Control of the columnar to equiaxed transition(CET)is a major challenge in additively manufacturedβtitanium alloys.In this work,the promotion of CET was successfully achieved through in-situ fabrication of Ti-5Cu(wt....Control of the columnar to equiaxed transition(CET)is a major challenge in additively manufacturedβtitanium alloys.In this work,the promotion of CET was successfully achieved through in-situ fabrication of Ti-5Cu(wt.%)alloys with additions of 5,15,and 25 wt.%Nb using elemental Ti,Cu,and Nb powders by employing laser powder bed fusion(LPBF).The alloy containing 5 wt.%Nb consisted ofαlamellae,Ti2 Cu precipitates,and unmeltedβ-Nb inclusions,whereas the 25 wt.%Nb alloy consisted of equiaxedβgrains,ωprecipitates,and Ti2 Cu precipitates at the grain boundaries.In terms of mechanical proper-ties,despite the presence of Nb inclusions and liquation cracks in the 5 wt.%Nb alloy,it showed a yield strength of 1051±40 MPa and an elongation of 5.2%±1.3%.Both the strength and ductility decreased with increasing Nb content,e.g.,the 25 wt.%Nb alloy exhibited a yield strength of 808±53 MPa and an elongation of 1.6%±0.2%.As the Nb content increased from 5 to 25 wt.%,the Young’s modulus decreased from 110 to 65 GPa.The 25 wt.%Nb alloy showed a high ratio of hardness to Young’s mod-ulus(H/E)and yield pressure(H3/E2).However,due to its brittle nature,the material manifested high wear rates.These findings provide a basis for the future development of novel low-modulus isotropicβ-titanium alloys using LPBF.展开更多
The microstructural evolution,mechanical properties,and corrosion behavior of Ti-12Ni(wt.%)specimens produced by laser powder bed fusion(LPBF)using various volume energy density(VED)processing parameter values were in...The microstructural evolution,mechanical properties,and corrosion behavior of Ti-12Ni(wt.%)specimens produced by laser powder bed fusion(LPBF)using various volume energy density(VED)processing parameter values were investigated.The results showed that the alloy prepared at a low VED of 67 J/mm^(3)consisted of near-βgrains.At a VED of 133 J/mm^(3),the alloy exhibited coarse primary Ti2Ni and fine eutectoid structure.This eutectoid structure consisted ofαlaths and two types of nanoscale Ti2Ni,one in the form of short rods and the other with a spherical morphology.Further increase of the VED to 267 J/mm^(3)led to coarsening of the eutectoid structure.The dispersed Ti2Ni nanoparticles exhibited a significant strengthening effect.The alloy produced at a VED of 133 J/mm^(3)showed the greatest strength with a nanohardness of(7.8±0.1)GPa and a compressive strength of(1777±27)MPa.However,the presence of Ni segregation and holes produced by the LPBF processing adversely affected the corrosion resistance of the alloy.展开更多
The tribological behavior of a Zr-based bulk metallic glass(BMG) was investigated using pin-on-disk sliding measurements in two different environments,i.e.,air and argon,against an yttria-stabilized zirconia counter...The tribological behavior of a Zr-based bulk metallic glass(BMG) was investigated using pin-on-disk sliding measurements in two different environments,i.e.,air and argon,against an yttria-stabilized zirconia counterface.It was found that the wear of the Zr-based BMG was reduced by more than 45% due to the removal of oxygen from the test environment at two different loads,i.e.,16 N and 23 N.The wear pins were examined using X-ray diffractometry,differential scanning calorimetry,scanning electron microscopy and optical surface profilometry.A number of abrasive particles and grooves presented on the worn surface of the pin tested in air,while a relatively smooth worn surface was observed in the specimens tested in argon.The wear mechanism of the pin worn in air was dominated by abrasive wear compared with an adhesive wear controlled process in the tests performed in argon.展开更多
The excessive emission of CO_(2) has caused many environmental issues and is severely threatening the eco-system.CO_(2) electroreduction reaction(CO_(2) RR) that driven by sustainable power is an ideal route for reali...The excessive emission of CO_(2) has caused many environmental issues and is severely threatening the eco-system.CO_(2) electroreduction reaction(CO_(2) RR) that driven by sustainable power is an ideal route for realizing the net reduction of CO_(2) and carbon recycle.Developing efficient electrocatalysts with low cost and high performance is critical for the wide applications of CO_(2) RR electrolysis.Among the various explored CO_(2) RR catalysts,non-noble metal(NNM)-based nanomaterials have drawn increasing attentions due to the remarkable performance and low cost.In this mini-review,the recent advances of NNM-based CO_(2) RR catalysts are summarized,and the catalysts are classified based on their corresponding reduction products.The preparation strategies for engineering the electrocatalysts are introduced,and the relevant CO_(2) RR mechanisms are discussed in detail.Finally,the current challenges in CO_(2) RR research are presented,and some perspectives are proposed for the future development of CO_(2) RR technology.This mini-review introduces the recent advances and frontiers of NNM-based CO_(2) RR catalysts,which should shed light on the further exploration of efficient CO_(2) RR electrocatalysts.展开更多
Snow depth and sea ice thickness were observed applying an ice mass balance buoy(IMB)in the drifting ice station Tara during the International Polar Year in 2007.Detailed in situ observations on meteorological variabl...Snow depth and sea ice thickness were observed applying an ice mass balance buoy(IMB)in the drifting ice station Tara during the International Polar Year in 2007.Detailed in situ observations on meteorological variables and surface fluxes were taken during May to August.For this study,the operational analyses and short-term forecasts from two numerical weather prediction(NWP)models(ECMWF and HIRLAM)were extracted for the Tara drift trajectory.We compared the IMB,meteorological and surface flux observations against the NWP products,also applying a one-dimensional thermodynamic sea ice model(HIGHTSI)to calculate the snow and ice mass balance and its sensitivity to atmospheric forcing.The modelled snow depth time series,controlled by NWP-based precipitation,was in line with the observed one.HIGHTSI reproduced well the snowmelt onset,the progress of the melt,and the first date of snow-free conditions.HIGHTSI performed well also in the late August freezing season.Challenges remain to model the“false bottom”observed during the melting season.The evolution of the vertical temperature profiles in snow and ice was better simulated when the model was forced by in situ observations instead of NWP results.During the melting period,the nonlinear ice temperature profile was successfully modelled with both forcing options.During spring and the melting season,total sea ice mass balance was most sensitive to uncertainties in NWP results for the downward longwave radiation,followed by the downward shortwave radiation,air temperature,and wind speed.展开更多
Additively manufactured (AM) biodegradable zinc (Zn) alloys constitute an important branch of orthopedic implants because of their moderate degradation properties and bone-mimicking mechanical properties. In this pape...Additively manufactured (AM) biodegradable zinc (Zn) alloys constitute an important branch of orthopedic implants because of their moderate degradation properties and bone-mimicking mechanical properties. In this paper, the microstructural evolution and corrosion mechanisms of zinc-copper (Zn-Cu) alloys prepared by the laser-powder-bed-fusion (L-PBF) additive manufacturing method were investigated. Alloying with Cu significantly increases the ultimate tensile strength (UTS) of unalloyed Zn, but the UTS and ductility of unalloyed Zn and Zn-2Cu decrease with increasing laser energy density. Unalloyed Zn has a dendritic microstructure, while Zn-2Cu alloy has a peritectic microstructure. The formation of round peritectic grains is due to the low-temperature gradient of unalloyed Zn during the AM. The Zn-2Cu samples exhibited higher corrosion rates, addressing the problem of slow degradation of unalloyed Zn. The grain size distribution influences the corrosion behavior of the material. It enhances the corrosion rates of materials with fine grains in a non-passivating environment. However, the 100% extracts of Zn-2Cu samples exhibited greater values of cellular activity compared to unalloyed Zn samples, thus confirming their better cytocompatibility. This work demonstrates the great potential to design and modulate biodegradable Zn alloys to fulfill clinical needs by using AM technology.展开更多
The present study investigated the microstructure,nanomechanics,and corrosion behavior of AlCoCuFeNi high entropy alloys fabricated by selective laser melting(SLM)and laser metal deposition(LMD).The microstructure of ...The present study investigated the microstructure,nanomechanics,and corrosion behavior of AlCoCuFeNi high entropy alloys fabricated by selective laser melting(SLM)and laser metal deposition(LMD).The microstructure of SLM-processed specimens was mainly composed of columnar-grained BCC matrix(^90μm in width)and Cu-rich twinned FCC phase.The columnar grains grew epitaxially along the building direction and exhibited a strong{001}texture.In comparison,a coarse columnar-grained BCC matrix(^150μm in width)with a stronger<001>texture,rod-like B2 precipitates,and large core-shell structured FCC phases were formed in the LMD-processed specimens due to the higher heat accumulation effect.Consequently,the LMD-processed specimens showed a lower hardness,wear resistance,and corrosion resistance,but higher creep resistance and reduced Young's modulus than the SLM-processed specimens.Hot cracks occurred in both types of specimens,which could not be completely suppressed due to Cu segregation.展开更多
Corn leaf and corn stalk were pretreated with only hot water and 0.1% sulfuric acid at 160℃ or 200℃, respectively. For hot water pretreatment, the pH of corn stalk hydrolysate decreased more rapidly than that of cor...Corn leaf and corn stalk were pretreated with only hot water and 0.1% sulfuric acid at 160℃ or 200℃, respectively. For hot water pretreatment, the pH of corn stalk hydrolysate decreased more rapidly than that of corn leaf as the reaction time increased. On the contrary, the pH of corn leaf hydrolysate increased more than that of corn stalk with diluted acid addition. Increasing temperature enhanced the xylose dissolution rate and increased cellulose digestibility. Compared with hot water, 0.1% sulfuric acid addition improved the xylan removal and the enzymatic hydrolysis of both corn leaf and corn stalk residue. Much less xylan must be removed to achieve the same cellulose digestibility for the corn leaf as that for the corn stalk; 55% digestibility was obtained when only 32% xylan was removed from corn leaf, whereas corn stalk required removal of about 50% of the xylan to achieve the same di- gestibility. Overall, the descending order of enzymatic digestibility was: dilute acid hydrolysate of corn leaf > dilute acid hydrolysate of corn stalk > water-only hydrolysate of corn leaf > water-only hydrolysate of corn stalk. Finally, one separate pretreatment strategy was developed to transfer corn leaf and corn stalk to fermentable sugars for fur- ther bioenergy production.展开更多
A near-infrared(NIR)tomography system with spectrally-encoded sources in two wavelength bands was built to quantify the temporal oxyhemoglobin and deoxyhemoglobin contrast in breast tissue at a 20 Hz bandwidth.The sys...A near-infrared(NIR)tomography system with spectrally-encoded sources in two wavelength bands was built to quantify the temporal oxyhemoglobin and deoxyhemoglobin contrast in breast tissue at a 20 Hz bandwidth.The system was integrated into a 3T magnetic resonance(MR)imaging system through a customized breast coil interface for simultaneous optical and MRI acquisition.In this configuration,the MR images provide breast tissue structural information for NIR spectroscopy of adipose andfibro-glandular tissue in breast.Spectral characterization performance of the NIR system was verified through dynamic phantom experiments.Normal human subjects were imaged withfinger pulse oximeter(PO)plethysmogram synchronized to the NIR system to provide a frequency-locked reference.Both the raw data from the NIR system and the recovered absorption coefficients of the breast at two wavelengths showed the same frequency of about 1.3 Hz as the PO output.The frequency lock-in approach provided a practical platform for MR-localized recovery of small pulsatile variations of oxyhemoglobin and deoxyhemoglobin in the breast,which are related to the heartbeat and vascular resistance of the tissue.展开更多
Single crystal Ni-rich cathode materials(SCNCM)are a good supplement in the market of nickel-based materials due to their safety and excellent electrochemical performance.However,the challenges of cation mixing,phase ...Single crystal Ni-rich cathode materials(SCNCM)are a good supplement in the market of nickel-based materials due to their safety and excellent electrochemical performance.However,the challenges of cation mixing,phase change during charge/discharge,and low thermal stability remain unresolved in single crystal particles.To address these issues,SCNCM are rationally modified by incorporating transition metal(TM)oxides,and the influence of metal ions with different valence states on the electrochemical properties of SCNCM is methodically explored through experimental results and theoretical calculations.Enhanced structural stability is demonstrated in SCNCM after the modifications,and the degree of improvement in the matrix materials varies depending on the valence state of doped TM ions.The highest structural stability is found in WO_(3)-modified SCNCM,due to the smaller effective ion radii,higher electro-negativity,stronger W-O bond,and efficient suppression of oxygen vacancy generation.As a result,WO_(3)-modified SCNCM have outstanding cycle performance,with a capacity retention rate of90.2%after 200 cycles.This study provides an insight into the design of advanced SCNCM with enhanced reversibility and cyclability.展开更多
Enabling highly reversible sodium(Na) metal anodes in a polymer electrolyte(PE) system is critical for realizing next-generation batteries with lower cost,higher energy,and improved safety.However,the uneven Na deposi...Enabling highly reversible sodium(Na) metal anodes in a polymer electrolyte(PE) system is critical for realizing next-generation batteries with lower cost,higher energy,and improved safety.However,the uneven Na deposition and high Na/PE interphase resistance lead to poor reversibility and short cycle life of Na metal anodes.To tackle these problems,here a variety of metal nanoparticles(M-np,M=Al,Sn,In or Au) are deposited onto copper(Cu) foils to synthesize binder-free M-np@Cu substrates for Na plating/stripping.Notably,the Au-np@Cu substrate provides abundant preferential nucleation/growth sites,decreasing Na nucleation barrier and thus promoting uniform Na deposition.Accordingly,stable Na metal anodes are achieved with high reversible capacities,long cycle life,and high usage of Na.With the Au-np@Cu/Na anode and PE,the full cell using a commercial bulk sulfur cathode exhibits a reversible capacity of>400 mAh g^(-1) with near-100% Coulombic efficiency over 200 cycles.展开更多
Magnesium(Mg)and its alloys have similar densities and elastic moduli to natural bone,making them an excellent choice for orthopedic implants.However,Mg alloys are prone to electrochemical corrosion,which often leads ...Magnesium(Mg)and its alloys have similar densities and elastic moduli to natural bone,making them an excellent choice for orthopedic implants.However,Mg alloys are prone to electrochemical corrosion,which often leads to implant failure and hinders the further development of Mg alloys due to bacterial infection around the implant.This work aims to enhance the corrosion resistance of Mg alloys,and provide theoretical guidance for solving the problem that Mg-based orthopedic implants are susceptible to bacterial infection and,thus,implant failure.In order to solve the corrosion problem,the Mg alloy AZ91D was used as the substrate,and a compact and uniform MgAlCu-layered double hydroxide(Mg(Cu)-LDH)was prepared on its surface using a hydrothermal method.The Mg(Cu)-LDH provides a barrier between the AZ91D and corrosive liquid,which effectively protects the Mg substrate from being corroded.The Mg(Cu)-LDH shows great cell viability for MC3T3-E1 cells.The Cu^(2+)and Mg^(2+) in the coating also endow the Mg(Cu)-LDH/AZ91D with antibacterial properties,showing strong antibacterial effects on both E.coli and S.aureus with antibacterial rates over 85%.Finally,in vivo results indicated that a LDH-coated implant had no systemic effects on the hearts,livers,spleens,lungs or kidneys.It was shown that 4 weeks after surgery the ratio of bone volume to tissue volume(BV/TV)of the LDH implant was 24%,which was 1.7 times that observed for AZ91D.展开更多
A good Ti-based joint implant should prevent stress shielding and achieve good bioactivity and anti-infection performance.To meet these requirements,the low-elastic-modulus alloy—Ti–35Nb–2Ta–3Zr—was used as the s...A good Ti-based joint implant should prevent stress shielding and achieve good bioactivity and anti-infection performance.To meet these requirements,the low-elastic-modulus alloy—Ti–35Nb–2Ta–3Zr—was used as the substrate,and functional coatings that contained bioceramics and Ag ions were prepared for coating on TiO_(2)nanotubes(diameter:(80±20)nm and(150±40)nm)using anodization,deposition,and spin-coating methods.The effects of the bioceramics(nano-β-tricalcium phosphate,microhydroxyapatite(micro-HA),and meso-CaSiO_(3))and Ag nanoparticles(size:(50±20)nm)on the antibacterial activity and the tribocorrosion,corrosion,and early in vitro osteogenic behaviors of the nanotubes were investigated.The tribocorrosion and corrosion results showed that the wear rate and corrosive rate were highly dependent on the features of the nanotube surface.Micro-HA showed great wear resistance with a wear rate of(1.26±0.06)×10^(−3)mm^(3)/(N·m)due to adhesive and abrasivewear.Meso-CaSiO_(3)showed enhanced cell adhesion,proliferation,and alkaline phosphatase activity.The coatings that contained nano-Ag exhibited good antibacterial activity with an antibacterial rate of≥89.5%against Escherichia coli.These findings indicate that hybrid coatings may have the potential to accelerate osteogenesis.展开更多
stract Facilitating an appropriate immune response is crucial for promoting bone tissue regeneration upon biomaterial implantation.In this study,the Mg^(2+)-containing nanostructures on the surface of Ti-1.25Mg alloy ...stract Facilitating an appropriate immune response is crucial for promoting bone tissue regeneration upon biomaterial implantation.In this study,the Mg^(2+)-containing nanostructures on the surface of Ti-1.25Mg alloy were prepared by a one-step hydrothermal reaction method via regulating pH value to enhance the immunomodulatory osteogenic properties of Ti-Mg alloys.In neutral(HT7)or alkaline(HT9)hydrothermal treatment(HT)solution,the size of MgTiO_(3)nanostructures formed on the surface of Ti-1.25Mg alloy is smaller than that in acidic HT solution(HT5),and lamellar Mg(OH)_(2)nano-structures are found in HT7 and HT9.In addition,the sample surface has a lower roughness and higher wettability with increasing pH value.The Mg^(2+)-containing nanostructures on the Ti-1.25Mg alloy inhibited inflammatory response by promoting the polarization of M2 macrophages,thereby promoting osteogenesis in vitro.The micro-CT and histological assessment proved that the regeneration of bone defect was faster in HT7 than the Ti-1.25Mg in vivo.Mechanically,Mg^(2+)-containing nanostructures can mediate the immune response of macro-phages via upregulating integrinsα5β1 and inhibiting Toll-like receptors(TLR-4),subsequently inhibiting the NF-κB signaling pathway.Overall,osteoimmunity-regulating Mg^(2+)-containing nanostructures on Ti-1.25Mg present a promising biomaterial for bone repair.展开更多
Understanding lattice dynamics and thermal transport mechanisms in cubic hybrid organic–inorganic perovskites remain challenging due to strong anharmonicity and phase transitions.Here,we investigate the thermal trans...Understanding lattice dynamics and thermal transport mechanisms in cubic hybrid organic–inorganic perovskites remain challenging due to strong anharmonicity and phase transitions.Here,we investigate the thermal transport behavior in benchmark cubic hybrid perovskite FAPbI_(3)by coupling first principles-based anharmonic lattice dynamics with a linearized Wigner transport equation.Using the Temperature-Dependent Effective Potential(TDEP)method,we stabilize the negative soft modes,primarily dominated by organic FA+cations.Our calculations predict an ultra-low thermal conductivity of~0:63Wm^(-1)K^(-1)at 300 K,following a temperature dependence of T^(−0.740).Contrary to common assumptions,we find that the[PbI_(3)]^(1-)units,rather than FA^(+)cations,dominate thermal resistance.Furthermore,we demonstrate that anharmonic force constants are highly temperature-sensitive,relying on 0-K force constants significantly underestimates thermal conductivity.Our study not only elucidates the microscopic mechanisms governing thermal transport in FAPbI_(3)but also provides a robust framework for modeling heat conduction in hybrid organic-inorganic compounds.展开更多
2D transition metal carbides,carbonitrides,and nitrides known as MXenes possess high electrical conductivity,large redox active surface area,rich surface chemistry,and tunable structures.Benefiting from these exceptio...2D transition metal carbides,carbonitrides,and nitrides known as MXenes possess high electrical conductivity,large redox active surface area,rich surface chemistry,and tunable structures.Benefiting from these exceptional chemical and physical properties,the applications of MXenes for electrochemical energy storage and conversion have attracted increasing research interests around the world.Notably,the electrochemical performances of MXenes are directly dependent on their synthesis conditions,interfacial chemistries and structural configurations.In this review,we summarize the synthesis techniques of MXenes,as well as the recent advances in the interfacial structure design of MXene-based nanomaterials for electrochemical energy storage and conversion applications.Additionally,we provide an in-depth discussion on the relationship between interfacial structure and electrochemical performance from the perspectives of energy storage and electrocatalysis mechanisms.Finally,the challenges and insights for the future research of interfacial structure design of MXenes are outlined.展开更多
Color vision is used throughout medicine to interpret the health and status of tissue.Ionizing radiation used in radiation therapy produces broadband white light inside tissue through the Cherenkov effect,and this lig...Color vision is used throughout medicine to interpret the health and status of tissue.Ionizing radiation used in radiation therapy produces broadband white light inside tissue through the Cherenkov effect,and this light is attenuated by tissue features as it leaves the body.In this study,a novel time-gated three-channel camera was developed for the first time and was used to image color Cherenkov emission coming from patients during treatment.The spectral content was interpreted by comparison with imaging calibrated tissue phantoms.Color shades of Cherenkov emission in radiotherapy can be used to interpret tissue blood volume,oxygen saturation and major vessels within the body.展开更多
基金the National Natural Science Foun-dation of China(Grant Nos.12374022,U23A20540)the Natu-ral Science Foundation of Hunan Province for Distinguished Young Scholars(Grant No.2023JJ10075)+3 种基金the China Postdoctoral Science Foundation(Grant Nos.GZC20241335,2024MD753962)the YueLuShan Center Industrial Innovation(Grant No.2024YCII0106)the Scientific and Technological Project of Yunnan Precious Met-als Laboratory(Grant No.YPML-2023050247)the Central South University Research Programme of Advanced Interdisci-plinary Studies(Grant No.2023QYJC039).
文摘Control of the columnar to equiaxed transition(CET)is a major challenge in additively manufacturedβtitanium alloys.In this work,the promotion of CET was successfully achieved through in-situ fabrication of Ti-5Cu(wt.%)alloys with additions of 5,15,and 25 wt.%Nb using elemental Ti,Cu,and Nb powders by employing laser powder bed fusion(LPBF).The alloy containing 5 wt.%Nb consisted ofαlamellae,Ti2 Cu precipitates,and unmeltedβ-Nb inclusions,whereas the 25 wt.%Nb alloy consisted of equiaxedβgrains,ωprecipitates,and Ti2 Cu precipitates at the grain boundaries.In terms of mechanical proper-ties,despite the presence of Nb inclusions and liquation cracks in the 5 wt.%Nb alloy,it showed a yield strength of 1051±40 MPa and an elongation of 5.2%±1.3%.Both the strength and ductility decreased with increasing Nb content,e.g.,the 25 wt.%Nb alloy exhibited a yield strength of 808±53 MPa and an elongation of 1.6%±0.2%.As the Nb content increased from 5 to 25 wt.%,the Young’s modulus decreased from 110 to 65 GPa.The 25 wt.%Nb alloy showed a high ratio of hardness to Young’s mod-ulus(H/E)and yield pressure(H3/E2).However,due to its brittle nature,the material manifested high wear rates.These findings provide a basis for the future development of novel low-modulus isotropicβ-titanium alloys using LPBF.
基金supported by the National Natural Science Foundation of China(Nos.12374022,U23A20540)the Technological Base Project,China(No.JSHS2022206A001)+2 种基金the Natural Science Foundation of Hunan Province for Distinguished Young Scholars,China(No.2023JJ10075)the Scientific and Technological Project of Yunnan Precious Metals Laboratory,China(No.YPML-202305247)the Central South University Research Program of Advanced Interdisciplinary Studies,China(No.2023QYJC038).
文摘The microstructural evolution,mechanical properties,and corrosion behavior of Ti-12Ni(wt.%)specimens produced by laser powder bed fusion(LPBF)using various volume energy density(VED)processing parameter values were investigated.The results showed that the alloy prepared at a low VED of 67 J/mm^(3)consisted of near-βgrains.At a VED of 133 J/mm^(3),the alloy exhibited coarse primary Ti2Ni and fine eutectoid structure.This eutectoid structure consisted ofαlaths and two types of nanoscale Ti2Ni,one in the form of short rods and the other with a spherical morphology.Further increase of the VED to 267 J/mm^(3)led to coarsening of the eutectoid structure.The dispersed Ti2Ni nanoparticles exhibited a significant strengthening effect.The alloy produced at a VED of 133 J/mm^(3)showed the greatest strength with a nanohardness of(7.8±0.1)GPa and a compressive strength of(1777±27)MPa.However,the presence of Ni segregation and holes produced by the LPBF processing adversely affected the corrosion resistance of the alloy.
基金Project(DE-FG02-07ER46392) supported by U.S.Department of Energy,Office of Basic Energy ScienceProject(2011JQ002) supported by the Fundamental Research Funds for the Central Universities,ChinaProject supported by the Open-End Fund for the Valuable and Precision Instruments of Central South University,China
文摘The tribological behavior of a Zr-based bulk metallic glass(BMG) was investigated using pin-on-disk sliding measurements in two different environments,i.e.,air and argon,against an yttria-stabilized zirconia counterface.It was found that the wear of the Zr-based BMG was reduced by more than 45% due to the removal of oxygen from the test environment at two different loads,i.e.,16 N and 23 N.The wear pins were examined using X-ray diffractometry,differential scanning calorimetry,scanning electron microscopy and optical surface profilometry.A number of abrasive particles and grooves presented on the worn surface of the pin tested in air,while a relatively smooth worn surface was observed in the specimens tested in argon.The wear mechanism of the pin worn in air was dominated by abrasive wear compared with an adhesive wear controlled process in the tests performed in argon.
基金financially supported by the National Natural Science Foundation of China(Nos.52001227 and 51972224)the China Postdoctoral Science Foundation(No.2019M661014)。
文摘The excessive emission of CO_(2) has caused many environmental issues and is severely threatening the eco-system.CO_(2) electroreduction reaction(CO_(2) RR) that driven by sustainable power is an ideal route for realizing the net reduction of CO_(2) and carbon recycle.Developing efficient electrocatalysts with low cost and high performance is critical for the wide applications of CO_(2) RR electrolysis.Among the various explored CO_(2) RR catalysts,non-noble metal(NNM)-based nanomaterials have drawn increasing attentions due to the remarkable performance and low cost.In this mini-review,the recent advances of NNM-based CO_(2) RR catalysts are summarized,and the catalysts are classified based on their corresponding reduction products.The preparation strategies for engineering the electrocatalysts are introduced,and the relevant CO_(2) RR mechanisms are discussed in detail.Finally,the current challenges in CO_(2) RR research are presented,and some perspectives are proposed for the future development of CO_(2) RR technology.This mini-review introduces the recent advances and frontiers of NNM-based CO_(2) RR catalysts,which should shed light on the further exploration of efficient CO_(2) RR electrocatalysts.
基金This study was initialized during DAMOCLES project(Grant no.18509)which was funded by the 6th Framework Programme of the European Commission+2 种基金The initial data analysis was funded by the Research Council of Norway’s AMORA project(Grant no.#193592)The modelling work has been supported by the Academy of Finland(Contract 317999)The finalization of this work was supported by the European Union’s Horizon 2020 research and innovation programme(Grant no.727890–INTAROS).
文摘Snow depth and sea ice thickness were observed applying an ice mass balance buoy(IMB)in the drifting ice station Tara during the International Polar Year in 2007.Detailed in situ observations on meteorological variables and surface fluxes were taken during May to August.For this study,the operational analyses and short-term forecasts from two numerical weather prediction(NWP)models(ECMWF and HIRLAM)were extracted for the Tara drift trajectory.We compared the IMB,meteorological and surface flux observations against the NWP products,also applying a one-dimensional thermodynamic sea ice model(HIGHTSI)to calculate the snow and ice mass balance and its sensitivity to atmospheric forcing.The modelled snow depth time series,controlled by NWP-based precipitation,was in line with the observed one.HIGHTSI reproduced well the snowmelt onset,the progress of the melt,and the first date of snow-free conditions.HIGHTSI performed well also in the late August freezing season.Challenges remain to model the“false bottom”observed during the melting season.The evolution of the vertical temperature profiles in snow and ice was better simulated when the model was forced by in situ observations instead of NWP results.During the melting period,the nonlinear ice temperature profile was successfully modelled with both forcing options.During spring and the melting season,total sea ice mass balance was most sensitive to uncertainties in NWP results for the downward longwave radiation,followed by the downward shortwave radiation,air temperature,and wind speed.
基金financially supported by the National Natural Science Foundation of China(No.52071346)Key Research and Development Program of Hunan Province(No.2022SK2006)+5 种基金the Natural Science Foundation of Hunan Province(No.2023JJ40836)the Natural Science Foundation of Hunan Province for Distinguished Young Scholars(No.2023JJ10075)the Changsha Municipal Natural Science Foundation(No.kq2202417)the Central South University Research Program of Advanced Interdisciplinary Stud-ies(No.2023QYJC038)the Fundamental Research Fundsforthe Central Universities of Central South University(No.2021zzts0110)。
文摘Additively manufactured (AM) biodegradable zinc (Zn) alloys constitute an important branch of orthopedic implants because of their moderate degradation properties and bone-mimicking mechanical properties. In this paper, the microstructural evolution and corrosion mechanisms of zinc-copper (Zn-Cu) alloys prepared by the laser-powder-bed-fusion (L-PBF) additive manufacturing method were investigated. Alloying with Cu significantly increases the ultimate tensile strength (UTS) of unalloyed Zn, but the UTS and ductility of unalloyed Zn and Zn-2Cu decrease with increasing laser energy density. Unalloyed Zn has a dendritic microstructure, while Zn-2Cu alloy has a peritectic microstructure. The formation of round peritectic grains is due to the low-temperature gradient of unalloyed Zn during the AM. The Zn-2Cu samples exhibited higher corrosion rates, addressing the problem of slow degradation of unalloyed Zn. The grain size distribution influences the corrosion behavior of the material. It enhances the corrosion rates of materials with fine grains in a non-passivating environment. However, the 100% extracts of Zn-2Cu samples exhibited greater values of cellular activity compared to unalloyed Zn samples, thus confirming their better cytocompatibility. This work demonstrates the great potential to design and modulate biodegradable Zn alloys to fulfill clinical needs by using AM technology.
基金financially supported by the National Natural Science Foundation of China(Nos.52111530193 and 52020105013)the Key Research and Development Program of Hunan Province(No.2022SK2006)+1 种基金the Fundamental Research Funds for the Central University of Central South University(No.2021ZZTS0098)the HK Research Grants Council(ECS 25202719 and GRF 15227121)。
文摘The present study investigated the microstructure,nanomechanics,and corrosion behavior of AlCoCuFeNi high entropy alloys fabricated by selective laser melting(SLM)and laser metal deposition(LMD).The microstructure of SLM-processed specimens was mainly composed of columnar-grained BCC matrix(^90μm in width)and Cu-rich twinned FCC phase.The columnar grains grew epitaxially along the building direction and exhibited a strong{001}texture.In comparison,a coarse columnar-grained BCC matrix(^150μm in width)with a stronger<001>texture,rod-like B2 precipitates,and large core-shell structured FCC phases were formed in the LMD-processed specimens due to the higher heat accumulation effect.Consequently,the LMD-processed specimens showed a lower hardness,wear resistance,and corrosion resistance,but higher creep resistance and reduced Young's modulus than the SLM-processed specimens.Hot cracks occurred in both types of specimens,which could not be completely suppressed due to Cu segregation.
基金the National Natural Science Foundation of China (No.29976045).
文摘Corn leaf and corn stalk were pretreated with only hot water and 0.1% sulfuric acid at 160℃ or 200℃, respectively. For hot water pretreatment, the pH of corn stalk hydrolysate decreased more rapidly than that of corn leaf as the reaction time increased. On the contrary, the pH of corn leaf hydrolysate increased more than that of corn stalk with diluted acid addition. Increasing temperature enhanced the xylose dissolution rate and increased cellulose digestibility. Compared with hot water, 0.1% sulfuric acid addition improved the xylan removal and the enzymatic hydrolysis of both corn leaf and corn stalk residue. Much less xylan must be removed to achieve the same cellulose digestibility for the corn leaf as that for the corn stalk; 55% digestibility was obtained when only 32% xylan was removed from corn leaf, whereas corn stalk required removal of about 50% of the xylan to achieve the same di- gestibility. Overall, the descending order of enzymatic digestibility was: dilute acid hydrolysate of corn leaf > dilute acid hydrolysate of corn stalk > water-only hydrolysate of corn leaf > water-only hydrolysate of corn stalk. Finally, one separate pretreatment strategy was developed to transfer corn leaf and corn stalk to fermentable sugars for fur- ther bioenergy production.
基金We gratefully acknowledge National Institutes of Health(NIH)research grants R33CA100984,RO1CA069544,and P01CA080139.
文摘A near-infrared(NIR)tomography system with spectrally-encoded sources in two wavelength bands was built to quantify the temporal oxyhemoglobin and deoxyhemoglobin contrast in breast tissue at a 20 Hz bandwidth.The system was integrated into a 3T magnetic resonance(MR)imaging system through a customized breast coil interface for simultaneous optical and MRI acquisition.In this configuration,the MR images provide breast tissue structural information for NIR spectroscopy of adipose andfibro-glandular tissue in breast.Spectral characterization performance of the NIR system was verified through dynamic phantom experiments.Normal human subjects were imaged withfinger pulse oximeter(PO)plethysmogram synchronized to the NIR system to provide a frequency-locked reference.Both the raw data from the NIR system and the recovered absorption coefficients of the breast at two wavelengths showed the same frequency of about 1.3 Hz as the PO output.The frequency lock-in approach provided a practical platform for MR-localized recovery of small pulsatile variations of oxyhemoglobin and deoxyhemoglobin in the breast,which are related to the heartbeat and vascular resistance of the tissue.
基金financially supported by the National Natural Science Foundation of China,China(52004103,51974137,52274229,22350410378 and 52304328)the China Postdoctoral Science Foundation,China(2020M671361 and 2023M733189)+4 种基金the Natural Science Foundation of Jiangsu Province,China(BK20220534)the Jiangsu Postdoctoral Science Foundation,China(2020Z090)the Senior Talents Fund of Jiangsu University,China(5501220014)the Key Research and Development Project of Ningxia Province,China(2024BEE02001)the Open Project of Key Laboratory of Advanced Battery Materials of Yunnan Province,China(KLABM-2024092403).
文摘Single crystal Ni-rich cathode materials(SCNCM)are a good supplement in the market of nickel-based materials due to their safety and excellent electrochemical performance.However,the challenges of cation mixing,phase change during charge/discharge,and low thermal stability remain unresolved in single crystal particles.To address these issues,SCNCM are rationally modified by incorporating transition metal(TM)oxides,and the influence of metal ions with different valence states on the electrochemical properties of SCNCM is methodically explored through experimental results and theoretical calculations.Enhanced structural stability is demonstrated in SCNCM after the modifications,and the degree of improvement in the matrix materials varies depending on the valence state of doped TM ions.The highest structural stability is found in WO_(3)-modified SCNCM,due to the smaller effective ion radii,higher electro-negativity,stronger W-O bond,and efficient suppression of oxygen vacancy generation.As a result,WO_(3)-modified SCNCM have outstanding cycle performance,with a capacity retention rate of90.2%after 200 cycles.This study provides an insight into the design of advanced SCNCM with enhanced reversibility and cyclability.
基金support from the Early Career Faculty grant (80NSSC18K1514) from NASA’s Space Technology Research Grants Programsupport from the startup funds at Thayer School of Engineering,Dartmouth College。
文摘Enabling highly reversible sodium(Na) metal anodes in a polymer electrolyte(PE) system is critical for realizing next-generation batteries with lower cost,higher energy,and improved safety.However,the uneven Na deposition and high Na/PE interphase resistance lead to poor reversibility and short cycle life of Na metal anodes.To tackle these problems,here a variety of metal nanoparticles(M-np,M=Al,Sn,In or Au) are deposited onto copper(Cu) foils to synthesize binder-free M-np@Cu substrates for Na plating/stripping.Notably,the Au-np@Cu substrate provides abundant preferential nucleation/growth sites,decreasing Na nucleation barrier and thus promoting uniform Na deposition.Accordingly,stable Na metal anodes are achieved with high reversible capacities,long cycle life,and high usage of Na.With the Au-np@Cu/Na anode and PE,the full cell using a commercial bulk sulfur cathode exhibits a reversible capacity of>400 mAh g^(-1) with near-100% Coulombic efficiency over 200 cycles.
基金supported by National Natural Science Foundation of China(nos.52071346,52111530193)the Natural Science Foundation of Hunan Province for Distinguished Young Scholars(2023JJ10075)+3 种基金Hunan Provincial Natural Science Foundation of China(2021JJ30846)Natural Science Foundation of Hunan Province(2023JJ40836)Central South University Research Program of Advanced Interdisciplinary Studies(2023QYJC038)Fundamental Research Funds for the Central Universities of Central South University(2022ZZTS0402).
文摘Magnesium(Mg)and its alloys have similar densities and elastic moduli to natural bone,making them an excellent choice for orthopedic implants.However,Mg alloys are prone to electrochemical corrosion,which often leads to implant failure and hinders the further development of Mg alloys due to bacterial infection around the implant.This work aims to enhance the corrosion resistance of Mg alloys,and provide theoretical guidance for solving the problem that Mg-based orthopedic implants are susceptible to bacterial infection and,thus,implant failure.In order to solve the corrosion problem,the Mg alloy AZ91D was used as the substrate,and a compact and uniform MgAlCu-layered double hydroxide(Mg(Cu)-LDH)was prepared on its surface using a hydrothermal method.The Mg(Cu)-LDH provides a barrier between the AZ91D and corrosive liquid,which effectively protects the Mg substrate from being corroded.The Mg(Cu)-LDH shows great cell viability for MC3T3-E1 cells.The Cu^(2+)and Mg^(2+) in the coating also endow the Mg(Cu)-LDH/AZ91D with antibacterial properties,showing strong antibacterial effects on both E.coli and S.aureus with antibacterial rates over 85%.Finally,in vivo results indicated that a LDH-coated implant had no systemic effects on the hearts,livers,spleens,lungs or kidneys.It was shown that 4 weeks after surgery the ratio of bone volume to tissue volume(BV/TV)of the LDH implant was 24%,which was 1.7 times that observed for AZ91D.
基金supported by the National Natural Science Foundation of China(Nos.52071346,52111530193,and 52274387)the Natural Science Foundation of Hunan Province for Distinguished Young Scholars(No.2023JJ10075)+3 种基金the Hunan Provincial Natural Science Foundation of China(No.2021JJ30846)the Central South University Research Program of Advanced Interdisciplinary Studies(No.2023QYJC038)the Funding for the Medical Engineering Cross Disciplinary Project at Shanghai Jiao Tong University,and the Fundamental Research Funds for the Central Universities of Central South University(No.2022ZZTS0402)The authors would also thank Sinoma Institute of Materials Research(Guangzhou)Co.,Ltd.for the assistance with the TEM characterization.
文摘A good Ti-based joint implant should prevent stress shielding and achieve good bioactivity and anti-infection performance.To meet these requirements,the low-elastic-modulus alloy—Ti–35Nb–2Ta–3Zr—was used as the substrate,and functional coatings that contained bioceramics and Ag ions were prepared for coating on TiO_(2)nanotubes(diameter:(80±20)nm and(150±40)nm)using anodization,deposition,and spin-coating methods.The effects of the bioceramics(nano-β-tricalcium phosphate,microhydroxyapatite(micro-HA),and meso-CaSiO_(3))and Ag nanoparticles(size:(50±20)nm)on the antibacterial activity and the tribocorrosion,corrosion,and early in vitro osteogenic behaviors of the nanotubes were investigated.The tribocorrosion and corrosion results showed that the wear rate and corrosive rate were highly dependent on the features of the nanotube surface.Micro-HA showed great wear resistance with a wear rate of(1.26±0.06)×10^(−3)mm^(3)/(N·m)due to adhesive and abrasivewear.Meso-CaSiO_(3)showed enhanced cell adhesion,proliferation,and alkaline phosphatase activity.The coatings that contained nano-Ag exhibited good antibacterial activity with an antibacterial rate of≥89.5%against Escherichia coli.These findings indicate that hybrid coatings may have the potential to accelerate osteogenesis.
基金supported by the National Natural Science Foundation of China(52071346)Natural Science Foundation of Hunan Province(2023JJ40836)+1 种基金Central South University Research Programme of Advanced Interdisciplinary Studies(2023QYJC026,2023QYJC038)Outstanding Youth Scientist Foundation of Hunan Province(2022JJ10095,2023JJ10075).
文摘stract Facilitating an appropriate immune response is crucial for promoting bone tissue regeneration upon biomaterial implantation.In this study,the Mg^(2+)-containing nanostructures on the surface of Ti-1.25Mg alloy were prepared by a one-step hydrothermal reaction method via regulating pH value to enhance the immunomodulatory osteogenic properties of Ti-Mg alloys.In neutral(HT7)or alkaline(HT9)hydrothermal treatment(HT)solution,the size of MgTiO_(3)nanostructures formed on the surface of Ti-1.25Mg alloy is smaller than that in acidic HT solution(HT5),and lamellar Mg(OH)_(2)nano-structures are found in HT7 and HT9.In addition,the sample surface has a lower roughness and higher wettability with increasing pH value.The Mg^(2+)-containing nanostructures on the Ti-1.25Mg alloy inhibited inflammatory response by promoting the polarization of M2 macrophages,thereby promoting osteogenesis in vitro.The micro-CT and histological assessment proved that the regeneration of bone defect was faster in HT7 than the Ti-1.25Mg in vivo.Mechanically,Mg^(2+)-containing nanostructures can mediate the immune response of macro-phages via upregulating integrinsα5β1 and inhibiting Toll-like receptors(TLR-4),subsequently inhibiting the NF-κB signaling pathway.Overall,osteoimmunity-regulating Mg^(2+)-containing nanostructures on Ti-1.25Mg present a promising biomaterial for bone repair.
基金funding by the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences, Materials Sciences and Engineering Division, under Contract No. DE-AC02-05-CH11231: Materials Project program KC23MPR.G. acknowledges support from the Excellent Young Scientists Fund (Overseas) of Shandong Province (2022HWYQ091) and the Initiative Research Fund of Shandong Institute of Advanced Technology (2020107R03)+5 种基金B.H. acknowledges the financial support from the Science and Technology Planning Project of Guangdong Province, China (Grant No. 2017A050506053)the Science and Technology Program of Guangzhou (No. 201704030107)the Hong Kong General Research Fund (Grants No. 16214217 and No. 16206020)This paper was also supported in part by the Project of Hetao Shenzhen-Hong Kong Science and Technology Innovation Cooperation Zone (HZQB-KCZYB2020083)C.L. acknowledges the support from the Sinergia project of the Swiss National Science Foundation (grant number CRSII5_189924)Z.C. acknowledges support from the Fundamental Research Fund for Zhejiang Ocean University (Grant No. JX6311181423).
文摘Understanding lattice dynamics and thermal transport mechanisms in cubic hybrid organic–inorganic perovskites remain challenging due to strong anharmonicity and phase transitions.Here,we investigate the thermal transport behavior in benchmark cubic hybrid perovskite FAPbI_(3)by coupling first principles-based anharmonic lattice dynamics with a linearized Wigner transport equation.Using the Temperature-Dependent Effective Potential(TDEP)method,we stabilize the negative soft modes,primarily dominated by organic FA+cations.Our calculations predict an ultra-low thermal conductivity of~0:63Wm^(-1)K^(-1)at 300 K,following a temperature dependence of T^(−0.740).Contrary to common assumptions,we find that the[PbI_(3)]^(1-)units,rather than FA^(+)cations,dominate thermal resistance.Furthermore,we demonstrate that anharmonic force constants are highly temperature-sensitive,relying on 0-K force constants significantly underestimates thermal conductivity.Our study not only elucidates the microscopic mechanisms governing thermal transport in FAPbI_(3)but also provides a robust framework for modeling heat conduction in hybrid organic-inorganic compounds.
基金Zhejiang University of TechnologyNatural Science Foundation of Zhejiang Province,Grant/Award Number:LD18E020003+1 种基金National Natural Science Foundation of China,Grant/Award Number:51722210Dartmouth College。
文摘2D transition metal carbides,carbonitrides,and nitrides known as MXenes possess high electrical conductivity,large redox active surface area,rich surface chemistry,and tunable structures.Benefiting from these exceptional chemical and physical properties,the applications of MXenes for electrochemical energy storage and conversion have attracted increasing research interests around the world.Notably,the electrochemical performances of MXenes are directly dependent on their synthesis conditions,interfacial chemistries and structural configurations.In this review,we summarize the synthesis techniques of MXenes,as well as the recent advances in the interfacial structure design of MXene-based nanomaterials for electrochemical energy storage and conversion applications.Additionally,we provide an in-depth discussion on the relationship between interfacial structure and electrochemical performance from the perspectives of energy storage and electrocatalysis mechanisms.Finally,the challenges and insights for the future research of interfacial structure design of MXenes are outlined.
基金This work has been predominantly funded by NIH grant R01 EB023909 with hardware support through NIH R44 CA232879the support of the Norris Cotton Cancer Center shared resources in NIH 5P30 CA023108-41.
文摘Color vision is used throughout medicine to interpret the health and status of tissue.Ionizing radiation used in radiation therapy produces broadband white light inside tissue through the Cherenkov effect,and this light is attenuated by tissue features as it leaves the body.In this study,a novel time-gated three-channel camera was developed for the first time and was used to image color Cherenkov emission coming from patients during treatment.The spectral content was interpreted by comparison with imaging calibrated tissue phantoms.Color shades of Cherenkov emission in radiotherapy can be used to interpret tissue blood volume,oxygen saturation and major vessels within the body.
