Magnesium-lithium hybrid batteries(MLHBs)have gained increasing attention due to their combined advantages of rapid ion insertion/extraction cathode and magnesium metal anode.Herein,Sn S_(2)-SPAN hybrid cathode with s...Magnesium-lithium hybrid batteries(MLHBs)have gained increasing attention due to their combined advantages of rapid ion insertion/extraction cathode and magnesium metal anode.Herein,Sn S_(2)-SPAN hybrid cathode with strong C-Sn bond and rich defects is ingeniously constructed to realize Mg^(2+)/Li^(+)co-intercalation.The physical and chemical double-confinement synergistic engineering of sulfurized polyacrylonitrile can suppress the agglomeration of Sn S_(2)nanoparticles and the volume expansion,simultaneously promote charge transfer and enhance structural stability.The introduced abundant sulfur vacancies provide more active sites for Mg^(2+)/Li^(+)co-intercalation.Meanwhile,the beneficial effects of rich sulfur defects and C-Sn bond on enhanced electrochemical properties are further evidenced by density-functional theory(DFT)calculations.Therefore,compared with pristine SnS_(2),SnS_(2)-SPAN cathode displays high specific capacity(218 m Ah g^(-1)at 0.5A g^(-1)over 700 cycles)and ultra-long cycling life(101 m Ah g^(-1)at 5 A g^(-1)up to 28,000 cycles).And a high energy density of 307 Wh kg^(-1)can be realized by the Sn S_(2)-SPAN//Mg pouch cell.Such elaborate and simple design supplies a reference for the exploitation of advanced cathode materials with excellent electrochemical properties for MLHBs.展开更多
Magnesium(Mg)is the fourth most abundant element in the human body and is important in terms of specific osteogenesis functions.Here,we provide a comprehensive review of the use of magnesium-based biomaterials(MBs)in ...Magnesium(Mg)is the fourth most abundant element in the human body and is important in terms of specific osteogenesis functions.Here,we provide a comprehensive review of the use of magnesium-based biomaterials(MBs)in bone reconstruction.We review the history of MBs and their excellent biocompatibility,biodegradability and osteopromotive properties,highlighting them as candidates for a new generation of biodegradable orthopedic implants.In particular,the results reported in the field-specific literature(280 articles)in recent decades are dissected with respect to the extensive variety of MBs for orthopedic applications,including Mg/Mg alloys,bioglasses,bioceramics,and polymer materials.We also summarize the osteogenic mechanism of MBs,including a detailed section on the physiological process,namely,the enhanced osteogenesis,promotion of osteoblast adhesion and motility,immunomodulation,and enhanced angiogenesis.Moreover,the merits and limitations of current bone grafts and substitutes are compared.The objective of this review is to reveal the strong potential of MBs for their use as agents in bone repair and regeneration and to highlight issues that impede their clinical translation.Finally,the development and challenges of MBs for transplanted orthopedic materials are discussed.展开更多
The addition of nanoscale additions to magnesium(Mg)based alloys can boost mechanical characteristics without noticeably decreasing ductility.Since Mg is the lightest structural material,the Mg-based nanocomposites(NC...The addition of nanoscale additions to magnesium(Mg)based alloys can boost mechanical characteristics without noticeably decreasing ductility.Since Mg is the lightest structural material,the Mg-based nanocomposites(NCs)with improved mechanical properties are appealing materials for lightweight structural applications.In contrast to conventional Mg-based composites,the incorporation of nano-sized reinforcing particles noticeably boosts the strength of Mg-based nanocomposites without significantly reducing the formability.The present article reviews Mg-based metal matrix nanocomposites(MMNCs)with metallic and ceramic additions,fabricated via both solid-based(sintering and powder metallurgy)and liquid-based(disintegrated melt deposition)technologies.It also reviews strengthening models and mechanisms that have been proposed to explain the improved mechanical characteristics of Mg-based alloys and nanocomposites.Further,synergistic strengthening mecha-nisms in Mg matrix nanocomposites and the dominant equations for quantitatively predicting mechanical properties are provided.Furthermore,this study offers an overview of the creep and fatigue behavior of Mg-based alloys and nanocomposites using both traditional(uniaxial)and depth-sensing indentation techniques.The potential applications of magnesium-based alloys and nanocomposites are also surveyed.展开更多
Biodegradable metals such as magnesium(Mg)and its alloys have attracted extensive attention in biomedical research due to their excellent mechanical properties and biodegradability.However,traditional casting,extrusio...Biodegradable metals such as magnesium(Mg)and its alloys have attracted extensive attention in biomedical research due to their excellent mechanical properties and biodegradability.However,traditional casting,extrusion,and commercial processing have limitations in manufacturing components with a complex shape/structure,and these processes may produce defects such as cavities and gas pores which can degrade the properties and usefulness of the products.Compared to conventional techniques,additive manufacturing(AM)can be used to precisely control the geometry of workpieces made of different Mg-based materials with multiple geometric scales and produce desirable medical products for orthopedics,dentistry,and other fields.However,a detailed and thorough understanding of the raw materials,manufacturing processes,properties,and applications is required to foster the production of commercial Mg-based biomedical components by AM.This review summarizes recent advances and important issues pertaining to AM of Mg-based biomedical products and discusses future development and application trends.展开更多
Magnesium-based biomaterials(MBMs)are one of the most promising materials for tissue engineering due to their unique mechanical properties and excellent functional properties.This review describes the development,adva...Magnesium-based biomaterials(MBMs)are one of the most promising materials for tissue engineering due to their unique mechanical properties and excellent functional properties.This review describes the development,advantages,and challenges of MBMs for biomedical applications,especially for tissue repair and regeneration.The history of the use of MBMs from the beginning of the 20th century is traced,and the transformative advances in contemporary applications of MBMs in areas such as orthopedics and cardiovascular surgery are emphasized.The review also provides insight into the signaling pathways affected by MBMs,such as the PI3K/Akt and RANKL/RANK/OPG pathways,which are critical for osteogenesis and angiogenesis.The review advocates that future research should focus on optimizing alloy compositions,surface modification and exploring innovative technologies such as 3D printing to improve the efficacy of MBMs in complex tissue repair.The potential of MBMs to tissue engineering and regenerative medicine is significant,urging further exploration and interdisciplinary collaboration to maximize their therapeutic effects.展开更多
We investigate experimentally and analytically the combustion behavior of a high-metal magnesium-based hydro- reactive fuel under high temperature gaseous atmosphere. The fuel studied in this paper contains 73% magnes...We investigate experimentally and analytically the combustion behavior of a high-metal magnesium-based hydro- reactive fuel under high temperature gaseous atmosphere. The fuel studied in this paper contains 73% magnesium powders. An experimental system is designed and experiments are carried out in both argon and water vapor atmo- spheres. It is found that the burning surface temperature of the fuel is higher in water vapor than that in argon and both of them are higher than the melting point of magnesium, which indicates the molten state of magnesium particles in the burning surface of the fuel. Based on physical considerations and experimental results, a mathematical one-dimensional model is formulated to describe the combustion behavior of the high-metal magnesium-based hydro-reactive fuel. The model enables the evaluation of the burning surface temperature, the burning rate and the flame standoff distance each as a function of chamber pressure and water vapor concentration. The results predicted by the model show that the burning rate and the surface temperature increase when the chamber pressure and the water vapor concentration increase, which are in agreement with the observed experimental trends.展开更多
This study explores the potential of Mg/Carbon Nanotubes/Baghdadite composites as biomaterials for bone regeneration and repair while addressing the obstacles to their clinical application.BAG powder was synthesized u...This study explores the potential of Mg/Carbon Nanotubes/Baghdadite composites as biomaterials for bone regeneration and repair while addressing the obstacles to their clinical application.BAG powder was synthesized using the sol-gel method to ensure a fine distribution within the Mg/CNTs matrix.Mg/1.5 wt.%CNT composites were reinforced with BAG at weight fractions of 0.5,1.0,and 1.5 wt.%using spark plasma sintering at 450℃and 50 MPa after homogenization via ball milling.The cellular bioactivity of these nanocomposites was evaluated using human osteoblast-like cells and adipose-derived mesenchymal stromal cells.The proliferation and attachment of MG-63cells were assessed and visualized using the methylthiazol tetrazolium(MTT)assay and SEM,while AD-MSC differentiation was measured using alkaline phosphatase activity assays.Histograms were also generated to visualize the diameter distributions of particles in SEM images using image processing techniques.The Mg/CNTs/0.5 wt.%BAG composite demonstrated optimal mechanical properties,with compressive strength,yield strength,and fracture strain of 259.75 MPa,180.25 MPa,and 31.65%,respectively.Machine learning models,including CNN,LSTM,and GRU,were employed to predict stress-strain relationships across varying BAG amounts,aiming to accurately model these curves without requiring extensive physical experiments.As shown by contact angle measurements,enhanced hydrophilicity promoted better cell adhesion and proliferation.Furthermore,corrosion resistance improved with a higher BAG content.This study concludes that Mg/CNTs composites reinforced with BAG concentrations below 1.0 wt.%offer promising biodegradable implant materials for orthopedic applications,featuring adequate load-bearing capacity and improved corrosion resistance.展开更多
Mg-based materials have potential applications in the field of orthopedics owing to their good biodegradability,biocompatibility,and boneinducing properties.However,during the early application process,their major dra...Mg-based materials have potential applications in the field of orthopedics owing to their good biodegradability,biocompatibility,and boneinducing properties.However,during the early application process,their major drawback was rapid degradation rate,which limited their clinical application.Nanoparticles can effectively reinforce the mechanical strength and corrosion resistance of Mg matrices,and different nanoparticles can be selected to achieve different biological functions.Therefore,Mg-based nanocomposites have emerged as a versatile class of degradable implant materials with broad clinical potential.This review summarizes the research progress of Mg-based orthopedic implants,mainly including the reinforcement mechanism of nanoparticles on Mg-based materials,the effects and biological functions of different nanoparticle enhancers,surface modification,and the application of new manufacturing technologies.Furthermore,the degradation process of Mg-based materials and the biological functions of magnesium ion(Mg^(2+))during the degradation process are discussed in detail We focused on the biological mechanisms through which Mg^(2+)promotes bone and vascular formation and inhibits osteoclasts by regulating the immune microenvironment or multiple signaling pathways.Finally,the clinical application of Mg-based orthopedic implants are introduced and the future research directions of Mg-based nanocomposites are discussed.展开更多
Magnesium(Mg)and its alloys are revolutionizing the field of interventional surgeries in the medical industry.Their high biocompatibility,biodegradability,and a similar elastic modulus to natural bone make porous Mg-b...Magnesium(Mg)and its alloys are revolutionizing the field of interventional surgeries in the medical industry.Their high biocompatibility,biodegradability,and a similar elastic modulus to natural bone make porous Mg-based structures potential candidates for orthopedic implants and tissue engineering scaffolding.However,fabricating and machining porous Mg-based structures is challenging due to their complexity and difficulties in achieving uniform or gradient porosity.This review aims to thoroughly explore various fabrication procedures used to create metallic scaffolds,with a specific focus on those made from Mg-based alloys.Both traditional manufacturing techniques,including the directional solidification of metal-gas eutectic technique,pattern casting,methods using space holders,and modern fabrication methods,which are based on additive manufacturing,are covered in this review article.Furthermore,the paper highlights the most important findings of recent studies on Mg-based scaffolds in terms of their microstructure specifications,mechanical properties,degradation and corrosion behavior,antibacterial activity,and biocompatibility(both in vivo and in vitro).While extensive research has been conducted to optimize manufacturing parameters and qualities of Mg-based scaffolds for use in biomedical applications,specifically for bone tissue engineering applications,further investigation is needed to fabricate these scaffolds with specific properties,such as high resistance to corrosion,good antibacterial properties,osteoconductivity,osteoinductivity,and the ability to elicit a favorable response from osteoblast-like cell lines.The review concludes with recommendations for future research in the field of medical applications.展开更多
Biodegradable metals have been increasingly utilized clinically due to their biosafety and pro-osteogenic prop-erties.However,conventional monolayer cell-based preclinical safety evaluation methods based on ISO10993-5...Biodegradable metals have been increasingly utilized clinically due to their biosafety and pro-osteogenic prop-erties.However,conventional monolayer cell-based preclinical safety evaluation methods based on ISO10993-5 consistently indicate significant cytotoxicity that contradicts in vivo outcomes.In this study,we aimed to establish an in vitro evaluation model that better correlates with in vivo performance.Three-layer BMSC cell sheets were constructed using layer-by-layer assembly.Histological analyses revealed a stable three-dimensional structure with elevated cell-cell interaction proteins,including N-Cadherin,Fibronectin,and Vinculin,along with enhanced osteogenic potential.The cytotoxicity of 4N pure Mg was evaluated in both cell sheet and monolayer co-culture models.Flow cytometry showed higher Ki67 expression and lower ROS levels and apoptosis rate in cell sheets.ShRNA-mediated silencing of N-Cadherin in cell sheets significantly compromised their cytopro-tective capacity against Mg metal-induced toxicity.Osteogenesis-related gene expression correlation analysis between in vitro co-culture models and in vivo femur implantation models was conducted using RNA-seq and qRT-PCR.Results showed that 4N pure Mg enhanced osteogenic genes(BMP2R,RUNX2,and SP7)in cell sheets,consistent with in vivo patterns but contrary to monolayer models.Various Mg-based metals(4N/5N Pure Mg,ZE21B,and WE43)were evaluated in cell sheet defect,monolayer defect,and cranial defect models.5N Pure Mg,ZE21B,and WE43 promoted defect healing in both cranial defect and cell sheets,but showed no positive effect in monolayers.Collectively,cell sheet models correlated well with in vivo results,suggesting their potential as alternative in vitro evaluation models,thereby accelerating clinical translation of Mg-based biomaterials.展开更多
Biodegradable metals have garnered considerable interest owing to their capacity for self-degradation following the repair of damaged tissues.This review commences with their historical development and clarifies the e...Biodegradable metals have garnered considerable interest owing to their capacity for self-degradation following the repair of damaged tissues.This review commences with their historical development and clarifies the essential prerequisites for their successful clinical translation.Subsequently,a detailed review of magnesium-based materials is presented from five critical areas of alloying,fabrication techniques,purification,surface modification,and structural design,systematically addressing their progress in biodegradation rate retardation,mechanical reinforcement,and biocompatibility enhancement.Furthermore,recent breakthroughs in vivo animal experiments and clinical translation of magnesium alloys are summarized.Finally,this review concludes with a critical assessment of the achievements and challenges encountered in the clinical application of these materials,and proposes practical strategies to address current limitations and guide future research perspectives.展开更多
The rapid corrosion rate and limited biological functionality still pose challenges for magnesium(Mg)-based implants in the treatment of complicated bone-related diseases in clinic.Herein,a multifunctional biodegradab...The rapid corrosion rate and limited biological functionality still pose challenges for magnesium(Mg)-based implants in the treatment of complicated bone-related diseases in clinic.Herein,a multifunctional biodegradable curcumin(herbal medicine)-ferrum(Cur-Fe)nanoflower was self-assembled on plasma electrolytic oxidation(PEO)-treated Mg alloy via a facile immersion process to realize differential biological function for anti-bacteria/tumor and bone regeneration.The results indicated that Cur-Fe nanoflower coating can promote protein adsorption,cell adhesion and proliferation,exhibiting excellent biocompatibility.The Cur-Fe nanoflower coating exhibits unique degradation characteristics,as curcumin gradually decomposes into ferulic acid,aromatic aldehyde and other antibacterial substances,and the coating spontaneously converts into FeOOH nanosheets,ensuring the corrosion resistance of Mg-based implants.Moreover,Cur-Fe coating exhibits remarkable narrow gap semiconductor characteristics,which can generate reactive oxygen species(ROS)and demonstrated excellent antibacterial effect under simulated sunlight(SSL)irradiation.Meanwhile,under NIR irradiation,Cur-Fe coating showed excellent chemotherapy/photodynamic/photothermal synergetic antitumor properties in vitro and in vivo due to the introduction of curcumin,and photocatalysis and photothermal conversion properties of coating.Furthermore,Cur-Fe nanoflower coating demonstrated great osteogenesis activity in vitro and in vivo due to unique micro/nano structure,surface chemical bond,and the release of Mg and Fe ions.展开更多
Osteoporotic fractures often exhibit delayed healing and repair difficulties in which the bone immune microenvironment may play a critical role,but direct evidence remains elusive.Recently,magnesium(Mg)-based alloys h...Osteoporotic fractures often exhibit delayed healing and repair difficulties in which the bone immune microenvironment may play a critical role,but direct evidence remains elusive.Recently,magnesium(Mg)-based alloys have emerged as promising biodegradable materials capable of promoting fracture healing.Herein,we performed internal fixation of high-purity Mg implants for osteoporotic fractures and used single-cell studies to investigate and elucidate the cellular heterogeneity and dynamic changes that occurred during osteoporotic fracture repair.We observed an early increase in immature neutrophil numbers,together with anti-inflammatory changes in lymphocytes and macrophages.A cluster of macrophages exhibited pro-angiogenic capabilities activated via the TRPM7/S100A4 pathway.These findings provide new theoretical insights into the biological effects of Mg-based materials on the healing of osteoporotic fractures.展开更多
Magnesium-based hydrogen storage materials are promising candidates for hydrogen storage due to their high storage density and environmentally friendly properties.However,the high dehydrogenation enthalpy change(appro...Magnesium-based hydrogen storage materials are promising candidates for hydrogen storage due to their high storage density and environmentally friendly properties.However,the high dehydrogenation enthalpy change(approximately 75 kJ/mol H_(2))and high dehydrogenation temperature(573 K at 0.1 MPa)of MgH_(2),limits the engineering application of Mg/MgH_(2) as a hydrogen storage material.This work reviews the prediction models and methods of enthalpy changes for hydriding/dehydriding(H/D)reactions in order to find out the ideas and ways to reduce them.The mechanism behind the improvement methods mainly includes two aspects,weakening Mg-H bond and compensating heat of reaction.Proceed from this,the experimental methods and enthalpy data as well as calculated values of enthalpy changes were compared systematically.Elements such as Ti,Nb,V,etc.,with a small electronegativity difference compared to Mg,can reduce the hydrogenation and dehydrogenation enthalpy changes by forming strong Metal-H or Metal-Mg bonds.In addition,this review concludes with an outlook on the remaining challenge issues and prospects.展开更多
Over the last decade’s magnesium and magnesium based compounds have been intensively investigated as potential hydrogen storage as well as thermal energy storage materials due to their abundance and availability as w...Over the last decade’s magnesium and magnesium based compounds have been intensively investigated as potential hydrogen storage as well as thermal energy storage materials due to their abundance and availability as well as their extraordinary high gravimetric and volumetric storage densities.This review work provides a broad overview of the most appealing systems and of their hydrogenation/dehydrogenation properties.Special emphasis is placed on reviewing the efforts made by the scientific community in improving the material’s thermodynamic and kinetic properties while maintaining a high hydrogen storage capacity.展开更多
Mg-based materials are one of the most promising hydrogen storage candidates due to their high hydrogen storage capacity,environmental benignity,and high Clarke number characteristics.However,the limited thermodynamic...Mg-based materials are one of the most promising hydrogen storage candidates due to their high hydrogen storage capacity,environmental benignity,and high Clarke number characteristics.However,the limited thermodynamics and kinetic properties pose major challenges for their engineering applications.Herein,we review the recent progress in improving their thermodynamics and kinetics,with an emphasis on the models and the influence of various parameters in the calculated models.Subsequently,the impact of alloying,composite,and nanocrystallization on both thermodynamics and dynamics are discussed in detail.In particular,the correlation between various modification strategies and the hydrogen capacity,dehydrogenation enthalpy and temperature,hydriding/dehydriding rates are summarized.In addition,the mechanism of hydrogen storage processes of Mg-based materials is discussed from the aspect of classical kinetic theories and microscope hydrogen transferring behavior.This review concludes with an outlook on the remaining challenge issues and prospects.展开更多
Magnesium and magnesium-based alloy hydrides remain attractive hydrogen storage materials owing to high hydrogen capacity and rich reserves in the earth's crust. A high stability of hydride and sluggish hydriding/deh...Magnesium and magnesium-based alloy hydrides remain attractive hydrogen storage materials owing to high hydrogen capacity and rich reserves in the earth's crust. A high stability of hydride and sluggish hydriding/dehydriding kinetics at practical temperatures for the materials drove researchers into alloying with other elements, using different preparation techniques, using catalyst and thin film hydride to improve the hydrogen absorption/desorption properties. In this review, the development of these approaches and their effects on the thermodynamic and kinetics properties of magnesium and magnesium-based alloy hydrides were descript in details.展开更多
Magnesium and its alloys are the most investigated materials for solid-state hydrogen storage in the form of metal hydrides,but there are still unresolved problems with the kinetics and thermodynamics of hydrogenation...Magnesium and its alloys are the most investigated materials for solid-state hydrogen storage in the form of metal hydrides,but there are still unresolved problems with the kinetics and thermodynamics of hydrogenation and dehydrogenation of this group of materials.Severe plastic deformation(SPD)methods,such as equal-channel angular pressing(ECAP),high-pressure torsion(HPT),intensive rolling,and fast forging,have been widely used to enhance the activation,air resistance,and hydrogenation/dehydrogenation kinetics of Mg-based hydrogen storage materials by introducing ultrafine/nanoscale grains and crystal lattice defects.These severely deformed materials,particularly in the presence of alloying additives or second-phase nanoparticles,can show not only fast hydrogen absorption/desorption kinetics but also good cycling stability.It was shown that some materials that are apparently inert to hydrogen can absorb hydrogen after SPD processing.Moreover,the SPD methods were effectively used for hydrogen binding-energy engineering and synthesizing new magnesium alloys with low thermodynamic stability for reversible low/room-temperature hydrogen storage,such as nanoglasses,high-entropy alloys,and metastable phases including the high-pressureγ-MgH2 polymorph.This work reviews recent advances in the development of Mg-based hydrogen storage materials by SPD processing and discusses their potential in future applications.展开更多
Magnesium-based biomaterials have recently gained great attention as promising candidates for the new generation of biodegradable implants.This study investigated the mechanical performance and biodegradation behaviou...Magnesium-based biomaterials have recently gained great attention as promising candidates for the new generation of biodegradable implants.This study investigated the mechanical performance and biodegradation behaviour of magnesium-zinc/hydroxyapatite(Mg-Zn/HA)composites fabricated by different powder mixing techniques.A single step mixing process involved mechanical alloying or mechanical milling techniques,while double step processing involved a combination of both mechanical alloying and mechanical milling.Optimum mechanical properties of the composite were observed when the powders were prepared using single step processing via mechanical alloying technique.However,Mg-Zn/HA composite fabricated through single step processing via mechanical milling technique was found to have the most desirable low degradation rate coupled with highest bioactivity.The composite achieved the lowest degradation rate of 0.039×10^−3 mm/year as measured by immersion test and 0.0230 mm/year as measured by electrochemical polarization.Ca:P ratio of the composite also slightly more than enough to aid the initial bone mineralization,that is 1:1.76,as the required Ca:P ratio for initial bone mineralization is between 1:1 and 1:1.67.展开更多
Hydrogen is an ideal clean energy because of its high calorific value and abundance of sources.However,storing hydrogen in a compact,inexpensive,and safe manner is the main restriction on the extensive utilization of ...Hydrogen is an ideal clean energy because of its high calorific value and abundance of sources.However,storing hydrogen in a compact,inexpensive,and safe manner is the main restriction on the extensive utilization of hydrogen energy.Magnesium(Mg)-based hydrogen storage material is considered a reliable solid hydrogen storage material with the advantages of high hydrogen storage capacity(7.6wt%),good performance,and low cost.However,the high thermodynamic stability and slow kinetics of Mg-based hydrogen storage materials have to be overcome.In this paper,we will review the recent advances in the nanoconfinement of Mg-related hydrogen storage materials by loading Mg particles on different supporting materials,including carbons,metal-organic frameworks,and other materials.Perspectives are also provided for designing high-performance Mg-based materials using nanoconfinement.展开更多
基金financially supported by the National Key R&D Program of China(No.2023YFB3809500)National Natural Science Foundation of China(Grant No.51931006,52272240 and U22A20118)+2 种基金the Fundamental Research Funds for the Central Universities of China(Xiamen University:No.20720220074)Science and Technology Projects of Innovation Laboratory for Sciences and Technologies of Energy Materials of Fujian Province(HRTP-[2022]-22)the“Double-First Class”Foundation of Materials Intelligent Manufacturing Discipline of Xiamen University。
文摘Magnesium-lithium hybrid batteries(MLHBs)have gained increasing attention due to their combined advantages of rapid ion insertion/extraction cathode and magnesium metal anode.Herein,Sn S_(2)-SPAN hybrid cathode with strong C-Sn bond and rich defects is ingeniously constructed to realize Mg^(2+)/Li^(+)co-intercalation.The physical and chemical double-confinement synergistic engineering of sulfurized polyacrylonitrile can suppress the agglomeration of Sn S_(2)nanoparticles and the volume expansion,simultaneously promote charge transfer and enhance structural stability.The introduced abundant sulfur vacancies provide more active sites for Mg^(2+)/Li^(+)co-intercalation.Meanwhile,the beneficial effects of rich sulfur defects and C-Sn bond on enhanced electrochemical properties are further evidenced by density-functional theory(DFT)calculations.Therefore,compared with pristine SnS_(2),SnS_(2)-SPAN cathode displays high specific capacity(218 m Ah g^(-1)at 0.5A g^(-1)over 700 cycles)and ultra-long cycling life(101 m Ah g^(-1)at 5 A g^(-1)up to 28,000 cycles).And a high energy density of 307 Wh kg^(-1)can be realized by the Sn S_(2)-SPAN//Mg pouch cell.Such elaborate and simple design supplies a reference for the exploitation of advanced cathode materials with excellent electrochemical properties for MLHBs.
基金financial support from the National Natural Science Foundation of China(No.81672230)the Natural Science Foundation of Chongqing(No.cstc2020jcyjmsxm2234)+1 种基金the Top-notch Young Talent Project of Chongqing Traditional Chinese Medicine Hospital(No.CQSZYY2020008)the Chongqing Graduate Research Innovation Project(No.CYS20199)。
文摘Magnesium(Mg)is the fourth most abundant element in the human body and is important in terms of specific osteogenesis functions.Here,we provide a comprehensive review of the use of magnesium-based biomaterials(MBs)in bone reconstruction.We review the history of MBs and their excellent biocompatibility,biodegradability and osteopromotive properties,highlighting them as candidates for a new generation of biodegradable orthopedic implants.In particular,the results reported in the field-specific literature(280 articles)in recent decades are dissected with respect to the extensive variety of MBs for orthopedic applications,including Mg/Mg alloys,bioglasses,bioceramics,and polymer materials.We also summarize the osteogenic mechanism of MBs,including a detailed section on the physiological process,namely,the enhanced osteogenesis,promotion of osteoblast adhesion and motility,immunomodulation,and enhanced angiogenesis.Moreover,the merits and limitations of current bone grafts and substitutes are compared.The objective of this review is to reveal the strong potential of MBs for their use as agents in bone repair and regeneration and to highlight issues that impede their clinical translation.Finally,the development and challenges of MBs for transplanted orthopedic materials are discussed.
基金H.R.Bakhsheshi-Rad and S.Sharif would like to acknowledge UTM Research Management for the financial support through the funding(Q.J130000.2409.08G37).
文摘The addition of nanoscale additions to magnesium(Mg)based alloys can boost mechanical characteristics without noticeably decreasing ductility.Since Mg is the lightest structural material,the Mg-based nanocomposites(NCs)with improved mechanical properties are appealing materials for lightweight structural applications.In contrast to conventional Mg-based composites,the incorporation of nano-sized reinforcing particles noticeably boosts the strength of Mg-based nanocomposites without significantly reducing the formability.The present article reviews Mg-based metal matrix nanocomposites(MMNCs)with metallic and ceramic additions,fabricated via both solid-based(sintering and powder metallurgy)and liquid-based(disintegrated melt deposition)technologies.It also reviews strengthening models and mechanisms that have been proposed to explain the improved mechanical characteristics of Mg-based alloys and nanocomposites.Further,synergistic strengthening mecha-nisms in Mg matrix nanocomposites and the dominant equations for quantitatively predicting mechanical properties are provided.Furthermore,this study offers an overview of the creep and fatigue behavior of Mg-based alloys and nanocomposites using both traditional(uniaxial)and depth-sensing indentation techniques.The potential applications of magnesium-based alloys and nanocomposites are also surveyed.
基金This work was financially supported by the Guangdong Basic and Applied Basic Research Foundation(No.2020B1515120078,2021A1515111140,and 2021B1515120059)National Key Research and Development Project of China(No.2020YFC1107202)+3 种基金Science Research Cultivation Program(PY2022002)Science and Technology Planning Project of Guangzhou(No.202206010030)City University of Hong Kong Donation Research Grants[DONRMG No.9229021 and 9220061]as well as City University of Hong Kong Strategic Research Grant[SRG 7005505].
文摘Biodegradable metals such as magnesium(Mg)and its alloys have attracted extensive attention in biomedical research due to their excellent mechanical properties and biodegradability.However,traditional casting,extrusion,and commercial processing have limitations in manufacturing components with a complex shape/structure,and these processes may produce defects such as cavities and gas pores which can degrade the properties and usefulness of the products.Compared to conventional techniques,additive manufacturing(AM)can be used to precisely control the geometry of workpieces made of different Mg-based materials with multiple geometric scales and produce desirable medical products for orthopedics,dentistry,and other fields.However,a detailed and thorough understanding of the raw materials,manufacturing processes,properties,and applications is required to foster the production of commercial Mg-based biomedical components by AM.This review summarizes recent advances and important issues pertaining to AM of Mg-based biomedical products and discusses future development and application trends.
基金supported by the National Natural Science Foundation of China(Grant No.82202672)the Key Research and Development Program of Anhui Province(No.2022e07020017)+5 种基金China Postdoctoral Science Foundation Grant(2022M723049)the National Postdoctoral Program for Innovative Talents(BX20230350)Research Funds of Centre for Leading Medicine and Advanced Technologies of IHM(No.2023IHM02007)the Foundation of National Center for Translational Medicine(Shanghai)SHU Branch(No.SUITM-202301)Anhui Provincial Research Preparation Plan(2022AH040074),Natural science fund for colleges and universities in Anhui Proxince(2023AH053289)Research Fund of Anhui Institute of translational medicine(2022zhyx-C32).
文摘Magnesium-based biomaterials(MBMs)are one of the most promising materials for tissue engineering due to their unique mechanical properties and excellent functional properties.This review describes the development,advantages,and challenges of MBMs for biomedical applications,especially for tissue repair and regeneration.The history of the use of MBMs from the beginning of the 20th century is traced,and the transformative advances in contemporary applications of MBMs in areas such as orthopedics and cardiovascular surgery are emphasized.The review also provides insight into the signaling pathways affected by MBMs,such as the PI3K/Akt and RANKL/RANK/OPG pathways,which are critical for osteogenesis and angiogenesis.The review advocates that future research should focus on optimizing alloy compositions,surface modification and exploring innovative technologies such as 3D printing to improve the efficacy of MBMs in complex tissue repair.The potential of MBMs to tissue engineering and regenerative medicine is significant,urging further exploration and interdisciplinary collaboration to maximize their therapeutic effects.
基金Project supported by the Young Scientist Fund of the National Natural Science Foundation of China(Grant No.51006118)
文摘We investigate experimentally and analytically the combustion behavior of a high-metal magnesium-based hydro- reactive fuel under high temperature gaseous atmosphere. The fuel studied in this paper contains 73% magnesium powders. An experimental system is designed and experiments are carried out in both argon and water vapor atmo- spheres. It is found that the burning surface temperature of the fuel is higher in water vapor than that in argon and both of them are higher than the melting point of magnesium, which indicates the molten state of magnesium particles in the burning surface of the fuel. Based on physical considerations and experimental results, a mathematical one-dimensional model is formulated to describe the combustion behavior of the high-metal magnesium-based hydro-reactive fuel. The model enables the evaluation of the burning surface temperature, the burning rate and the flame standoff distance each as a function of chamber pressure and water vapor concentration. The results predicted by the model show that the burning rate and the surface temperature increase when the chamber pressure and the water vapor concentration increase, which are in agreement with the observed experimental trends.
文摘This study explores the potential of Mg/Carbon Nanotubes/Baghdadite composites as biomaterials for bone regeneration and repair while addressing the obstacles to their clinical application.BAG powder was synthesized using the sol-gel method to ensure a fine distribution within the Mg/CNTs matrix.Mg/1.5 wt.%CNT composites were reinforced with BAG at weight fractions of 0.5,1.0,and 1.5 wt.%using spark plasma sintering at 450℃and 50 MPa after homogenization via ball milling.The cellular bioactivity of these nanocomposites was evaluated using human osteoblast-like cells and adipose-derived mesenchymal stromal cells.The proliferation and attachment of MG-63cells were assessed and visualized using the methylthiazol tetrazolium(MTT)assay and SEM,while AD-MSC differentiation was measured using alkaline phosphatase activity assays.Histograms were also generated to visualize the diameter distributions of particles in SEM images using image processing techniques.The Mg/CNTs/0.5 wt.%BAG composite demonstrated optimal mechanical properties,with compressive strength,yield strength,and fracture strain of 259.75 MPa,180.25 MPa,and 31.65%,respectively.Machine learning models,including CNN,LSTM,and GRU,were employed to predict stress-strain relationships across varying BAG amounts,aiming to accurately model these curves without requiring extensive physical experiments.As shown by contact angle measurements,enhanced hydrophilicity promoted better cell adhesion and proliferation.Furthermore,corrosion resistance improved with a higher BAG content.This study concludes that Mg/CNTs composites reinforced with BAG concentrations below 1.0 wt.%offer promising biodegradable implant materials for orthopedic applications,featuring adequate load-bearing capacity and improved corrosion resistance.
基金Scientific Development Program of Jilin Province(20220204103YY)。
文摘Mg-based materials have potential applications in the field of orthopedics owing to their good biodegradability,biocompatibility,and boneinducing properties.However,during the early application process,their major drawback was rapid degradation rate,which limited their clinical application.Nanoparticles can effectively reinforce the mechanical strength and corrosion resistance of Mg matrices,and different nanoparticles can be selected to achieve different biological functions.Therefore,Mg-based nanocomposites have emerged as a versatile class of degradable implant materials with broad clinical potential.This review summarizes the research progress of Mg-based orthopedic implants,mainly including the reinforcement mechanism of nanoparticles on Mg-based materials,the effects and biological functions of different nanoparticle enhancers,surface modification,and the application of new manufacturing technologies.Furthermore,the degradation process of Mg-based materials and the biological functions of magnesium ion(Mg^(2+))during the degradation process are discussed in detail We focused on the biological mechanisms through which Mg^(2+)promotes bone and vascular formation and inhibits osteoclasts by regulating the immune microenvironment or multiple signaling pathways.Finally,the clinical application of Mg-based orthopedic implants are introduced and the future research directions of Mg-based nanocomposites are discussed.
基金U.S.National Institute of Health-National Heart,Lung,and Blood Institute Grants R56HL163552 and R01HL168696 are acknowledged by J W D for funding work on biodegradable metals.
文摘Magnesium(Mg)and its alloys are revolutionizing the field of interventional surgeries in the medical industry.Their high biocompatibility,biodegradability,and a similar elastic modulus to natural bone make porous Mg-based structures potential candidates for orthopedic implants and tissue engineering scaffolding.However,fabricating and machining porous Mg-based structures is challenging due to their complexity and difficulties in achieving uniform or gradient porosity.This review aims to thoroughly explore various fabrication procedures used to create metallic scaffolds,with a specific focus on those made from Mg-based alloys.Both traditional manufacturing techniques,including the directional solidification of metal-gas eutectic technique,pattern casting,methods using space holders,and modern fabrication methods,which are based on additive manufacturing,are covered in this review article.Furthermore,the paper highlights the most important findings of recent studies on Mg-based scaffolds in terms of their microstructure specifications,mechanical properties,degradation and corrosion behavior,antibacterial activity,and biocompatibility(both in vivo and in vitro).While extensive research has been conducted to optimize manufacturing parameters and qualities of Mg-based scaffolds for use in biomedical applications,specifically for bone tissue engineering applications,further investigation is needed to fabricate these scaffolds with specific properties,such as high resistance to corrosion,good antibacterial properties,osteoconductivity,osteoinductivity,and the ability to elicit a favorable response from osteoblast-like cell lines.The review concludes with recommendations for future research in the field of medical applications.
基金financially funded by National Key Research and Development Program of China(2021YFC2400703)the National Nat-ural Science Foundation of China(NSFC)(52171234)+1 种基金Beijing Municipal Science and Technology Project(Z211100002921066)Peking Univer-sity National Clinical Key Specialty Translation Support Project(PKUSSNKP-Т202104).
文摘Biodegradable metals have been increasingly utilized clinically due to their biosafety and pro-osteogenic prop-erties.However,conventional monolayer cell-based preclinical safety evaluation methods based on ISO10993-5 consistently indicate significant cytotoxicity that contradicts in vivo outcomes.In this study,we aimed to establish an in vitro evaluation model that better correlates with in vivo performance.Three-layer BMSC cell sheets were constructed using layer-by-layer assembly.Histological analyses revealed a stable three-dimensional structure with elevated cell-cell interaction proteins,including N-Cadherin,Fibronectin,and Vinculin,along with enhanced osteogenic potential.The cytotoxicity of 4N pure Mg was evaluated in both cell sheet and monolayer co-culture models.Flow cytometry showed higher Ki67 expression and lower ROS levels and apoptosis rate in cell sheets.ShRNA-mediated silencing of N-Cadherin in cell sheets significantly compromised their cytopro-tective capacity against Mg metal-induced toxicity.Osteogenesis-related gene expression correlation analysis between in vitro co-culture models and in vivo femur implantation models was conducted using RNA-seq and qRT-PCR.Results showed that 4N pure Mg enhanced osteogenic genes(BMP2R,RUNX2,and SP7)in cell sheets,consistent with in vivo patterns but contrary to monolayer models.Various Mg-based metals(4N/5N Pure Mg,ZE21B,and WE43)were evaluated in cell sheet defect,monolayer defect,and cranial defect models.5N Pure Mg,ZE21B,and WE43 promoted defect healing in both cranial defect and cell sheets,but showed no positive effect in monolayers.Collectively,cell sheet models correlated well with in vivo results,suggesting their potential as alternative in vitro evaluation models,thereby accelerating clinical translation of Mg-based biomaterials.
基金supported by the Science and Technology Planning Project of Guangdong Province(Nos.2024A0505040016 and 2023A0505050148)National Key Research and Development Project of China(2023YFB3809900/2023YFB3809902)Natural Science Foundation of Guangdong Province(No.2025A1515010026)。
文摘Biodegradable metals have garnered considerable interest owing to their capacity for self-degradation following the repair of damaged tissues.This review commences with their historical development and clarifies the essential prerequisites for their successful clinical translation.Subsequently,a detailed review of magnesium-based materials is presented from five critical areas of alloying,fabrication techniques,purification,surface modification,and structural design,systematically addressing their progress in biodegradation rate retardation,mechanical reinforcement,and biocompatibility enhancement.Furthermore,recent breakthroughs in vivo animal experiments and clinical translation of magnesium alloys are summarized.Finally,this review concludes with a critical assessment of the achievements and challenges encountered in the clinical application of these materials,and proposes practical strategies to address current limitations and guide future research perspectives.
基金supported by the National Key R&D Program of China(2021YFC2400500)Shanghai Committee of Science and Technology,China(20S31901200)+2 种基金the Fundamental Research Funds for the Central Universities(2022ZYGXZR042)Postdoctoral Science Foundation of China(2022M723288)GDPH Supporting Fund for Talent Program(KY0120220137).
文摘The rapid corrosion rate and limited biological functionality still pose challenges for magnesium(Mg)-based implants in the treatment of complicated bone-related diseases in clinic.Herein,a multifunctional biodegradable curcumin(herbal medicine)-ferrum(Cur-Fe)nanoflower was self-assembled on plasma electrolytic oxidation(PEO)-treated Mg alloy via a facile immersion process to realize differential biological function for anti-bacteria/tumor and bone regeneration.The results indicated that Cur-Fe nanoflower coating can promote protein adsorption,cell adhesion and proliferation,exhibiting excellent biocompatibility.The Cur-Fe nanoflower coating exhibits unique degradation characteristics,as curcumin gradually decomposes into ferulic acid,aromatic aldehyde and other antibacterial substances,and the coating spontaneously converts into FeOOH nanosheets,ensuring the corrosion resistance of Mg-based implants.Moreover,Cur-Fe coating exhibits remarkable narrow gap semiconductor characteristics,which can generate reactive oxygen species(ROS)and demonstrated excellent antibacterial effect under simulated sunlight(SSL)irradiation.Meanwhile,under NIR irradiation,Cur-Fe coating showed excellent chemotherapy/photodynamic/photothermal synergetic antitumor properties in vitro and in vivo due to the introduction of curcumin,and photocatalysis and photothermal conversion properties of coating.Furthermore,Cur-Fe nanoflower coating demonstrated great osteogenesis activity in vitro and in vivo due to unique micro/nano structure,surface chemical bond,and the release of Mg and Fe ions.
基金financially supported by the National Natural Science Foundation of China(Nos.81871742 and 82102538)Shanghai Sailing Program(No.21YF1405800)+2 种基金Shanghai Pudong Science and Technology Development Funding(No.PKJ2020-Y44)the Featured Clinical Discipline Project of Shanghai Pudong New District(No.Pwyts2021-03)the support of the National Engineering Research Center of Light Alloy Net Forming,Shanghai Jiao Tong University
文摘Osteoporotic fractures often exhibit delayed healing and repair difficulties in which the bone immune microenvironment may play a critical role,but direct evidence remains elusive.Recently,magnesium(Mg)-based alloys have emerged as promising biodegradable materials capable of promoting fracture healing.Herein,we performed internal fixation of high-purity Mg implants for osteoporotic fractures and used single-cell studies to investigate and elucidate the cellular heterogeneity and dynamic changes that occurred during osteoporotic fracture repair.We observed an early increase in immature neutrophil numbers,together with anti-inflammatory changes in lymphocytes and macrophages.A cluster of macrophages exhibited pro-angiogenic capabilities activated via the TRPM7/S100A4 pathway.These findings provide new theoretical insights into the biological effects of Mg-based materials on the healing of osteoporotic fractures.
基金financially supported by the National Key Research and Development Program of China(No.2023YFB3809101)the National Natural Science Foundation of China(No.U23A20128)the Chongqing Science and Technology Commission of China(CSTC2024YCJHBGZXM0041).
文摘Magnesium-based hydrogen storage materials are promising candidates for hydrogen storage due to their high storage density and environmentally friendly properties.However,the high dehydrogenation enthalpy change(approximately 75 kJ/mol H_(2))and high dehydrogenation temperature(573 K at 0.1 MPa)of MgH_(2),limits the engineering application of Mg/MgH_(2) as a hydrogen storage material.This work reviews the prediction models and methods of enthalpy changes for hydriding/dehydriding(H/D)reactions in order to find out the ideas and ways to reduce them.The mechanism behind the improvement methods mainly includes two aspects,weakening Mg-H bond and compensating heat of reaction.Proceed from this,the experimental methods and enthalpy data as well as calculated values of enthalpy changes were compared systematically.Elements such as Ti,Nb,V,etc.,with a small electronegativity difference compared to Mg,can reduce the hydrogenation and dehydrogenation enthalpy changes by forming strong Metal-H or Metal-Mg bonds.In addition,this review concludes with an outlook on the remaining challenge issues and prospects.
文摘Over the last decade’s magnesium and magnesium based compounds have been intensively investigated as potential hydrogen storage as well as thermal energy storage materials due to their abundance and availability as well as their extraordinary high gravimetric and volumetric storage densities.This review work provides a broad overview of the most appealing systems and of their hydrogenation/dehydrogenation properties.Special emphasis is placed on reviewing the efforts made by the scientific community in improving the material’s thermodynamic and kinetic properties while maintaining a high hydrogen storage capacity.
基金supported by the Chongqing Special Key Project of Technology Innovation and Application Development,China(cstc2019jscx-dxwt B0029)the National Natural Science Foundation of China(51871143)+5 种基金the Science and Technology Committee of Shanghai(19010500400)the Shanghai Rising-Star Program(21QA1403200)Chongqing Research Program of Basic Research and Frontier Technology(No.cstc2019jcyj-msxm X0306)the Start-up Funds of Chongqing University(02110011044171)the Senior Talent Start-up Funds of Jiangsu University(4111310024)the Independent Research Project of State Key Laboratory of Mechanical Transmissions(SKLMT-ZZKT-2021M11)
文摘Mg-based materials are one of the most promising hydrogen storage candidates due to their high hydrogen storage capacity,environmental benignity,and high Clarke number characteristics.However,the limited thermodynamics and kinetic properties pose major challenges for their engineering applications.Herein,we review the recent progress in improving their thermodynamics and kinetics,with an emphasis on the models and the influence of various parameters in the calculated models.Subsequently,the impact of alloying,composite,and nanocrystallization on both thermodynamics and dynamics are discussed in detail.In particular,the correlation between various modification strategies and the hydrogen capacity,dehydrogenation enthalpy and temperature,hydriding/dehydriding rates are summarized.In addition,the mechanism of hydrogen storage processes of Mg-based materials is discussed from the aspect of classical kinetic theories and microscope hydrogen transferring behavior.This review concludes with an outlook on the remaining challenge issues and prospects.
基金financially supported by the National Natural Science Foundation of China (Nos. 51161015 and 51371094)
文摘Magnesium and magnesium-based alloy hydrides remain attractive hydrogen storage materials owing to high hydrogen capacity and rich reserves in the earth's crust. A high stability of hydride and sluggish hydriding/dehydriding kinetics at practical temperatures for the materials drove researchers into alloying with other elements, using different preparation techniques, using catalyst and thin film hydride to improve the hydrogen absorption/desorption properties. In this review, the development of these approaches and their effects on the thermodynamic and kinetics properties of magnesium and magnesium-based alloy hydrides were descript in details.
基金supported in part by the Light Metals Educational Foundation of Japan,and in part by the MEXT,Japan through Grants-in-Aid for Scientific Research on Innovative Areas(Nos.JP19H05176&JP21H00150)the Challenging Research Exploratory(Grant No.JP22K18737)+6 种基金W.J.Botta is grateful to the Brazilian agencies FAPESP(Grant No.2013/05987-8)CNPq(Grant Nos.421181-2018-4 and 307397-2019-0)the financial support and to the Laboratory of Structural Characterization(LCE-DEMa-UFSCar)for general electron microscopy facilities.R.Floriano thanks for the financial support from FAPESP(Grant No.2022/01351-0)support from the French State through the ANR-21-CE08-0034-01 project as well as the program“Investment in the future”operated by the National Research Agency(ANR)referenced under No.ANR-11-LABX-0008-01(Labex DAMAS)support from the National Natural Science Foundation of China(Grant No.52171205)support from the National Natural Science Foundation of China(Grant No.52071157).
文摘Magnesium and its alloys are the most investigated materials for solid-state hydrogen storage in the form of metal hydrides,but there are still unresolved problems with the kinetics and thermodynamics of hydrogenation and dehydrogenation of this group of materials.Severe plastic deformation(SPD)methods,such as equal-channel angular pressing(ECAP),high-pressure torsion(HPT),intensive rolling,and fast forging,have been widely used to enhance the activation,air resistance,and hydrogenation/dehydrogenation kinetics of Mg-based hydrogen storage materials by introducing ultrafine/nanoscale grains and crystal lattice defects.These severely deformed materials,particularly in the presence of alloying additives or second-phase nanoparticles,can show not only fast hydrogen absorption/desorption kinetics but also good cycling stability.It was shown that some materials that are apparently inert to hydrogen can absorb hydrogen after SPD processing.Moreover,the SPD methods were effectively used for hydrogen binding-energy engineering and synthesizing new magnesium alloys with low thermodynamic stability for reversible low/room-temperature hydrogen storage,such as nanoglasses,high-entropy alloys,and metastable phases including the high-pressureγ-MgH2 polymorph.This work reviews recent advances in the development of Mg-based hydrogen storage materials by SPD processing and discusses their potential in future applications.
基金The authors would like thank to Universiti Sains Malaysia for FRGS Grant No.203/PBAHAN/6071386 and financial scholarship from Ministry of Higher Education of Malaysia.
文摘Magnesium-based biomaterials have recently gained great attention as promising candidates for the new generation of biodegradable implants.This study investigated the mechanical performance and biodegradation behaviour of magnesium-zinc/hydroxyapatite(Mg-Zn/HA)composites fabricated by different powder mixing techniques.A single step mixing process involved mechanical alloying or mechanical milling techniques,while double step processing involved a combination of both mechanical alloying and mechanical milling.Optimum mechanical properties of the composite were observed when the powders were prepared using single step processing via mechanical alloying technique.However,Mg-Zn/HA composite fabricated through single step processing via mechanical milling technique was found to have the most desirable low degradation rate coupled with highest bioactivity.The composite achieved the lowest degradation rate of 0.039×10^−3 mm/year as measured by immersion test and 0.0230 mm/year as measured by electrochemical polarization.Ca:P ratio of the composite also slightly more than enough to aid the initial bone mineralization,that is 1:1.76,as the required Ca:P ratio for initial bone mineralization is between 1:1 and 1:1.67.
基金financially supported by the research programs of the National Natural Science Foundation of China (No. 52101274)the Natural Science Foundation of Shandong Province, China (No. ZR2020QE011)the Youth Top Talent Foundation of Yantai University, China (No. 2219008)
文摘Hydrogen is an ideal clean energy because of its high calorific value and abundance of sources.However,storing hydrogen in a compact,inexpensive,and safe manner is the main restriction on the extensive utilization of hydrogen energy.Magnesium(Mg)-based hydrogen storage material is considered a reliable solid hydrogen storage material with the advantages of high hydrogen storage capacity(7.6wt%),good performance,and low cost.However,the high thermodynamic stability and slow kinetics of Mg-based hydrogen storage materials have to be overcome.In this paper,we will review the recent advances in the nanoconfinement of Mg-related hydrogen storage materials by loading Mg particles on different supporting materials,including carbons,metal-organic frameworks,and other materials.Perspectives are also provided for designing high-performance Mg-based materials using nanoconfinement.
