepatic CD4^(+)T cell as key drivers of disease progression.The findings link these changes to steroid biosynthesis and p53 signaling,contributing to T-cell dysfunction and immunosuppression.This article emphasizes the relevance of these results in understanding MAFLD pathogenesis and discusses potential therapeutic strategies targeting CPT Ⅱ activity,mitochondrial function,and immune surveillance to prevent or mitigate HCC development in advanced MAFLD.
基金supported by the Fundamental Research Funds for the Central Universities(2572020DR10)Project on the Investigation,Supervision and Industry Regulation of Rare and Endangered Species(2024)。
文摘Illegal hunting and trafficking of wildlife and their derivatives extort unprecedented population decline of relatively many species pushing them towards extinction.Notwithstanding contemporary counteracting interventions at international,regional,national and local levels,wildlife farming is advocated as an alternative approach to minimize pressure on wild populations.For wildlife farming to be an effective conservation tool,the integration of wildlife forensics is inevitable to allow distinction between captive-bred and wild-caught species.To this end,we analyzed methylation rates of skeletal muscle samples(pectoralis major,triceps brachii,gastrocnemius,biceps femoris,and neck muscles)from 60 captive-bred and 30 wild-caught Common Pheasant.A total of 13,507 differentially methylated regions were identified between five wild-caught and five captive-bred individuals through whole-genome methylation sequencing(WGBS).Based on the selected five methylation sites,LOC116231076,LOC116242223,ATAD2B,EGFL6,and HS2ST,quantitative detection technique was developed using methylation-sensitive high-resolution melting curve(MS-HRM)to measure methylation rates.The results showed significant differences in methylation rates at all differential sites between wild-caught and captive-bred individuals(|t|=0.67–33.10,P=0.000–0.042).The discrimination accuracy rate of each locus was highest in the gastrocnemius muscle and lowest in the neck muscle.The discrimination accuracy rate on LOC116231076,LOC116242223,ATAD2B,EGFL6,and HS2ST methylation sites for gastrocnemius muscle was 64.98%,100.00%,68.54%,63.79%,and 63.70%,respectively;and for neck muscle it was 67.42%,68.06%,83.61%,65.04%,and68.85%,respectively.The united discrimination accuracy rate of the five loci were 100.00%for gastrocnemius muscle,99.78%for biceps femoris muscle,97.52%for pectoralis major muscle,93.96%for triceps brachii muscle,and 91.63%for neck muscle,respectively.The panel also revealed excellent repeatability,reproducibility,sensitivity and universality to mammals and avian species.This study establishes an effective,accurate and low-cost identification technology for the identification of wild and farmed Common Pheasant,and also provides a reference for the development of identification methods for other species.
