With the growing importance of wearable and portable electronics in modern society and industry,researchers from all over the world have reported on advances in energy harvesting and self-powered sensing technologies....With the growing importance of wearable and portable electronics in modern society and industry,researchers from all over the world have reported on advances in energy harvesting and self-powered sensing technologies.The current review discusses recent developments in triboelectric platforms from a manufacturing perspective,including material,design,application,and industrialization.Manufacturing is an essential component of both industry and technology.The use of a proper manufacturing process enables cutting-edge technology in a lab-scale stage to progress to commercialization and popularization with scalability,availability,commercial advantage,and consistent quality.Furthermore,much literature has emphasized that the most powerful advantage of the triboelectric platform is its wide range of available materials and simple working mechanism,both of which are important characteristics in manufacturing engineering.As a result,different manufacturing processes can be implemented as needed.Because the practical process can have a synergetic effect on the fundamental development,resulting in the growth of both,the development of the triboelectric platform from the standpoint of manufacturing engineering can be further advanced.However,research into the development of a productive manufacturing process is still in its early stages in the field of triboelectric platforms.This review looks at the various manufacturing technologies used in previous studies and discusses the potential benefits of the appropriate process for triboelectric platforms.Given its unique strength,which includes a diverse material selection and a simple working mechanism,the triboelectric platform can use a variety of manufacturing technologies and the process can be optimized as needed.Numerous research groups have clearly demonstrated the triboelectric platform's advantages.As a result,using appropriate manufacturing processes can accelerate the technological advancement of triboelectric platforms in a variety of research and industrial fields by allowing them to move beyond the lab-scale fabrication stage.展开更多
Soft robots have partially or entirely provided versatile opportunities for issues or roles that cannot be addressed by conventional machine robots,although most studies are limited to designs,controls,or physical/mec...Soft robots have partially or entirely provided versatile opportunities for issues or roles that cannot be addressed by conventional machine robots,although most studies are limited to designs,controls,or physical/mechanical motions.Here,we present a transformable,reconfigurable robotic platform created by the integration of magnetically responsive soft composite matrices with deformable multifunctional electronics.Magnetic compounds engineered to undergo phase transition at a low temperature can readily achieve reversible magnetization and conduct various changes of motions and shapes.Thin and flexible electronic system designed with mechanical dynamics does not interfere with movements of the soft electronic robot,and the performances of wireless circuit,sensors,and devices are independent of a variety of activities,all of which are verified by theoretical studies.Demonstration of navigations and electronic operations in an artificial track highlights the potential of the integrated soft robot for on-demand,environments-responsive movements/metamorphoses,and optoelectrical detection and stimulation.Further improvements to a miniaturized,sophisticated system with material options enable in situ monitoring and treatment in envisioned areas such as biomedical implants.展开更多
Organometal halide perovskites are promising semiconducting materials for photodetectors because of their favorable optoelectrical properties.Although nanoscale perovskite materials such as quantum dots(QDs)show novel...Organometal halide perovskites are promising semiconducting materials for photodetectors because of their favorable optoelectrical properties.Although nanoscale perovskite materials such as quantum dots(QDs)show novel behavior,they have intrinsic stability issues.In this study,an effectively silane barrier-capped quantum dot(QD@APDEMS)is thinly applied onto a bulk perovskite photosensitive layer for use in photodetectors.QD@APDEMS is synthesized with a silane ligand with hydrophobic CH_(3)-terminal groups,resulting in excellent dispersibility and durability to enable effective coating.The introduction of the QD@APDEMS layer results in the formation of a lowdefect perovskite film with enlarged grains.This is attributed to the grain boundary interconnection effect via interaction between the functional groups of QD@APDEMS and uncoordinated Pb^(2+)in grain boundaries.By passivating the grain boundaries,where various trap sites are distributed,hole chargecarrier injection and shunt leakage can be suppressed.Also,from the energy point of view,the deep highest occupied molecular orbital(HOMO)level of QD@APDEMS can work as a hole charge injection barrier.Improved charge dynamics(generation,transfer,and recombination properties)and reduced trap density of QD@APDEMS are demonstrated.When this perovskite film is used in a photodetector,the device performance(especially the detectivity)stands out among existing perovskites evaluated for energy sensing device applications.展开更多
Liquid metals(LMs),because of their ability to remain in a liquid state at room temperature,render them highly versatile for applications in electronics,energy storage,medicine,and robotics.Among various LMs,Ga-based ...Liquid metals(LMs),because of their ability to remain in a liquid state at room temperature,render them highly versatile for applications in electronics,energy storage,medicine,and robotics.Among various LMs,Ga-based LMs exhibit minimal cytotoxicity,low viscosity,high thermal and electrical conductivities,and excellent wettability.Therefore,Ga-based LM composites(LMCs)have emerged as a recent research focus.Recent advancements have focused on novel fabrication techniques and applications spanning energy storage,flexible electronics,and biomedical devices.Particularly noteworthy are the developments in wearable sensors and electronic skins,which hold promise for healthcare monitoring and human-machine interfaces.Despite their potential,challenges,such as oxidative susceptibil-ity and biocompatibility,remain.Creating bio-based LMC materials is a promising approach to address these issues while exploring new avenues to optimize LMC performance and broaden its application domains.This review provides a concise overview of the recent trends in LMC research,highlights their transformative impacts,and outlines key directions for future investigation and development.展开更多
The harsh corrosive environment and sluggish oxygen evolution reaction(OER)kinetics at the anode of proton exchange membrane water electrolysis(PEMWE)cells warrant the use of excess Ir,thereby hindering large-scale in...The harsh corrosive environment and sluggish oxygen evolution reaction(OER)kinetics at the anode of proton exchange membrane water electrolysis(PEMWE)cells warrant the use of excess Ir,thereby hindering large-scale industrialization.To mitigate these issues,the present study aimed at fabricating a robust low-Ir-loading electrode via one-pot synthesis for efficient PEMWE.The pre-electrode was first prepared by alloying through the co-electrodeposition of Ir and Co,followed by the fabrication of Ir–Co oxide(Co-incorporated Ir oxide)electrodes via electrochemical dealloying.Two distinct dealloying techniques resulted in a modified valence state of Ir,and the effects of Co incorporation on the activity and stability of the OER catalysts were clarified using density functional theory(DFT)calculations,which offered theoretical insights into the reaction mechanism.While direct experimental validation of the oxygen evolution mechanism remains challenging under the current conditions,DFT-based theoretical modeling provided valuable perspectives on how Co incorporation could influence key steps in oxygen evolution catalysis.The Ir–Co oxide electrode with a selectively modulated valence state showed impressive performance with an overpotential of 258 mV at 10 mA cm^(−2),a low Tafel slope of 29.4 mV dec^(−1),and stability for 100 h at 100 mA cm^(−2)in the OER,in addition to a low overpotential of 16 mV at−10 mA cm^(−2)and high stability for 24 h in the hydrogen evolution reaction.The PEMWE cell equipped with the bifunctional Ir–Co oxide electrode as the anode and cathode exhibited outstanding performance(11.4 A cm^(−2)at 2.3 Vcell)despite having a low noble-metal content of 0.4 mgNM cm^(−2).展开更多
The advancement of wireless technologies has increased the global demand for ubiquitous connectivity.However,this surge has increased electromagnetic pollution.This study introduces a composite comprising a polymer ma...The advancement of wireless technologies has increased the global demand for ubiquitous connectivity.However,this surge has increased electromagnetic pollution.This study introduces a composite comprising a polymer matrix(polydimethylsiloxane,PDMS)and a magnetic filler(carbonyl iron powder,CIP)to effectively absorb electromagnetic waves(EMW)and suppress electromagnetic noise,while exhibiting good mechanical properties.Eutectic gallium–indium(EGa In)liquid metal(LM)was introduced to improve the insulating properties of magnetic fillers.A core–shell structure was obtained by coating the CIP particles with EGa In,thereby combining magnetic and dielectric materials to enhance EMW absorption.The fluid characteristics of the LM improved the mechanical properties,whereas its electrical conductivity enhanced interfacial polarization loss,thereby augmenting the dielectric loss value of the composites.Moreover,the application of mechanical strain enhanced the EMW absorption of the LM/CIP/PDMS composites due to the formation of a conductive LM network.展开更多
In secondary Al-Si based alloys,microalloying with Mn and Cr can modify harmful platelet-type Alx Fey Siz intermetallic phases to less detrimentalα-Alx(Fe,Mn,Cr)_(y)Siz phase(script or polygonal morphologies).However...In secondary Al-Si based alloys,microalloying with Mn and Cr can modify harmful platelet-type Alx Fey Siz intermetallic phases to less detrimentalα-Alx(Fe,Mn,Cr)_(y)Siz phase(script or polygonal morphologies).However,theα-Alx(Fe,Mn,Cr)_(y)Siz phase morphology,phase composition and the addition of Fecorrecting elements can be influenced by solidification conditions.Therefore,this research is aimed to highlight the morphological evolution and mechanisms ofα-Alx(Fe,Mn,Cr)_(y)Si_(z)phase in a Cr added Al-9%Si-1%Fe-0.2%Cr(all weight percentage thereafter,unless otherwise stated)alloy with varying Mn concentrations(0.25%,0.5%,and 0.8%).Microstructure evolution of Fe intermetallic phases is investi-gated under different casting conditions using a wedge-shaped die,Cu-chill block and melt quenching experiments.Thermodynamic simulations have been performed using CALculation of PHAse Diagrams(CALPHAD)method and compared with the experimental results for phase composition and formation temperatures ofα-Alx(Fe,Mn,Cr)_(y)Siz phase.The results indicated that for 0.25Mn-0.2Cr addition to Al-9Si-1Fe alloy,compact morphology containing polygonal phases are formed in Cu-chill casting,while the wedge castings predominantly show a mixed structure with platelets and script type morphologies.Tensile tests revealed a higher elongation value of 6.6%for mixed structure with platelet and script phases,which is decreased to 4.2%for polygonal phases in Al-9Si-1Fe-0.2Cr-0.25Mn alloy.This study highlights the importance of solidification conditions on morphologies of Fe-intermetallic phases and the mechanical properties by comparing selected literature relevant to high pressure die-casting process.展开更多
The crystallization of ionic crystals has traditionally been explained by Gibbs's classical nucleation theory.However,recent observations of intermediate phases during nucleation suggest that the process may be mo...The crystallization of ionic crystals has traditionally been explained by Gibbs's classical nucleation theory.However,recent observations of intermediate phases during nucleation suggest that the process may be more complex,necessitating new theoretical frameworks,though key empirical evidence remains elusive.In this study,we used microdroplets to investigate the crystallization of sodium halides(NaCl,NaBr,and NaI)under homogeneous nucleation conditions across a wide range of supersaturations.In the evaporating droplet,NaCl follows the classical nucleation pathway,whereas NaBr and NaI exhibit the formation of an intermediate phase prior to the nucleation of anhydrous and hydrous single crystals,respectively.Optical and computational analyses indicate that these intermediate phases are liquid crystal phases composed of contact ion pairs.These findings establish a new theoretical framework for crystal nucleation and growth and offer methods to control nucleation pathways,enabling us to achieve desired crystals regardless of specific conditions.展开更多
The authors regret the following changes to the paper:1.The following author is added to this article:Agnieszka Chmielewska-Wysockaa 2.Section 2.1:●“An aqueous binder”should be changed to“A solvent binder”.●Repl...The authors regret the following changes to the paper:1.The following author is added to this article:Agnieszka Chmielewska-Wysockaa 2.Section 2.1:●“An aqueous binder”should be changed to“A solvent binder”.●Replace“a composition of ethylene glycol monobutyl ether and ethylene glycol”by“50% binder saturation”.展开更多
Metabolic dysfunction-associated fatty liver disease(MASLD)and alcohol-associated liver disease(ALD)are prevalent chronic liver diseases that can progress to steatohepatitis,fibrosis,cirrhosis,and ultimately liver fai...Metabolic dysfunction-associated fatty liver disease(MASLD)and alcohol-associated liver disease(ALD)are prevalent chronic liver diseases that can progress to steatohepatitis,fibrosis,cirrhosis,and ultimately liver failure.Here,we demonstrated that oral administration of GNVs provided substantial protection against liver injury and fibrosis in MASLD and ALD mouse models.In a Western-style high-fat diet-induced MASLD model and a chronic binge alcohol-induced ALD model,GNVs treatment significantly reduced gut leakiness by restoring intestinal junctional complex proteins and rebalancing the gut microbiome.GNVs attenuated hepatic lipid accumulation,oxidative stress and fibrogenicmarkers.GNV treatment downregulated the fibrosis-associated tissue inhibitor of metalloproteinase-2(TIMP2)pathway in hepatic stellate cells,which is linked to enhanced matrix degradation and reduced fibrogenesis.GNVs prevent MASLD-and ALD-associated gut barrier dysfunction and liver fibrosis through modulation of the gut-liver axis and the TIMP2 pathway.Edible GNVs represent a novel,multifaceted therapeutic strategy for managing chronic liver diseases.展开更多
This study demonstrates the fabrication of mesoporous tungsten trioxide(WO_(3))-decorated flexible polyimide(PI)electrodes for the highly sensitive detection of catechol(CC)and hydroquinone(HQ),two environmental pollu...This study demonstrates the fabrication of mesoporous tungsten trioxide(WO_(3))-decorated flexible polyimide(PI)electrodes for the highly sensitive detection of catechol(CC)and hydroquinone(HQ),two environmental pollutants.Organic-inorganic composite dots are formed on flexible PI electrodes using evaporation-induced self-assembly(EISA)and electrospray methods.The EISA process is induced by a temperature gradient during electrospray,and the heated substrate partially decomposes the organic parts etched by O_(2) plasma,creating mesoporous structures.Differential pulse voltammetry and cyclic voltammetry demonstrate a linear correlation between analyte concentration and the electrochemical response.Computational studies support the spontaneous adsorption of CC and HQ molecules on model WO_(3) surfaces.The proposed sensor shows high sensitivity,a wide linear range,and a low detection limit for both individual and simultaneous determination of CC and HQ.Real sample analysis on river water confirms practical applicability.The WO_(3)-decorated PI electrode presents an efficient and reliable approach for detecting these pollutants,contributing to environmental safety measures.展开更多
The advancement in catalysis techniques for sustainable environmental applications,particularly an alternative to the current Haber-Bosch process for NH_(3),has recently gained widespread attention.Although photocatal...The advancement in catalysis techniques for sustainable environmental applications,particularly an alternative to the current Haber-Bosch process for NH_(3),has recently gained widespread attention.Although photocatalytic conversion of N_(2) to NH_(3) using solar energy is an eco-friendly method,it has the limitation of low quantum yield.Recently,2D Bi-based photocatalysts which exhibit higher visible light absorption than TiO_(2) and higher stability than MXene have been an active research topic,and their performance can be enhanced through improved visible light absorption properties by incorporating plasmonic gold nanoparticles while nitrogen adsorption could be enhanced through oxygen vacancy(OV)processes.In the present study,we explore the application of 2D nanosized Bi_(2)O_(3–x) and gold nanoparticles for visible light photo generation of NH_(3).HRTEM and XPS reveal that the formation of AuNP and nano-sized Bi_(2)O_(3–x) in AuNP/Bi_(2)O_(3–x) heterozygote structure promotes the charge carrier mobility and charge transport at the interface,resulting in a 2.6-fold increase in the photocatalytic activity compared to micro-sized Bi_(2)O_(3–x) with AuNP.The improved photocatalytic performance can be ascribed to significant enhancement of visible light absorption by plasmonic nanoparticles,fast charge transport and mobility(due to sheet morphology)and the N_(2) activation by OV in AuNP/Bi_(2)O_(3–x) heterozygote.Through a systematic experimental investigation involving catalysts,concentration,pH,and scavengers,the highest photocatalytic performance was achieved with the heterozygote structures of AuNP/n-Bi_(2)O_(3–x) under optimized conditions,yielding 432.5μmol gcat^(-1) h^(-1) of NH_(3).展开更多
Sustainable transformation and efficient utilization of biomasses and their derived materials are environ-mentally as well as economically compliant strategies.Biomass seaweed-derived nitrogen self-doped porous carbon...Sustainable transformation and efficient utilization of biomasses and their derived materials are environ-mentally as well as economically compliant strategies.Biomass seaweed-derived nitrogen self-doped porous carbon with tailored surface area and pore structures are prepared through carb on izatio n and activation.The in fluence of carb on ization temperature on morphology,surface area,and heteroatom dopants are investigated to optimize sodium-ion storage capability.Seaweed-derived nitrogen selfdoped activated carbon(SAC)as anode materials for sodium-ion batteries exhibits remarkable reversible capacity of 303/192 mAh g^(-1) after 100/500 cycles at current densities of 100/200 mA g^(-1) respectively,and a good rate capability.The interconnected and porous conducting nature along with the heteroatom dopant role in creating defective sites and charge stabilization are favorable for ion storage and diffusion and electron transport,indicating the electrodes can offer improved electrochemical performances.In addition,post-mortem analysis of the cycled carbon electrodes through ex-situ tools demonstrates the sodium-ion storage mechanism.展开更多
This paper summarizes the melting and casting processes for magnesium alloys.It also reviews the historical development of magnesium castings and their structural uses in the western world since 1921 when Dow began pr...This paper summarizes the melting and casting processes for magnesium alloys.It also reviews the historical development of magnesium castings and their structural uses in the western world since 1921 when Dow began producing magnesium pistons.Magnesium casting technology was well developed during and after World War II,both in gravity sand and permanent mold casting as well as high-pressure die casting,for aerospace,defense and automotive applications.In the last 20 years,most of the development has been focused on thin-wall die casting applications in the automotive industry,taking advantages of the excellent castability of modern magnesium alloys.Recently,the continued expansion of magnesium casting applications into automotive,defense,aerospace,electronics and power tools has led to the diversification of casting processes into vacuum die casting,low-pressure die casting,squeeze casting,lost foam casting,ablation casting as well as semi-solid casting.This paper will also review the historical,current and potential structural use of magnesium with a focus on automotive applications.The technical challenges of magnesium structural applications are also discussed.Increasing worldwide energy demand,environment protection and government regulations will stimulate more applications of lightweight magnesium castings in the next few decades.The development of use of Integrated Computational Materials Engineering(ICME)tools will accelerate the applications of magnesium castings in structural applications.展开更多
As the lightest structural metal and one of the most abundant metallic elements on earth, magnesium(Mg) has been used as an "industrial metal" for lightweighting in the transportation and electronics industr...As the lightest structural metal and one of the most abundant metallic elements on earth, magnesium(Mg) has been used as an "industrial metal" for lightweighting in the transportation and electronics industries, in addition to other traditional applications in aluminum alloying,steel desulfurization and protective anodes. In recent years, research has shown significant potential for Mg to become a "technology metal"in a variety of new applications from energy storage/battery to biomedical products. However, global Mg production has shown steady but moderate growth in the last three decades. Mg applications as an industry metal are still limited due to some sustainability concerns of primary Mg production, as well as a number of technical issues related to the structural and corrosion performance of commercial Mg alloys.New Mg applications as an industrial or technology metal face tremendous technical challenges, which have been reflected in the intensified global research efforts in the last twenty years. This paper will review some past and present applications, and discuss future opportunities and challenges for Mg research and applications for the global Mg community.展开更多
Mg-rare earth(RE)based systems provide several important commercial alloys and many alloy development opportunities for high strength applications,especially in aerospace and defense industries.The phase diagrams,micr...Mg-rare earth(RE)based systems provide several important commercial alloys and many alloy development opportunities for high strength applications,especially in aerospace and defense industries.The phase diagrams,microstructure,and strengthening mechanisms of these multicomponent systems are very complex and often not well understood in literature.We have calculated phase diagrams of important binary,ternary,and multicomponent RE-containing alloy systems,using CALPHAD(CALculation of PHAse Diagrams).Based on these phase diagrams,this paper offers a critical overview on phase equilibria and strengthening mechanisms in these alloy systems,including precipitation,long period stacking order(LPSO),and other intermetallic phases.This review also summarized several promising Mg-RE based cast alloys in comparison with commercial WE54 and WE43 alloys;and explored new strategies for future alloy development for high strength applications.It is pointed out that the combination of precipitation and LPSO phases can lead to superior strength and ductility in Mg-RE based cast alloys.The precipitates and LPSO phases can form a complex three-dimensional network that effectively impedes dislocation motion on the basal and non-basal planes.The LPSO phases can also prevent the coarsening of precipitates when they interact,thus providing good thermal stability at elevated temperatures.Future research is needed to determine how the combination of these two types of phases can be used in alloy design and industrial scale applications.展开更多
Porosity formation during solidification of aluminum-based alloys,due to hydrogen gas and alloy shrinkage,has been a major issue adversely affecting the performance of solidification products such as castings,welds or...Porosity formation during solidification of aluminum-based alloys,due to hydrogen gas and alloy shrinkage,has been a major issue adversely affecting the performance of solidification products such as castings,welds or additively manufactured components.A three-dimensional cellular automaton(CA)model has been developed,for the first time,to couple the predictions of hydrogen-induced gas porosity and shrinkage porosity during solidification microstructure evolution of a binary Al-Si alloy.The CA simulation results are validated under various cooling rates by porosity measurements in an experimental wedge die casting using X-ray micro computed tomography(XMCT)technique.This validated porosity moel provides a critical link in integrated computation materials engineering(ICME)design and manufacturing of solidification products.展开更多
Soft clays are problematic soils as they present high compressibility and low shear strength.There are several methods for improving in situ conditions of soft clays.Based on the geotechnical problem’s geometry and c...Soft clays are problematic soils as they present high compressibility and low shear strength.There are several methods for improving in situ conditions of soft clays.Based on the geotechnical problem’s geometry and characteristics,the in situ conditions may require reinforcement to restrain instability and construction settlements.Granular columns reinforced by geosynthetic material are widely used to reduce settlements of embankments on soft clays.They also accelerate the consolidation rate by reducing the drainage path’s length and increasing the foundation soil’s bearing capacity.In this study,the performance of encased and layered granular columns in soft clay is investigated and discussed.The numerical results show the significance of geosynthetic stiffness and the column length on the embankment settlements.Furthermore,the results show that granular columns may play an important role in dissipating the excess pore water pressures and accelerating the consolidation settlements of embankments on soft clays.展开更多
ZE20(Mg-2Zn-0.2Ce)^2 is a new wrought magnesium alloy with improved extrudability and mechanical properties[1].To understand the constitutive behavior and workability of this new alloy,Gleeble thermomechanical testing...ZE20(Mg-2Zn-0.2Ce)^2 is a new wrought magnesium alloy with improved extrudability and mechanical properties[1].To understand the constitutive behavior and workability of this new alloy,Gleeble thermomechanical testing has been carried out in this study.The flow stress behavior of ZE20 was investigated between 250℃–450℃ and 10^–3 s^–1–1.0 s^–1 in isothermal compression.Constitutive descriptions of the flow stress are provided.A new general approach at application of the extended Ludwik equation is demonstrated and was found to be more accurate than the hyperbolic sine Arrhenius model while having a similar number of model constants.Processing maps were developed based on the experimental results and are verified with microstructural investigation.A region of safe processing with non-basal texture and high activity of dynamic recrystallization(DRX)was found between 375℃ and 450℃,from 10^–1 s^–1 to 10^–2.5 s^–1.A region of potentially safe processing with annealing that is associated with shear band nucleation of non-basal grains was identified for temperatures as low as 300℃ and rates as high as 10^–1 s^–1.展开更多
In this study,an overcasting process followed by a low-temperature(200°C)annealing schedule has been developed to bond magnesium to aluminum alloys.ProCAST software was used to optimize the process parameters dur...In this study,an overcasting process followed by a low-temperature(200°C)annealing schedule has been developed to bond magnesium to aluminum alloys.ProCAST software was used to optimize the process parameters during the overcasting process which lead to Mg/Al bimetallic structures to be successfully produced without formation of Mg-Al intermetallic phases.Detailed microstructure evolution during annealing,including the formation and growth of Al-Mg interdiffusion layer and intermetallic phases(Al12Mg17 and Al3Mg2),was experimentally observed for the first time with direct evidence,and predicted using Calculation of Phase Diagrams(CALPHAD)modeling.Maximum interfacial strength was achieved when the interdiffusion layer formed at the Mg/Al interface reached a maximum thickness the without formation of brittle intermetallic compounds.The precise diffusion modeling of the Mg/Al interface provides an efficient way to optimize and control the interfacial microstructure of Mg/Al bimetallic structures for improved interfacial bonding.展开更多
基金supported by the National Research Foundation of Korea(NRF)(No.2021R1C1C2009703)supported by the National Research Foundation of Korea(NRF)Grant funded by the Korea government(MSIT)(RS-2024-00344920)supported by the Human Resources Development of the Korea Institute of Energy Technology Evaluation and Planning(KETEP)Grant funded by the Ministry of Trade,Industry and Energy of Korea(No.RS2023-00244330)。
文摘With the growing importance of wearable and portable electronics in modern society and industry,researchers from all over the world have reported on advances in energy harvesting and self-powered sensing technologies.The current review discusses recent developments in triboelectric platforms from a manufacturing perspective,including material,design,application,and industrialization.Manufacturing is an essential component of both industry and technology.The use of a proper manufacturing process enables cutting-edge technology in a lab-scale stage to progress to commercialization and popularization with scalability,availability,commercial advantage,and consistent quality.Furthermore,much literature has emphasized that the most powerful advantage of the triboelectric platform is its wide range of available materials and simple working mechanism,both of which are important characteristics in manufacturing engineering.As a result,different manufacturing processes can be implemented as needed.Because the practical process can have a synergetic effect on the fundamental development,resulting in the growth of both,the development of the triboelectric platform from the standpoint of manufacturing engineering can be further advanced.However,research into the development of a productive manufacturing process is still in its early stages in the field of triboelectric platforms.This review looks at the various manufacturing technologies used in previous studies and discusses the potential benefits of the appropriate process for triboelectric platforms.Given its unique strength,which includes a diverse material selection and a simple working mechanism,the triboelectric platform can use a variety of manufacturing technologies and the process can be optimized as needed.Numerous research groups have clearly demonstrated the triboelectric platform's advantages.As a result,using appropriate manufacturing processes can accelerate the technological advancement of triboelectric platforms in a variety of research and industrial fields by allowing them to move beyond the lab-scale fabrication stage.
基金supported by the Korea Institute of Science and Technology(KIST)Institutional Program(Project No.2E32501-23-106)the National Research Foundation of Korea(NRF)grant funded by the Korea government(the Ministry of Science,ICT,MSIT)(RS-2022-00165524)+2 种基金the development of technologies for electroceuticals of National Research Foundation(NRF)funded by the Korean government(MSIT)(RS-2023-00220534)ICT Creative Consilience program through the Institute of Information&Communications Technology Planning&Evaluation(IITP)grant funded by the Korea government(MSIT)(IITP-2024-2020-0-01819)Start up Pioneering in Research and Innovation(SPRINT)through the Commercialization Promotion Agency for R&D Outcomes(COMPA)grant funded by the Korea government(Ministry of Science and ICT)(1711198921).
文摘Soft robots have partially or entirely provided versatile opportunities for issues or roles that cannot be addressed by conventional machine robots,although most studies are limited to designs,controls,or physical/mechanical motions.Here,we present a transformable,reconfigurable robotic platform created by the integration of magnetically responsive soft composite matrices with deformable multifunctional electronics.Magnetic compounds engineered to undergo phase transition at a low temperature can readily achieve reversible magnetization and conduct various changes of motions and shapes.Thin and flexible electronic system designed with mechanical dynamics does not interfere with movements of the soft electronic robot,and the performances of wireless circuit,sensors,and devices are independent of a variety of activities,all of which are verified by theoretical studies.Demonstration of navigations and electronic operations in an artificial track highlights the potential of the integrated soft robot for on-demand,environments-responsive movements/metamorphoses,and optoelectrical detection and stimulation.Further improvements to a miniaturized,sophisticated system with material options enable in situ monitoring and treatment in envisioned areas such as biomedical implants.
基金Ministry of Trade,Industry and Energy,Grant/Award Numbers:20017439,20021915National Research Foundation of Korea,Grant/Award Number:2019R1A2C1087653。
文摘Organometal halide perovskites are promising semiconducting materials for photodetectors because of their favorable optoelectrical properties.Although nanoscale perovskite materials such as quantum dots(QDs)show novel behavior,they have intrinsic stability issues.In this study,an effectively silane barrier-capped quantum dot(QD@APDEMS)is thinly applied onto a bulk perovskite photosensitive layer for use in photodetectors.QD@APDEMS is synthesized with a silane ligand with hydrophobic CH_(3)-terminal groups,resulting in excellent dispersibility and durability to enable effective coating.The introduction of the QD@APDEMS layer results in the formation of a lowdefect perovskite film with enlarged grains.This is attributed to the grain boundary interconnection effect via interaction between the functional groups of QD@APDEMS and uncoordinated Pb^(2+)in grain boundaries.By passivating the grain boundaries,where various trap sites are distributed,hole chargecarrier injection and shunt leakage can be suppressed.Also,from the energy point of view,the deep highest occupied molecular orbital(HOMO)level of QD@APDEMS can work as a hole charge injection barrier.Improved charge dynamics(generation,transfer,and recombination properties)and reduced trap density of QD@APDEMS are demonstrated.When this perovskite film is used in a photodetector,the device performance(especially the detectivity)stands out among existing perovskites evaluated for energy sensing device applications.
基金supported by the GRDC(Global Research Development Center)Cooperative Hub Program through the National Research Foundation of Korea(NRF),funded by the Ministry of Science and ICT(MSIT)(No.RS-2023-00257595).
文摘Liquid metals(LMs),because of their ability to remain in a liquid state at room temperature,render them highly versatile for applications in electronics,energy storage,medicine,and robotics.Among various LMs,Ga-based LMs exhibit minimal cytotoxicity,low viscosity,high thermal and electrical conductivities,and excellent wettability.Therefore,Ga-based LM composites(LMCs)have emerged as a recent research focus.Recent advancements have focused on novel fabrication techniques and applications spanning energy storage,flexible electronics,and biomedical devices.Particularly noteworthy are the developments in wearable sensors and electronic skins,which hold promise for healthcare monitoring and human-machine interfaces.Despite their potential,challenges,such as oxidative susceptibil-ity and biocompatibility,remain.Creating bio-based LMC materials is a promising approach to address these issues while exploring new avenues to optimize LMC performance and broaden its application domains.This review provides a concise overview of the recent trends in LMC research,highlights their transformative impacts,and outlines key directions for future investigation and development.
基金supported by the National Research Foundation of Korea(NRF)grant funded by the Korean government(MSIT)(RS-2024-00340074,RS-2024-00409901,2022M3I3A1081901,and RS-2024-00413272)。
文摘The harsh corrosive environment and sluggish oxygen evolution reaction(OER)kinetics at the anode of proton exchange membrane water electrolysis(PEMWE)cells warrant the use of excess Ir,thereby hindering large-scale industrialization.To mitigate these issues,the present study aimed at fabricating a robust low-Ir-loading electrode via one-pot synthesis for efficient PEMWE.The pre-electrode was first prepared by alloying through the co-electrodeposition of Ir and Co,followed by the fabrication of Ir–Co oxide(Co-incorporated Ir oxide)electrodes via electrochemical dealloying.Two distinct dealloying techniques resulted in a modified valence state of Ir,and the effects of Co incorporation on the activity and stability of the OER catalysts were clarified using density functional theory(DFT)calculations,which offered theoretical insights into the reaction mechanism.While direct experimental validation of the oxygen evolution mechanism remains challenging under the current conditions,DFT-based theoretical modeling provided valuable perspectives on how Co incorporation could influence key steps in oxygen evolution catalysis.The Ir–Co oxide electrode with a selectively modulated valence state showed impressive performance with an overpotential of 258 mV at 10 mA cm^(−2),a low Tafel slope of 29.4 mV dec^(−1),and stability for 100 h at 100 mA cm^(−2)in the OER,in addition to a low overpotential of 16 mV at−10 mA cm^(−2)and high stability for 24 h in the hydrogen evolution reaction.The PEMWE cell equipped with the bifunctional Ir–Co oxide electrode as the anode and cathode exhibited outstanding performance(11.4 A cm^(−2)at 2.3 Vcell)despite having a low noble-metal content of 0.4 mgNM cm^(−2).
基金supported by the Global Research Development Center(GRDC)Cooperative Hub Program through the National Research Foundation of Korea(NRF)funded by the Ministry of Science and ICT(MSIT)(No.RS-202300257595)。
文摘The advancement of wireless technologies has increased the global demand for ubiquitous connectivity.However,this surge has increased electromagnetic pollution.This study introduces a composite comprising a polymer matrix(polydimethylsiloxane,PDMS)and a magnetic filler(carbonyl iron powder,CIP)to effectively absorb electromagnetic waves(EMW)and suppress electromagnetic noise,while exhibiting good mechanical properties.Eutectic gallium–indium(EGa In)liquid metal(LM)was introduced to improve the insulating properties of magnetic fillers.A core–shell structure was obtained by coating the CIP particles with EGa In,thereby combining magnetic and dielectric materials to enhance EMW absorption.The fluid characteristics of the LM improved the mechanical properties,whereas its electrical conductivity enhanced interfacial polarization loss,thereby augmenting the dielectric loss value of the composites.Moreover,the application of mechanical strain enhanced the EMW absorption of the LM/CIP/PDMS composites due to the formation of a conductive LM network.
基金supported by the U.S.Department of Energy’s Office of Energy Efficiency and Renewable Energy(EERE)under the Advanced Manufacturing Office Award Number DE-EE0007897。
文摘In secondary Al-Si based alloys,microalloying with Mn and Cr can modify harmful platelet-type Alx Fey Siz intermetallic phases to less detrimentalα-Alx(Fe,Mn,Cr)_(y)Siz phase(script or polygonal morphologies).However,theα-Alx(Fe,Mn,Cr)_(y)Siz phase morphology,phase composition and the addition of Fecorrecting elements can be influenced by solidification conditions.Therefore,this research is aimed to highlight the morphological evolution and mechanisms ofα-Alx(Fe,Mn,Cr)_(y)Si_(z)phase in a Cr added Al-9%Si-1%Fe-0.2%Cr(all weight percentage thereafter,unless otherwise stated)alloy with varying Mn concentrations(0.25%,0.5%,and 0.8%).Microstructure evolution of Fe intermetallic phases is investi-gated under different casting conditions using a wedge-shaped die,Cu-chill block and melt quenching experiments.Thermodynamic simulations have been performed using CALculation of PHAse Diagrams(CALPHAD)method and compared with the experimental results for phase composition and formation temperatures ofα-Alx(Fe,Mn,Cr)_(y)Siz phase.The results indicated that for 0.25Mn-0.2Cr addition to Al-9Si-1Fe alloy,compact morphology containing polygonal phases are formed in Cu-chill casting,while the wedge castings predominantly show a mixed structure with platelets and script type morphologies.Tensile tests revealed a higher elongation value of 6.6%for mixed structure with platelet and script phases,which is decreased to 4.2%for polygonal phases in Al-9Si-1Fe-0.2Cr-0.25Mn alloy.This study highlights the importance of solidification conditions on morphologies of Fe-intermetallic phases and the mechanical properties by comparing selected literature relevant to high pressure die-casting process.
基金supported by the National Research Foundation of Korea(NRF)grant funded by the Korea government(MSIT)(No.2021R1C1C2006535)supported by the Korea Basic Science Institute(National Research Facilities and Equipment Center)grant funded by the Korea government(MSIT)(No.RS-2024-00403164)supported by the National Research Foundation of Korea grant funded by the Korea government,Ministry of Science and ICT(Development of Nanofiber Yarn Based Compound Sensor as a Comprehensive Wearable Healthcare Solution)(Grant No.RS-2024-00357296).
文摘The crystallization of ionic crystals has traditionally been explained by Gibbs's classical nucleation theory.However,recent observations of intermediate phases during nucleation suggest that the process may be more complex,necessitating new theoretical frameworks,though key empirical evidence remains elusive.In this study,we used microdroplets to investigate the crystallization of sodium halides(NaCl,NaBr,and NaI)under homogeneous nucleation conditions across a wide range of supersaturations.In the evaporating droplet,NaCl follows the classical nucleation pathway,whereas NaBr and NaI exhibit the formation of an intermediate phase prior to the nucleation of anhydrous and hydrous single crystals,respectively.Optical and computational analyses indicate that these intermediate phases are liquid crystal phases composed of contact ion pairs.These findings establish a new theoretical framework for crystal nucleation and growth and offer methods to control nucleation pathways,enabling us to achieve desired crystals regardless of specific conditions.
文摘The authors regret the following changes to the paper:1.The following author is added to this article:Agnieszka Chmielewska-Wysockaa 2.Section 2.1:●“An aqueous binder”should be changed to“A solvent binder”.●Replace“a composition of ethylene glycol monobutyl ether and ethylene glycol”by“50% binder saturation”.
基金supported by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MSIT) (project number RS-2024-00340542)supported in part (to B.J.S.) by the Intramural Fund of National Institute of Alcohol Abuse and Alcoholismsupported by the 2022 research grant from the Korean Society of Ginseng
文摘Metabolic dysfunction-associated fatty liver disease(MASLD)and alcohol-associated liver disease(ALD)are prevalent chronic liver diseases that can progress to steatohepatitis,fibrosis,cirrhosis,and ultimately liver failure.Here,we demonstrated that oral administration of GNVs provided substantial protection against liver injury and fibrosis in MASLD and ALD mouse models.In a Western-style high-fat diet-induced MASLD model and a chronic binge alcohol-induced ALD model,GNVs treatment significantly reduced gut leakiness by restoring intestinal junctional complex proteins and rebalancing the gut microbiome.GNVs attenuated hepatic lipid accumulation,oxidative stress and fibrogenicmarkers.GNV treatment downregulated the fibrosis-associated tissue inhibitor of metalloproteinase-2(TIMP2)pathway in hepatic stellate cells,which is linked to enhanced matrix degradation and reduced fibrogenesis.GNVs prevent MASLD-and ALD-associated gut barrier dysfunction and liver fibrosis through modulation of the gut-liver axis and the TIMP2 pathway.Edible GNVs represent a novel,multifaceted therapeutic strategy for managing chronic liver diseases.
基金supported by the Basic Science Research Program through the National Research Foundation of Korea(NRF),funded by the Ministry of Education(RS-202300243390 and 2020R1A5A1018052)supported by the Basic Science Research Program through the National Research Foundation of Korea,funded by the Ministry of Education(2022R1A3B1078163)supported by the Technology Innovation Program(Publicprivate joint investment semiconductor R&D program[K-CHIPS])to foster high-quality human resources(RS-2023-00235484)funded by the Ministry of Trade,Industry&Energy(MOTIE,Korea)(1415187770)。
文摘This study demonstrates the fabrication of mesoporous tungsten trioxide(WO_(3))-decorated flexible polyimide(PI)electrodes for the highly sensitive detection of catechol(CC)and hydroquinone(HQ),two environmental pollutants.Organic-inorganic composite dots are formed on flexible PI electrodes using evaporation-induced self-assembly(EISA)and electrospray methods.The EISA process is induced by a temperature gradient during electrospray,and the heated substrate partially decomposes the organic parts etched by O_(2) plasma,creating mesoporous structures.Differential pulse voltammetry and cyclic voltammetry demonstrate a linear correlation between analyte concentration and the electrochemical response.Computational studies support the spontaneous adsorption of CC and HQ molecules on model WO_(3) surfaces.The proposed sensor shows high sensitivity,a wide linear range,and a low detection limit for both individual and simultaneous determination of CC and HQ.Real sample analysis on river water confirms practical applicability.The WO_(3)-decorated PI electrode presents an efficient and reliable approach for detecting these pollutants,contributing to environmental safety measures.
基金Financial support for this work by the National Research Foundation of Korea(2022R1F1A1074682,2022R1A4A1031687)Korea University,and the KU-KIST Research Fund.
文摘The advancement in catalysis techniques for sustainable environmental applications,particularly an alternative to the current Haber-Bosch process for NH_(3),has recently gained widespread attention.Although photocatalytic conversion of N_(2) to NH_(3) using solar energy is an eco-friendly method,it has the limitation of low quantum yield.Recently,2D Bi-based photocatalysts which exhibit higher visible light absorption than TiO_(2) and higher stability than MXene have been an active research topic,and their performance can be enhanced through improved visible light absorption properties by incorporating plasmonic gold nanoparticles while nitrogen adsorption could be enhanced through oxygen vacancy(OV)processes.In the present study,we explore the application of 2D nanosized Bi_(2)O_(3–x) and gold nanoparticles for visible light photo generation of NH_(3).HRTEM and XPS reveal that the formation of AuNP and nano-sized Bi_(2)O_(3–x) in AuNP/Bi_(2)O_(3–x) heterozygote structure promotes the charge carrier mobility and charge transport at the interface,resulting in a 2.6-fold increase in the photocatalytic activity compared to micro-sized Bi_(2)O_(3–x) with AuNP.The improved photocatalytic performance can be ascribed to significant enhancement of visible light absorption by plasmonic nanoparticles,fast charge transport and mobility(due to sheet morphology)and the N_(2) activation by OV in AuNP/Bi_(2)O_(3–x) heterozygote.Through a systematic experimental investigation involving catalysts,concentration,pH,and scavengers,the highest photocatalytic performance was achieved with the heterozygote structures of AuNP/n-Bi_(2)O_(3–x) under optimized conditions,yielding 432.5μmol gcat^(-1) h^(-1) of NH_(3).
基金supported by the Next Generation Engineering Researcher Program of National Research Foundation of Korea(NRF)funded by the Ministry of Science and ICT(2017H1D8A2031138).
文摘Sustainable transformation and efficient utilization of biomasses and their derived materials are environ-mentally as well as economically compliant strategies.Biomass seaweed-derived nitrogen self-doped porous carbon with tailored surface area and pore structures are prepared through carb on izatio n and activation.The in fluence of carb on ization temperature on morphology,surface area,and heteroatom dopants are investigated to optimize sodium-ion storage capability.Seaweed-derived nitrogen selfdoped activated carbon(SAC)as anode materials for sodium-ion batteries exhibits remarkable reversible capacity of 303/192 mAh g^(-1) after 100/500 cycles at current densities of 100/200 mA g^(-1) respectively,and a good rate capability.The interconnected and porous conducting nature along with the heteroatom dopant role in creating defective sites and charge stabilization are favorable for ion storage and diffusion and electron transport,indicating the electrodes can offer improved electrochemical performances.In addition,post-mortem analysis of the cycled carbon electrodes through ex-situ tools demonstrates the sodium-ion storage mechanism.
文摘This paper summarizes the melting and casting processes for magnesium alloys.It also reviews the historical development of magnesium castings and their structural uses in the western world since 1921 when Dow began producing magnesium pistons.Magnesium casting technology was well developed during and after World War II,both in gravity sand and permanent mold casting as well as high-pressure die casting,for aerospace,defense and automotive applications.In the last 20 years,most of the development has been focused on thin-wall die casting applications in the automotive industry,taking advantages of the excellent castability of modern magnesium alloys.Recently,the continued expansion of magnesium casting applications into automotive,defense,aerospace,electronics and power tools has led to the diversification of casting processes into vacuum die casting,low-pressure die casting,squeeze casting,lost foam casting,ablation casting as well as semi-solid casting.This paper will also review the historical,current and potential structural use of magnesium with a focus on automotive applications.The technical challenges of magnesium structural applications are also discussed.Increasing worldwide energy demand,environment protection and government regulations will stimulate more applications of lightweight magnesium castings in the next few decades.The development of use of Integrated Computational Materials Engineering(ICME)tools will accelerate the applications of magnesium castings in structural applications.
基金the financial support from the United States National Science Foundation and Department of Energy。
文摘As the lightest structural metal and one of the most abundant metallic elements on earth, magnesium(Mg) has been used as an "industrial metal" for lightweighting in the transportation and electronics industries, in addition to other traditional applications in aluminum alloying,steel desulfurization and protective anodes. In recent years, research has shown significant potential for Mg to become a "technology metal"in a variety of new applications from energy storage/battery to biomedical products. However, global Mg production has shown steady but moderate growth in the last three decades. Mg applications as an industry metal are still limited due to some sustainability concerns of primary Mg production, as well as a number of technical issues related to the structural and corrosion performance of commercial Mg alloys.New Mg applications as an industrial or technology metal face tremendous technical challenges, which have been reflected in the intensified global research efforts in the last twenty years. This paper will review some past and present applications, and discuss future opportunities and challenges for Mg research and applications for the global Mg community.
基金partially funded by the United States Army Research Laboratory (ARL)Terves LLC。
文摘Mg-rare earth(RE)based systems provide several important commercial alloys and many alloy development opportunities for high strength applications,especially in aerospace and defense industries.The phase diagrams,microstructure,and strengthening mechanisms of these multicomponent systems are very complex and often not well understood in literature.We have calculated phase diagrams of important binary,ternary,and multicomponent RE-containing alloy systems,using CALPHAD(CALculation of PHAse Diagrams).Based on these phase diagrams,this paper offers a critical overview on phase equilibria and strengthening mechanisms in these alloy systems,including precipitation,long period stacking order(LPSO),and other intermetallic phases.This review also summarized several promising Mg-RE based cast alloys in comparison with commercial WE54 and WE43 alloys;and explored new strategies for future alloy development for high strength applications.It is pointed out that the combination of precipitation and LPSO phases can lead to superior strength and ductility in Mg-RE based cast alloys.The precipitates and LPSO phases can form a complex three-dimensional network that effectively impedes dislocation motion on the basal and non-basal planes.The LPSO phases can also prevent the coarsening of precipitates when they interact,thus providing good thermal stability at elevated temperatures.Future research is needed to determine how the combination of these two types of phases can be used in alloy design and industrial scale applications.
基金the National Science Foundation for supporting this work(Award CMMI-1432688)supported by Honda R&D Americas(Raymond,Ohio)。
文摘Porosity formation during solidification of aluminum-based alloys,due to hydrogen gas and alloy shrinkage,has been a major issue adversely affecting the performance of solidification products such as castings,welds or additively manufactured components.A three-dimensional cellular automaton(CA)model has been developed,for the first time,to couple the predictions of hydrogen-induced gas porosity and shrinkage porosity during solidification microstructure evolution of a binary Al-Si alloy.The CA simulation results are validated under various cooling rates by porosity measurements in an experimental wedge die casting using X-ray micro computed tomography(XMCT)technique.This validated porosity moel provides a critical link in integrated computation materials engineering(ICME)design and manufacturing of solidification products.
文摘Soft clays are problematic soils as they present high compressibility and low shear strength.There are several methods for improving in situ conditions of soft clays.Based on the geotechnical problem’s geometry and characteristics,the in situ conditions may require reinforcement to restrain instability and construction settlements.Granular columns reinforced by geosynthetic material are widely used to reduce settlements of embankments on soft clays.They also accelerate the consolidation rate by reducing the drainage path’s length and increasing the foundation soil’s bearing capacity.In this study,the performance of encased and layered granular columns in soft clay is investigated and discussed.The numerical results show the significance of geosynthetic stiffness and the column length on the embankment settlements.Furthermore,the results show that granular columns may play an important role in dissipating the excess pore water pressures and accelerating the consolidation settlements of embankments on soft clays.
基金This work is partially supported by the United States Automotive Materials Partnership(USAMP).
文摘ZE20(Mg-2Zn-0.2Ce)^2 is a new wrought magnesium alloy with improved extrudability and mechanical properties[1].To understand the constitutive behavior and workability of this new alloy,Gleeble thermomechanical testing has been carried out in this study.The flow stress behavior of ZE20 was investigated between 250℃–450℃ and 10^–3 s^–1–1.0 s^–1 in isothermal compression.Constitutive descriptions of the flow stress are provided.A new general approach at application of the extended Ludwik equation is demonstrated and was found to be more accurate than the hyperbolic sine Arrhenius model while having a similar number of model constants.Processing maps were developed based on the experimental results and are verified with microstructural investigation.A region of safe processing with non-basal texture and high activity of dynamic recrystallization(DRX)was found between 375℃ and 450℃,from 10^–1 s^–1 to 10^–2.5 s^–1.A region of potentially safe processing with annealing that is associated with shear band nucleation of non-basal grains was identified for temperatures as low as 300℃ and rates as high as 10^–1 s^–1.
基金the National Natural Science Foundation of China[grant number 51571080].
文摘In this study,an overcasting process followed by a low-temperature(200°C)annealing schedule has been developed to bond magnesium to aluminum alloys.ProCAST software was used to optimize the process parameters during the overcasting process which lead to Mg/Al bimetallic structures to be successfully produced without formation of Mg-Al intermetallic phases.Detailed microstructure evolution during annealing,including the formation and growth of Al-Mg interdiffusion layer and intermetallic phases(Al12Mg17 and Al3Mg2),was experimentally observed for the first time with direct evidence,and predicted using Calculation of Phase Diagrams(CALPHAD)modeling.Maximum interfacial strength was achieved when the interdiffusion layer formed at the Mg/Al interface reached a maximum thickness the without formation of brittle intermetallic compounds.The precise diffusion modeling of the Mg/Al interface provides an efficient way to optimize and control the interfacial microstructure of Mg/Al bimetallic structures for improved interfacial bonding.
