The emergence offlexible organic crystals changed the perception of molecu-lar crystals that were regarded as brittle entities over a long period of time,and sparked a great interest in exploring mechanically complian...The emergence offlexible organic crystals changed the perception of molecu-lar crystals that were regarded as brittle entities over a long period of time,and sparked a great interest in exploring mechanically compliant organic crystalline materials toward next-generation smart materials during the past decade.Schiff base compounds are considered to be one of the most promising candidates forflexible organic crystals owing to their easy synthesis,high yield,stimuli respon-siveness and good mechanical properties.This paper gives an overview of the recent development of Schiff baseflexible organic crystals(including elastic organic crystals,plastic organic crystals,andflexible organic crystals integrating elastic-ity and plasticity)from serendipitous discovery to design strategies and versatile applications such as stimuli responses,optical waveguides,optoelectronic devices,biomimetic soft robots,and organic photonic integrated circuits.Notably,atomic force microscopy-micromanipulation technique has been utilized to bring the mul-tifunctional applications offlexible organic crystals from the macroscopic level to the microscopic world.Since understanding mechanicalflexibility at the molec-ular level through crystal engineering can assist us to trace down the structural origin of mechanical properties,we focus on the packing structures of various Schiff baseflexible organic crystals driven by non-covalent intermolecular inter-actions and their close correlation with mechanical behaviors.We hope that the information given here will help in the design of novelflexible organic crys-tals combined with other unique properties,and promote further research into the area of mechanically compliant organic crystalline materials toward multifunctional applications.展开更多
A novel host-vip luminous system with enhanced near-UV light absorption thereby enhanced luminescence are designed based on the synergism of quantum confinement,spatial confinement,and antenna effect,where ultrasmal...A novel host-vip luminous system with enhanced near-UV light absorption thereby enhanced luminescence are designed based on the synergism of quantum confinement,spatial confinement,and antenna effect,where ultrasmall Y_(2)O_(3):Eu^(3+)nanocrystals are fixed inside MOF(Eu/Y-BTC)as supporting structure.The Eu/Y-BTC not only limits the size and leads to lattice distortion of Y_(2)O_(3):Eu^(3+)nanocrystals and controls the distance between nanocrystals,but also promotes the light absorption and emission.The significantly red-shifted and broadened charge transfer band of Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)leads to the excellent applications of Y_(2)O_(3):Eu^(3+)in white light-emitting diodes(LEDs).Our results show that white light with superior color quality(CRI>90)and extremely high luminous efficacy(an LER of 335 lm/W)could be achieved using Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)as red phosphor.The Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)also improves the photoelectric performance of dye-sensitized solar cells(DSSCs),not only because Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)has a large specific surface area and the adsorption amount of the dye is increased,but also because the valence band position of Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)is 2.41 eV,which can provide an additional energy level between the TiO2 and dye,promoting electron transfer.For these advantageous features,the multifunctional Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)composite product will open new avenues in white LEDs and DSSCs.展开更多
Stemming from the unique in-plane honeycomb lattice structure and the sp^(2)hybridized carbon atoms bonded by exceptionally strong carbon–carbon bonds,graphene exhibits remarkable anisotropic electrical,mechanical,an...Stemming from the unique in-plane honeycomb lattice structure and the sp^(2)hybridized carbon atoms bonded by exceptionally strong carbon–carbon bonds,graphene exhibits remarkable anisotropic electrical,mechanical,and thermal properties.To maximize the utilization of graphene’s in-plane properties,pre-constructed and aligned structures,such as oriented aerogels,films,and fibers,have been designed.The unique combination of aligned structure,high surface area,excellent electrical conductivity,mechanical stability,thermal conductivity,and porous nature of highly aligned graphene aerogels allows for tailored and enhanced performance in specific directions,enabling advancements in diverse fields.This review provides a comprehensive overview of recent advances in highly aligned graphene aerogels and their composites.It highlights the fabrication methods of aligned graphene aerogels and the optimization of alignment which can be estimated both qualitatively and quantitatively.The oriented scaffolds endow graphene aerogels and their composites with anisotropic properties,showing enhanced electrical,mechanical,and thermal properties along the alignment at the sacrifice of the perpendicular direction.This review showcases remarkable properties and applications of aligned graphene aerogels and their composites,such as their suitability for electronics,environmental applications,thermal management,and energy storage.Challenges and potential opportunities are proposed to offer new insights into prospects of this material.展开更多
A multifunctional apparatus for microwave plasma reaction has been set up, which can be used in the fields such as Chemical synthesis, surface modification, and heterogeneous catalysis. This apparatus has laid an exp...A multifunctional apparatus for microwave plasma reaction has been set up, which can be used in the fields such as Chemical synthesis, surface modification, and heterogeneous catalysis. This apparatus has laid an experimental foundation for new methods, new technologies, and new train of thoughts to be explored.展开更多
One-dimensional(1D)SiO_(2) nanofibers(SNFs),one of the most popular inorganic nanomaterials,have aroused widespread attention because of their excellent chemical stability,as well as unique optical and thermal charact...One-dimensional(1D)SiO_(2) nanofibers(SNFs),one of the most popular inorganic nanomaterials,have aroused widespread attention because of their excellent chemical stability,as well as unique optical and thermal characteristics.Electrospinning is a straightforward and versatile method to prepare 1D SNFs with programmable structures,manageable dimensions,and modifiable properties,which hold great potential in many cutting-edge applications including aerospace,nanodevice,and energy.In this review,substantial advances in the structural design,controllable synthesis,and multifunctional applications of electrospun SNFs are highlighted.We begin with a brief introduction to the fundamental principles,available raw materials,and typical apparatus of electrospun SNFs.We then discuss the strategies for preparing SNFs with diverse structures in detail,especially stressing the newly emerging three-dimensional SiO_(2) nanofibrous aerogels.We continue with focus on major breakthroughs about brittleness-to-flexibility transition of SNFs and the means to achieve their mechanical reinforcement.In addition,we showcase recent applications enabled by electrospun SNFs,with particular emphasis on physical protection,health care and water treatment.In the end,we summarize this review and provide some perspectives on the future development direction of electrospun SNFs.展开更多
The urgent demand for renewable energy solutions,propelled by the global energy crisis and environmental concerns,has spurred the creation of innovative materials for solar thermal storage.Photothermal phase change ma...The urgent demand for renewable energy solutions,propelled by the global energy crisis and environmental concerns,has spurred the creation of innovative materials for solar thermal storage.Photothermal phase change materials(PTPCMs)represent a novel type of composite phase change material(PCM)aimed at improving thermal storage efficiency by incorporating photothermal materials into traditional PCMs and encapsulating them within porous structures.Various porous encapsulation materials have been studied,including porous carbon,expanded graphite,and ceramics,but issues like brittleness hinder their practical use.To overcome these limitations,flexible PTPCMs using organic porous polymers—like foams,hydrogels,and porous wood—have emerged,offering high porosity and lightweight characteristics.This review examines recent advancements in the preparation of PTPCMs based on porous polymer supports through techniques like impregnation and in situ polymerization,assessing the impact of different porous polymer materials on PCM performance and clarifying the mechanisms of photothermal conversion and heat storage.Subsequently,the most recent advancements in the applications of porous polymer-based PTPCMs are systematically summarized,and future research challenges and possible solutions are discussed.This review aims to foster awareness about the potential of PTPCMs in promoting environmentally friendly energy practices and catalyzing further research in this promising field.展开更多
Nanocomposite fibers are fibrous materials with specific properties and functionalities,which are prepared by introducing nanomaterials or nanostructures in the fibers.Polymeric nanocomposite fibers exhibit multiple f...Nanocomposite fibers are fibrous materials with specific properties and functionalities,which are prepared by introducing nanomaterials or nanostructures in the fibers.Polymeric nanocomposite fibers exhibit multiple functionalities,showing great application potential in healthcare,aerospace,mechanical engineering,and energy storage.Here,six functionalities of polymer nanocomposite fibers are reviewed:mechanical reinforcement,resistance to electromagnetic interference and flame,thermal and electrical conduction,generation of far-infrared ray,negative ion and electricity,energy storage,and sensing.For each functionality,the fiber component selection and preparation methods are summarized.The commonly used polymers comprise natural and synthetic polymers,and typical nanomaterials include carbon-based,polymer-based,metal-based,and metal oxide-based ones.Various compounding strategies and spinning approaches,such as wet-spinning,melt-spinning,and electrospinning,are introduced.Moreover,the functional properties of fibers fabricated from different constituents and by different strategies are compared,providing a reference for performance optimization.Finally,the prospective directions of research and application are discussed,and possible approaches are suggested to facilitate the development of advanced nanocomposite fibers.展开更多
Rare earth ions(RE^(3+))-doped double perovskites have attracted tremendous attention for its fascinating optical properties.Nevertheless,RE^(3+)generally exhibits poor photoluminescence quantum yield(PLQY)for their p...Rare earth ions(RE^(3+))-doped double perovskites have attracted tremendous attention for its fascinating optical properties.Nevertheless,RE^(3+)generally exhibits poor photoluminescence quantum yield(PLQY)for their parity-forbidden 4f-4f transition and the low doping concentration.Herein,we reported Sb^(3+)/Sm^(3+)-codoped rare earth-based double perovskite Cs_(2)Na Lu Cl_(6)that enables efficient visible and nearinfrared(NIR)emission,which stems from self-trapped exciton(STE)and Sm^(3+),respectively.Benefit from up to 72.89%energy transfer efficiency from STE to Sm^(3+)and high doping concentrations due to similar ionic activity between Sm^(3+)and Lu^(3+),thus eruptive PLQY of 74.58%in the visible light region and 23.12%in the NIR light region can be obtained.Moreover,Sb^(3+)/Sm^(3+)-codoped Cs_(2)Na Lu Cl_(6)exhibits tunable emission characteristic in the visible light region under different excitation wavelengths,which can change from blue emission(254 nm excitation)to white emission(365 nm excitation).More particularly,only the NIR emission can be captured by the NIR camera when a 700 nm cutoff filter is added.The excellent stability and unique optical properties of Sb^(3+)/Sm^(3+)-codoped Cs_(2)Na Lu Cl_(6)enable us to demonstrate its applications in NIR light-emitting diode,triple-mode fluorescence anti-counterfeiting and information encryption.These findings provide new inspiration for the application of rare earth-based double perovskite in optoelectronic devices.展开更多
Liquid leakage of PCM and thermophysical performance defects seriously affect the application prospect of PCMs.Aerogels provide an excellent solution for packaging and performance improvement of PCMs with its ultra-hi...Liquid leakage of PCM and thermophysical performance defects seriously affect the application prospect of PCMs.Aerogels provide an excellent solution for packaging and performance improvement of PCMs with its ultra-high specific surface area and low density and give PCMs other functions besides energy storage,such as energy conversion(photothermal/electrothermal conversion,magnetic thermal/acoustic thermal conversion),thermal management(battery thermal management,electronic thermal management),thermal infrared stealth,building materials,etc.In this paper,firstly,the preparation method and multifunctional response mechanism of aerogelbased PCMs are systematically described,and the improvement of thermophysical and mechanical properties of various aerogel-based PCMs is reviewed from the perspective of aerogel preparation.Then,according to the different application scenarios of aerogel-based PCMs,the advanced functions of aerogel-based PCMs are reviewed,and the multifunctional effects of different materials in aerogel-based PCMs are compared.Finally,some insightful guidance and suggestions for the research and development of aerogel-based PCMs are put forward.展开更多
The traditional inflexible electromagnetic interference(EMI)shielding materials have poor adaptability to wearable and portable flexible electronic devices due to their shortcomings such as brittleness and difficulty ...The traditional inflexible electromagnetic interference(EMI)shielding materials have poor adaptability to wearable and portable flexible electronic devices due to their shortcomings such as brittleness and difficulty in machinability.As an optimized alternative,the conductive polymer composites(CPCs)constructed by integrating MXene and polymer have become one of the most promising EMI shielding materials.To cope with the more harsh application conditions,the processing-structure-property relationship of MXene/polymer EMI shielding composites urgently needs to be clarified.In this review,the EMI shielding mechanism and theory of CPCs are first outlined.Then,the recent advances in processing strategies for MXene/polymer EMI shielding composites with different structures are comprehensively summarized,including layered structure,segregated structure,and porous structure.Next,the multifunctionality of MXene/polymer EMI shielding composites in hydrophobicity,flame retardancy,thermal conductivity,infrared thermal camouflage,electrothermal conversion,photothermal conversion,and sensing function,is systematically introduced.Finally,the prospects and challenges for the future development and application of multifunctional MXene/polymer EMI shielding composites are discussed.This review aims to put forward effective guidance for fabricating intelligent,adaptable,and integrated MXene/polymer EMI shielding composites,thus promoting the upgrading of advanced MXene-based CPCs.展开更多
1. Introduction The study of multifunction has been developed extensively with application to mathematics in economics, optimal control, game theory, mathematical programming and decision prooess, etc. Especially, it ...1. Introduction The study of multifunction has been developed extensively with application to mathematics in economics, optimal control, game theory, mathematical programming and decision prooess, etc. Especially, it has been widely used in mathematical economics. Debreu’s work Theory of Value is closely related to the method of multifunction which economists called correspondence. Economic equilibrium theory has long been treated by calculus since Walras. Von Neumann’s work in 1943 on economic theory has been an initiative to form a’new kind of mathematical method to economic theory and reduced the dependence on calculus. The early development of mathematical economics including the 19th century and even up to the World War Ⅱ was largely in terms of calculus; it was doubtless that th(?)展开更多
Paper-based relics as important carriers of human history and civilization have been facing severe damage problems,and their protection is a major project for cultural heritage restoration.So far,safe,high-efficiency,...Paper-based relics as important carriers of human history and civilization have been facing severe damage problems,and their protection is a major project for cultural heritage restoration.So far,safe,high-efficiency,and multifunctional protection materials are still urgent to be developed.Herein,through screening a series of alkaline nano-oxides and cleverly combining the advantages of modified natural polymer(quaternized chitosan)and inorganic nanomaterials(Zn O),we successfully prepared their functional nanocomposites with multiple properties and pioneered their smart application for multifunctional protection of paper relics.By spraying loads,this kind of nanocomposites can effectively and safely inhibit the acid degradation of paper relics and long-term maintain a natural or weak basic state even under harsh accelerated aging conditions.Meanwhile,the coating of nanocomposites does not change the chromatic aberration but partially improves the hydrophobicity.Moreover,the mechanical properties of paper relics are reinforced up to more than one time for all-around tensile strength,folding endurance,and tearing strength.It is worth noting that the usage of nanocomposites can avoid the discoloration or fading of p H-sensitive pigments/dyes and prevent the blue/red inks from ink-spreading.By integrating the anti-microorganism effects of the two components,the nanocomposites have exhibited a broad antimicrobial capacity for both fungi(e.g.,Plectosphaerella cucumerina and Aspergillus unguis)and bacteria(e.g.,Staphylococcus aureus).The acquired knowledge not only represents an advanced step for designing functionalized inorganic/polymer nanocomposite but also sheds light on the multi-functional integrated protection of paperbased relics.展开更多
Two-dimensional transition metal carbon/nitrides(MXenes)have emerged as prominent materials in the development of high-performance electromagnetic interference(EMI)shielding films owing to their ex-ceptional electrica...Two-dimensional transition metal carbon/nitrides(MXenes)have emerged as prominent materials in the development of high-performance electromagnetic interference(EMI)shielding films owing to their ex-ceptional electrical conductivity,special layered structure,and chemically active surfaces.Substantial ef-forts have been devoted to addressing the poor mechanical strength and limited functionality of pure MXene films through structural design and interfacial reinforcement.However,there is a notable lack of a systematic review of the research on MXene-based EMI shielding films with multi-layer structures,which could provide a theoretical foundation and technical guidance for the development and application of shielding films.This review aims to summarize the recent advancements in MXene-based layered films for EMI shielding.First,the structure and properties of MXene nanosheets are systematically introduced.Next,the optimization of layered structures and interfacial reinforcement strategies in MXene-based EMI shielding films are objectively reviewed,followed by a discussion of their multifunctional compatibility.Finally,future prospects and challenges for MXene-based layered EMI shielding films are highlighted.展开更多
Cd-based Cs_(7)Cd_(3)Br_(13)perovskites,featuring both tetrahedral and octahedral polyhedral structures,have garnered significant acclaim for their efficient luminescent performance achieved through multi-exciton stat...Cd-based Cs_(7)Cd_(3)Br_(13)perovskites,featuring both tetrahedral and octahedral polyhedral structures,have garnered significant acclaim for their efficient luminescent performance achieved through multi-exciton state regulation by doping.However,it remains controversial whether the doping sites are in the octahedra or tetrahedra of Cs_(7)Cd_(3)Br_(13).To address this,we introduced Pb^(2+)and Sb^(3+)ions and,supported by experimental and theoretical evidence,demonstrated that these ions preferentially occupy the octahedra.Among them,Pb^(2+)ions single doping achieves a near-unity photoluminescence quantum yield of 93.7%,which results in excellent X-ray scintillation performance,high light yield of 41,772 photon MeV^(-1),and a low detection limit of 29.78 nGyairs-1.Moreover,this incorporation of Pb^(2+)and Sb^(3+)enabled an exciton state regulation strategy,resulting in standard white light emission with CIE chromaticity coordinates of(0.33,0.33).Additionally,a multifaceted optical anticounterfeiting and information encryption scheme was designed based on the differences in optical properties caused by the different sensitivities of[PbBr6]4-octahedron and[SbBr6]3-octahedron to temperature and excitation wavelengths.These diverse photoluminescence characteristics provide new insights and practical demonstrations for advanced X-ray imaging,lighting,optical encryption,and anticounterfeiting technologies.展开更多
Dielectric metamaterials based on ceramics have attracted considerable in-terest in the past few years owing to their low dielectric loss,simple structure,excellent multifield tunability,and good environmental adaptab...Dielectric metamaterials based on ceramics have attracted considerable in-terest in the past few years owing to their low dielectric loss,simple structure,excellent multifield tunability,and good environmental adaptability.They are considered to be promising alternative to metal-based metamaterials and can lead to a new strategy for the development of passive devices.In this review,the recent progress of ceramic-based dielectric metamaterials in electro-magnetic applications,energy applications,non-Hermitian systems,and natural materials with near-zero or negative refraction are summarized.The design principle and mechanism,as well as manufacturing technologies,are also introduced,and the current development trend of ceramic-based dielectric metamaterials are proposed.展开更多
基金National Natural Science Foundation of China,Grant/Award Numbers:22205105,62288102,61874053,22075136National Key Basic Research Program of China,Grant/Award Number:2020YFA0709900+1 种基金State Key Laboratory of Luminescent Materials and DevicesResearch Innovation in University of Jiangsu Province,Grant/Award Number:KYCX21_0772。
文摘The emergence offlexible organic crystals changed the perception of molecu-lar crystals that were regarded as brittle entities over a long period of time,and sparked a great interest in exploring mechanically compliant organic crystalline materials toward next-generation smart materials during the past decade.Schiff base compounds are considered to be one of the most promising candidates forflexible organic crystals owing to their easy synthesis,high yield,stimuli respon-siveness and good mechanical properties.This paper gives an overview of the recent development of Schiff baseflexible organic crystals(including elastic organic crystals,plastic organic crystals,andflexible organic crystals integrating elastic-ity and plasticity)from serendipitous discovery to design strategies and versatile applications such as stimuli responses,optical waveguides,optoelectronic devices,biomimetic soft robots,and organic photonic integrated circuits.Notably,atomic force microscopy-micromanipulation technique has been utilized to bring the mul-tifunctional applications offlexible organic crystals from the macroscopic level to the microscopic world.Since understanding mechanicalflexibility at the molec-ular level through crystal engineering can assist us to trace down the structural origin of mechanical properties,we focus on the packing structures of various Schiff baseflexible organic crystals driven by non-covalent intermolecular inter-actions and their close correlation with mechanical behaviors.We hope that the information given here will help in the design of novelflexible organic crys-tals combined with other unique properties,and promote further research into the area of mechanically compliant organic crystalline materials toward multifunctional applications.
基金This work was supported by the National Natural Science Foundation of China(No.21871079)the National Science Foundation(No.1945558).
文摘A novel host-vip luminous system with enhanced near-UV light absorption thereby enhanced luminescence are designed based on the synergism of quantum confinement,spatial confinement,and antenna effect,where ultrasmall Y_(2)O_(3):Eu^(3+)nanocrystals are fixed inside MOF(Eu/Y-BTC)as supporting structure.The Eu/Y-BTC not only limits the size and leads to lattice distortion of Y_(2)O_(3):Eu^(3+)nanocrystals and controls the distance between nanocrystals,but also promotes the light absorption and emission.The significantly red-shifted and broadened charge transfer band of Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)leads to the excellent applications of Y_(2)O_(3):Eu^(3+)in white light-emitting diodes(LEDs).Our results show that white light with superior color quality(CRI>90)and extremely high luminous efficacy(an LER of 335 lm/W)could be achieved using Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)as red phosphor.The Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)also improves the photoelectric performance of dye-sensitized solar cells(DSSCs),not only because Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)has a large specific surface area and the adsorption amount of the dye is increased,but also because the valence band position of Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)is 2.41 eV,which can provide an additional energy level between the TiO2 and dye,promoting electron transfer.For these advantageous features,the multifunctional Y_(2)O_(3):Eu^(3+)/(Eu/Y-BTC)composite product will open new avenues in white LEDs and DSSCs.
基金The financial support by the National Natural Science Foundation of China(No.52002020)is acknowledged.
文摘Stemming from the unique in-plane honeycomb lattice structure and the sp^(2)hybridized carbon atoms bonded by exceptionally strong carbon–carbon bonds,graphene exhibits remarkable anisotropic electrical,mechanical,and thermal properties.To maximize the utilization of graphene’s in-plane properties,pre-constructed and aligned structures,such as oriented aerogels,films,and fibers,have been designed.The unique combination of aligned structure,high surface area,excellent electrical conductivity,mechanical stability,thermal conductivity,and porous nature of highly aligned graphene aerogels allows for tailored and enhanced performance in specific directions,enabling advancements in diverse fields.This review provides a comprehensive overview of recent advances in highly aligned graphene aerogels and their composites.It highlights the fabrication methods of aligned graphene aerogels and the optimization of alignment which can be estimated both qualitatively and quantitatively.The oriented scaffolds endow graphene aerogels and their composites with anisotropic properties,showing enhanced electrical,mechanical,and thermal properties along the alignment at the sacrifice of the perpendicular direction.This review showcases remarkable properties and applications of aligned graphene aerogels and their composites,such as their suitability for electronics,environmental applications,thermal management,and energy storage.Challenges and potential opportunities are proposed to offer new insights into prospects of this material.
文摘A multifunctional apparatus for microwave plasma reaction has been set up, which can be used in the fields such as Chemical synthesis, surface modification, and heterogeneous catalysis. This apparatus has laid an experimental foundation for new methods, new technologies, and new train of thoughts to be explored.
基金This work was supported by the National Natural Science Foundation of China(Nos.21961132024,51925302,and 52173055)the Ministry of Science and Technology of China(No.2021YFE0105100)the Fundamental Research Funds for the Central Universities and the DHU Distinguished Young Professor Program(No.LZA2020001).
文摘One-dimensional(1D)SiO_(2) nanofibers(SNFs),one of the most popular inorganic nanomaterials,have aroused widespread attention because of their excellent chemical stability,as well as unique optical and thermal characteristics.Electrospinning is a straightforward and versatile method to prepare 1D SNFs with programmable structures,manageable dimensions,and modifiable properties,which hold great potential in many cutting-edge applications including aerospace,nanodevice,and energy.In this review,substantial advances in the structural design,controllable synthesis,and multifunctional applications of electrospun SNFs are highlighted.We begin with a brief introduction to the fundamental principles,available raw materials,and typical apparatus of electrospun SNFs.We then discuss the strategies for preparing SNFs with diverse structures in detail,especially stressing the newly emerging three-dimensional SiO_(2) nanofibrous aerogels.We continue with focus on major breakthroughs about brittleness-to-flexibility transition of SNFs and the means to achieve their mechanical reinforcement.In addition,we showcase recent applications enabled by electrospun SNFs,with particular emphasis on physical protection,health care and water treatment.In the end,we summarize this review and provide some perspectives on the future development direction of electrospun SNFs.
基金supported by the National Natural Science Foundation of China(No.52103093,52103205)the Taishan Scholar Project of Shandong Province(No.tsqn202312187)+2 种基金the Natural Science Foundation of Shandong Province(ZR2024QE220)the Young Elite Scientists Sponsorship Program by CAST(No.2021QNRC001)the Jiangxi Provincial Natural Science Foundation(20232BAB214031,20242BAB25237).
文摘The urgent demand for renewable energy solutions,propelled by the global energy crisis and environmental concerns,has spurred the creation of innovative materials for solar thermal storage.Photothermal phase change materials(PTPCMs)represent a novel type of composite phase change material(PCM)aimed at improving thermal storage efficiency by incorporating photothermal materials into traditional PCMs and encapsulating them within porous structures.Various porous encapsulation materials have been studied,including porous carbon,expanded graphite,and ceramics,but issues like brittleness hinder their practical use.To overcome these limitations,flexible PTPCMs using organic porous polymers—like foams,hydrogels,and porous wood—have emerged,offering high porosity and lightweight characteristics.This review examines recent advancements in the preparation of PTPCMs based on porous polymer supports through techniques like impregnation and in situ polymerization,assessing the impact of different porous polymer materials on PCM performance and clarifying the mechanisms of photothermal conversion and heat storage.Subsequently,the most recent advancements in the applications of porous polymer-based PTPCMs are systematically summarized,and future research challenges and possible solutions are discussed.This review aims to foster awareness about the potential of PTPCMs in promoting environmentally friendly energy practices and catalyzing further research in this promising field.
基金support from the National Natural Science Foundation of China(No.52090030)Shanxi-Zheda Institute of New Materials and Chemical Engineering(2022SZ-TD011,2022SZTD012,2022SZ-TD014,and 2021SZ-FR004)the Fundamental Research Funds for the Central Universities(No.2021FZZX001-17).
文摘Nanocomposite fibers are fibrous materials with specific properties and functionalities,which are prepared by introducing nanomaterials or nanostructures in the fibers.Polymeric nanocomposite fibers exhibit multiple functionalities,showing great application potential in healthcare,aerospace,mechanical engineering,and energy storage.Here,six functionalities of polymer nanocomposite fibers are reviewed:mechanical reinforcement,resistance to electromagnetic interference and flame,thermal and electrical conduction,generation of far-infrared ray,negative ion and electricity,energy storage,and sensing.For each functionality,the fiber component selection and preparation methods are summarized.The commonly used polymers comprise natural and synthetic polymers,and typical nanomaterials include carbon-based,polymer-based,metal-based,and metal oxide-based ones.Various compounding strategies and spinning approaches,such as wet-spinning,melt-spinning,and electrospinning,are introduced.Moreover,the functional properties of fibers fabricated from different constituents and by different strategies are compared,providing a reference for performance optimization.Finally,the prospective directions of research and application are discussed,and possible approaches are suggested to facilitate the development of advanced nanocomposite fibers.
基金Scientific and Technological Bases and Talents of Guangxi(Nos.Guike AD23026119,AD21238027)the Guangxi National Science Fundation Project(No.2020GXNSFDA238004)the“Guangxi Bagui Scholars”foundation for financial support。
文摘Rare earth ions(RE^(3+))-doped double perovskites have attracted tremendous attention for its fascinating optical properties.Nevertheless,RE^(3+)generally exhibits poor photoluminescence quantum yield(PLQY)for their parity-forbidden 4f-4f transition and the low doping concentration.Herein,we reported Sb^(3+)/Sm^(3+)-codoped rare earth-based double perovskite Cs_(2)Na Lu Cl_(6)that enables efficient visible and nearinfrared(NIR)emission,which stems from self-trapped exciton(STE)and Sm^(3+),respectively.Benefit from up to 72.89%energy transfer efficiency from STE to Sm^(3+)and high doping concentrations due to similar ionic activity between Sm^(3+)and Lu^(3+),thus eruptive PLQY of 74.58%in the visible light region and 23.12%in the NIR light region can be obtained.Moreover,Sb^(3+)/Sm^(3+)-codoped Cs_(2)Na Lu Cl_(6)exhibits tunable emission characteristic in the visible light region under different excitation wavelengths,which can change from blue emission(254 nm excitation)to white emission(365 nm excitation).More particularly,only the NIR emission can be captured by the NIR camera when a 700 nm cutoff filter is added.The excellent stability and unique optical properties of Sb^(3+)/Sm^(3+)-codoped Cs_(2)Na Lu Cl_(6)enable us to demonstrate its applications in NIR light-emitting diode,triple-mode fluorescence anti-counterfeiting and information encryption.These findings provide new inspiration for the application of rare earth-based double perovskite in optoelectronic devices.
基金supported by the National Natural Science Foundation of China(Project No.51978231)S&T Program of Hebei(Project No.216Z4502G)Fundamental Research Funds of Hebei University of Technology(Project No.JBKYTD2003).
文摘Liquid leakage of PCM and thermophysical performance defects seriously affect the application prospect of PCMs.Aerogels provide an excellent solution for packaging and performance improvement of PCMs with its ultra-high specific surface area and low density and give PCMs other functions besides energy storage,such as energy conversion(photothermal/electrothermal conversion,magnetic thermal/acoustic thermal conversion),thermal management(battery thermal management,electronic thermal management),thermal infrared stealth,building materials,etc.In this paper,firstly,the preparation method and multifunctional response mechanism of aerogelbased PCMs are systematically described,and the improvement of thermophysical and mechanical properties of various aerogel-based PCMs is reviewed from the perspective of aerogel preparation.Then,according to the different application scenarios of aerogel-based PCMs,the advanced functions of aerogel-based PCMs are reviewed,and the multifunctional effects of different materials in aerogel-based PCMs are compared.Finally,some insightful guidance and suggestions for the research and development of aerogel-based PCMs are put forward.
基金financially supported by the National Natural Science Foundation of China(No.52436003)the Science and Technology Program of Guangzhou(No.2024A04J3710).
文摘The traditional inflexible electromagnetic interference(EMI)shielding materials have poor adaptability to wearable and portable flexible electronic devices due to their shortcomings such as brittleness and difficulty in machinability.As an optimized alternative,the conductive polymer composites(CPCs)constructed by integrating MXene and polymer have become one of the most promising EMI shielding materials.To cope with the more harsh application conditions,the processing-structure-property relationship of MXene/polymer EMI shielding composites urgently needs to be clarified.In this review,the EMI shielding mechanism and theory of CPCs are first outlined.Then,the recent advances in processing strategies for MXene/polymer EMI shielding composites with different structures are comprehensively summarized,including layered structure,segregated structure,and porous structure.Next,the multifunctionality of MXene/polymer EMI shielding composites in hydrophobicity,flame retardancy,thermal conductivity,infrared thermal camouflage,electrothermal conversion,photothermal conversion,and sensing function,is systematically introduced.Finally,the prospects and challenges for the future development and application of multifunctional MXene/polymer EMI shielding composites are discussed.This review aims to put forward effective guidance for fabricating intelligent,adaptable,and integrated MXene/polymer EMI shielding composites,thus promoting the upgrading of advanced MXene-based CPCs.
文摘1. Introduction The study of multifunction has been developed extensively with application to mathematics in economics, optimal control, game theory, mathematical programming and decision prooess, etc. Especially, it has been widely used in mathematical economics. Debreu’s work Theory of Value is closely related to the method of multifunction which economists called correspondence. Economic equilibrium theory has long been treated by calculus since Walras. Von Neumann’s work in 1943 on economic theory has been an initiative to form a’new kind of mathematical method to economic theory and reduced the dependence on calculus. The early development of mathematical economics including the 19th century and even up to the World War Ⅱ was largely in terms of calculus; it was doubtless that th(?)
基金supported by the National Natural Science Foundation of China(Grant No.22175040)the Natural Science Foundation of Shanghai(Grant No.21ZR1405100)+1 种基金the Foundation of State Key Laboratory of Biobased Material and Green PapermakingQilu University of Technology,Shandong Academy of Sciences(Grant Nos.GZKF202109,GZKF202210)。
文摘Paper-based relics as important carriers of human history and civilization have been facing severe damage problems,and their protection is a major project for cultural heritage restoration.So far,safe,high-efficiency,and multifunctional protection materials are still urgent to be developed.Herein,through screening a series of alkaline nano-oxides and cleverly combining the advantages of modified natural polymer(quaternized chitosan)and inorganic nanomaterials(Zn O),we successfully prepared their functional nanocomposites with multiple properties and pioneered their smart application for multifunctional protection of paper relics.By spraying loads,this kind of nanocomposites can effectively and safely inhibit the acid degradation of paper relics and long-term maintain a natural or weak basic state even under harsh accelerated aging conditions.Meanwhile,the coating of nanocomposites does not change the chromatic aberration but partially improves the hydrophobicity.Moreover,the mechanical properties of paper relics are reinforced up to more than one time for all-around tensile strength,folding endurance,and tearing strength.It is worth noting that the usage of nanocomposites can avoid the discoloration or fading of p H-sensitive pigments/dyes and prevent the blue/red inks from ink-spreading.By integrating the anti-microorganism effects of the two components,the nanocomposites have exhibited a broad antimicrobial capacity for both fungi(e.g.,Plectosphaerella cucumerina and Aspergillus unguis)and bacteria(e.g.,Staphylococcus aureus).The acquired knowledge not only represents an advanced step for designing functionalized inorganic/polymer nanocomposite but also sheds light on the multi-functional integrated protection of paperbased relics.
基金supported by the Key Research and Development Project of Henan Province of China(No.241111232300)the National Natural Science Foundation of China(Nos.52303113 and 5227308)the Open Project Program of Yaoshan Laboratory(No.2024003).
文摘Two-dimensional transition metal carbon/nitrides(MXenes)have emerged as prominent materials in the development of high-performance electromagnetic interference(EMI)shielding films owing to their ex-ceptional electrical conductivity,special layered structure,and chemically active surfaces.Substantial ef-forts have been devoted to addressing the poor mechanical strength and limited functionality of pure MXene films through structural design and interfacial reinforcement.However,there is a notable lack of a systematic review of the research on MXene-based EMI shielding films with multi-layer structures,which could provide a theoretical foundation and technical guidance for the development and application of shielding films.This review aims to summarize the recent advancements in MXene-based layered films for EMI shielding.First,the structure and properties of MXene nanosheets are systematically introduced.Next,the optimization of layered structures and interfacial reinforcement strategies in MXene-based EMI shielding films are objectively reviewed,followed by a discussion of their multifunctional compatibility.Finally,future prospects and challenges for MXene-based layered EMI shielding films are highlighted.
基金funded by the Jinan Central Hospital Collaboration(1190022050)Foundation for Innovative Research Groups of the National Natural Science Foundation of China(22205233,62374103,62374104,and 62405165)+3 种基金Basic and Applied Basic Research Foundation of Guangdong Province(2024A1515010926)Taishan Scholar Foundation of Shandong Province of Shandong Province(tsqn202312005)Postdoctoral Innovative Projects of Shandong Province(202400321)China Postdoctoral Science Foundation(2024M751789)。
文摘Cd-based Cs_(7)Cd_(3)Br_(13)perovskites,featuring both tetrahedral and octahedral polyhedral structures,have garnered significant acclaim for their efficient luminescent performance achieved through multi-exciton state regulation by doping.However,it remains controversial whether the doping sites are in the octahedra or tetrahedra of Cs_(7)Cd_(3)Br_(13).To address this,we introduced Pb^(2+)and Sb^(3+)ions and,supported by experimental and theoretical evidence,demonstrated that these ions preferentially occupy the octahedra.Among them,Pb^(2+)ions single doping achieves a near-unity photoluminescence quantum yield of 93.7%,which results in excellent X-ray scintillation performance,high light yield of 41,772 photon MeV^(-1),and a low detection limit of 29.78 nGyairs-1.Moreover,this incorporation of Pb^(2+)and Sb^(3+)enabled an exciton state regulation strategy,resulting in standard white light emission with CIE chromaticity coordinates of(0.33,0.33).Additionally,a multifaceted optical anticounterfeiting and information encryption scheme was designed based on the differences in optical properties caused by the different sensitivities of[PbBr6]4-octahedron and[SbBr6]3-octahedron to temperature and excitation wavelengths.These diverse photoluminescence characteristics provide new insights and practical demonstrations for advanced X-ray imaging,lighting,optical encryption,and anticounterfeiting technologies.
基金Basic Science Center Project of NSFC,Grant/Award Number:No.51788104
文摘Dielectric metamaterials based on ceramics have attracted considerable in-terest in the past few years owing to their low dielectric loss,simple structure,excellent multifield tunability,and good environmental adaptability.They are considered to be promising alternative to metal-based metamaterials and can lead to a new strategy for the development of passive devices.In this review,the recent progress of ceramic-based dielectric metamaterials in electro-magnetic applications,energy applications,non-Hermitian systems,and natural materials with near-zero or negative refraction are summarized.The design principle and mechanism,as well as manufacturing technologies,are also introduced,and the current development trend of ceramic-based dielectric metamaterials are proposed.
