In deep underground mining, the surrounding rocks are very soft with high stress. Their deformation and destruction are serious, and frequent failures occur on the bolt support. The failure mechanism of bolt support i...In deep underground mining, the surrounding rocks are very soft with high stress. Their deformation and destruction are serious, and frequent failures occur on the bolt support. The failure mechanism of bolt support is proposed to solve these problems. A calculation theory is established on the bond strength of the interface between the anchoring agent and surrounding rocks. An analysis is made on the influence law of different mechanical parameters of surrounding rocks on the interfacial bond strength. Based on the research, a new high-strength bolt-grouting technology is developed and applied on site. Besides, some helpful engineering suggestions and measures are proposed. The research shows that the serious deformation and failure, and the lower bond strength are the major factors causing frequent failures of bolt support. So, the bolt could not give full play to its supporting potential. It is also shown that as the integrity, strength, interface dilatancy and stress of surrounding rocks are improved, the bond strength will increase. So, the anchoring force on surrounding rocks can be effectively improved by employing an anchoring agent with high sand content, mechanical anchoring means, or grouting reinforcement. The new technology has advantages in a high strength, imposing pre-tightening force, and giving full play to the bolt supporting potential. Hence, it can improve the control effect on surrounding rocks. All these could be helpful references for the design of bolt support in deep underground mines.展开更多
Traditional metals often exhibit a trade-offbetween strength and plasticity,limiting their wide application of metals in aerospace,transportation,energy industry and other fields[1-3].In order to overcome this dilemma...Traditional metals often exhibit a trade-offbetween strength and plasticity,limiting their wide application of metals in aerospace,transportation,energy industry and other fields[1-3].In order to overcome this dilemma,high-entropy alloys(HEAs),proposed by Yeh et al.and Cantor et al.,are currently of great interest in the materials community due to their excellent mechanical properties[4-7].To further promote the wide application of HEAs in industrial production,Lu et al.developed a new eutectic high-entropy alloy(EHEAs)by combining the potential advantages of traditional eutectic alloys and HEAs[8-11].展开更多
Supramolecular materials,characterized by dynamic reversibility and responsiveness to environmental stimuli,have found widespread applications in numerous fields.Unlike traditional materials,supramolecular materials t...Supramolecular materials,characterized by dynamic reversibility and responsiveness to environmental stimuli,have found widespread applications in numerous fields.Unlike traditional materials,supramolecular materials that rely on non-covalent interactions can allow spontaneous reorganization and self-healing at room temperature.However,these materials typically exhibit low strength due to the weak bonding energies of non-covalent interactions.This study presents the development of a high-strength self-healing supramolecular material that combines multiple interactions including ionic bonding,hydrogen bonding,and coordination bonding.The material,formed by the aggregation of the negatively charged picolinate-grafted copolymer(PCM)with positively charged hyperbranched molecules(HP),is further enhanced by Eu^(3+)ion complexation.The resulting film exhibits a high modulus of 427 MPa,tensile strength of 10.5 MPa,and toughness of 14.7 MJ m^(−3).Meanwhile,the non-covalent interaction of this supramolecular material endows it with a self-healing efficiency of 92%within 24 h at room temperature,as well as multiple remolding properties.The incorporation of lanthanide ions also imparts tunable fluorescence.This study not only provides insights into the development of high-strength self-healing materials but also offers new possibilities for the functionalization of supramolecular materials.展开更多
High strength steels exhibit superior mechanical properties due to the unique microstructure,which successfully solves the drawback of the inevitable strength-toughness trade-off that occurs in traditional alloys.Here...High strength steels exhibit superior mechanical properties due to the unique microstructure,which successfully solves the drawback of the inevitable strength-toughness trade-off that occurs in traditional alloys.Here we investigated the effect of matrix and precipitates on mechanical properties of Cr-Ni-Mo-V/Nb steel after water quenching and tempering(150-500℃).The results showed that the microstructure of the present steel is noticeably tuned by changing the tempering temperature.An excellent combination of strength(a yield strength of 1308 MPa with a total elongation of 8.2%)and toughness(Charpy V-notch impact toughness of 40.5 J/cm^(2))is obtained upon tempering at 200℃.This is attributed to the lath martensite containing high dislocation density,the martensite-twin substructure,and the strengthening effects of the precipitated needle-likeε-carbides and spherical VC particles.The acicularε-carbides are replaced by the rod-shaped Fe_(3)C at the tempering temperature of 350℃,resulting in the remarkable deterioration in strength,hardness,and elongation.Spheroidized carbides formed at a tempering temperature of 500℃ are beneficial to the enhancement of the elongation and toughness,but the strength decreases due to the matrix softening caused by the recovery of dislocation.展开更多
Soft self-healing materials are promising candidates for flexible electronic devices due to their excep-tional compatibility,extensibility,and self-restorability.Generally,these materials suffer from low tensile stren...Soft self-healing materials are promising candidates for flexible electronic devices due to their excep-tional compatibility,extensibility,and self-restorability.Generally,these materials suffer from low tensile strength and susceptibility to fracture because of the restricted microstructure design.Herein,we pro-pose a hydrothermal-freeze-thaw method to construct high-strength self-healing hydrogels with even in-terconnected networks and distinctive wrinkled surfaces.The integration of the wrinkled outer surface with the three-dimensional internal network confers the self-healing hydrogel with enhanced mechan-ical strength.This hydrogel achieves a tensile strength of 223 kPa,a breaking elongation of 442%,an adhesion strength of 57.6 kPa,and an adhesion energy of 237.2 J m-2.Meanwhile,the hydrogel demon-strates impressive self-repair capability(repair efficiency:93%).Moreover,the density functional theory(DFT)calculations are used to substantiate the stable existence of hydrogen bonding between the PPPBG hydrogel and water molecules which ensures the durability of the PPPBG hydrogel for long-term applica-tion.The measurements demonstrate that this multifunctional hydrogel possesses the requisite sensitivity and durability to serve as a strain sensor,which monitors a spectrum of motion signals including subtle vocalizations,pronounced facial expressions,and limb articulations.This work presents a viable strategy for healthcare monitoring,soft robotics,and interactive electronic skins.展开更多
The tradeoff between strength and corrosion resistance restricts the development of low-alloyed magnesium(Mg)alloys.In this work,a low-alloyed Mg-1Sm-0.8Mn-0.5Ca-0.4Zn alloy was prepared through a simple process of co...The tradeoff between strength and corrosion resistance restricts the development of low-alloyed magnesium(Mg)alloys.In this work,a low-alloyed Mg-1Sm-0.8Mn-0.5Ca-0.4Zn alloy was prepared through a simple process of conventional casting followed by proper hotextrusion.The as-extruded alloy exhibits a very high yield strength of 402 MPa,an acceptable elongation of 5%,and a low corrosion rate of 0.56 mm y^(-1) which is close to that of high-purity Mg,and such comprehensive properties are superior to most reported Mg alloys,whether high alloying or low alloying.The special fine microstructure is responsible for high strength,including fine dynamic recrystallized(DRXed)grains,strong textured un-DRXed grains,dislocations and uniformly dispersed nano-spaced α-Mn nano-precipitates.An important finding of this study is that the corrosion film microstructure has amorphous characteristics,and this inevitably contributes to the high film protectiveness,and finally improves the corrosion resistance of the as-extruded alloy with relatively strong micro-galvanic corrosion tendency.In addition,the influence of micro/submicron-sized Mg_(2)Ca with anodic nature and nano-sized cathode α-Mn precipitates with strong strengthening effect on the corrosion film is also discussed.This study suggests that the strength-corrosion tradeoff can be evaded by regulating the microstructure of alloy substrate and corrosion film in the low-alloyed Mg alloy.展开更多
As a biomass material with biodegradability and biocompatibility, sodium alginate (SA) is a good candidate for constructing hydrogels for tissue-mimicking and biomedical scaffold fabricating through extrusion-based 3D...As a biomass material with biodegradability and biocompatibility, sodium alginate (SA) is a good candidate for constructing hydrogels for tissue-mimicking and biomedical scaffold fabricating through extrusion-based 3D printing technology. However, the mechanical strength and stiffness of alginate hydrogels are still not comparable with biological tissues such as tendons and the printability of SA solutions is often poor. Here, a novel strategy for 3D printing of alginate hydrogels with high mechanical performance is developed by using glycerol as a co-solvent for SA solutions. The addition of glycerol (GL) enables the formation of a homogenous SA/GL solution with a high solid content of 12–20 wt.% and endows crosslinked SA hydrogels with high stretchability. By applying uniaxial stretches, hydrogel filaments prepared with concentrated SA/GL solutions reveal a high tensile strength of 36.6–161.3 MPa, Young's modulus of 59.2–1964.2 MPa, and elongation at break of 8.5 %–106.2 % due to the high orientated and closely packed SA chains. SA/GL solutions become more solid-like with increasing SA concentration, and the solution with a solid content of 16 wt.% exhibits optimal 3D printability because of the appropriate rheological properties and thixotropic behavior. By designing the deforming-and-fixing process, 3D printed high-strength alginate hydrogels with complex structures are prepared, broadening the application of alginate hydrogels in load-bearing and biomedical fields.展开更多
The low strength of Mg-Li alloys sets a limit to lightweight applications.Introducing crystal defects(twins,dislocations,and SFs)is a distinctive strategy for maintaining good mechanical properties of metallic materia...The low strength of Mg-Li alloys sets a limit to lightweight applications.Introducing crystal defects(twins,dislocations,and SFs)is a distinctive strategy for maintaining good mechanical properties of metallic materials.A lamellar-structured Mg-4Li-3Al-0.4Ca alloy with high performance was prepared by hot extrusion and rotary swaging.The as-swaged alloy exhibits excellent mechanical properties with tensile strength,yield strength,elongation to failure,and specific strength of 391 MPa,312 MPa,14.2%,and 238.4 kN m kg^(-1),respectively.The average grain size of the as-swaged alloy is 160±23 nm,and the microstructure is mainly composed of lamellar structures,twins,ultrafine grains,and nano-grains.The abundant lamellar structures and twins promote the storage of dislocations and SFs,leading to the formation of twin-twin interactions and enhancing strain hardening.The formation of UFG and NG by dynamic recrystallization further improves the yield strength.Shearable second phases play a critical role in enhancing the yield strength and ductility.More importantly,extensive planar dislocation glide and(c+a)dislocations efficiently relax the local stress concentrations,and thus improve the ductility.展开更多
The dilemma of choosing between superb grain boundary strengthening and excellent precipitation strengthening is commonly faced in the pursuit of high-strength age-hardenable Mg alloys.Here,a strategy for addressing t...The dilemma of choosing between superb grain boundary strengthening and excellent precipitation strengthening is commonly faced in the pursuit of high-strength age-hardenable Mg alloys.Here,a strategy for addressing this dilemma via the balance between grain refinement and weakening of dynamic precipitation is proposed and applied on a Mg-10.95Gd-2.06Ag(wt%)alloy treated by sequential processing of equalchannel angular pressing(ECAP),hot rolling and aging.The hot rolling leads to a noticeable dissolution of the dynamic precipitates intensively formed during prior ECAP,together with a tolerable grain growth.Meanwhile,numerous multi-twinning-induced lamellar bands(LBs)demarcated by coaxial grain boundaries(CGBs)subdivide the grains.For the first time,a quadruple twinning pattern for the formation of CGB with a misorientation of~135°is raised.During post-rolling aging,besides the commonβ’andγ”precipitates and theβnano-particles whose Gd/Ag ratio is much lower than that of dynamically precipitatedβparticles,theβ”/βT precipitates,CGB segregation,and stacking fault(SF)-associated segregation/γ’precipitates within LBs,are also involved with the precipitation structure.Benefiting from this complex precipitation structure,a good age-hardening ability manifested by the aging-induced tensile yield strength(TYS)increment reaching 115 MPa is attained.Combining with the strengthening from grain boundaries,dislocations,solutes,and basal texture,a high TYS of 447 MPa is achieved.展开更多
Polypropylene(PP)has a relatively low melt strength due to its linear structure,which seriously limits its supercritical CO_(2)foaming performance.Introducing long-chain branches(LCBs)via grafting can significantly en...Polypropylene(PP)has a relatively low melt strength due to its linear structure,which seriously limits its supercritical CO_(2)foaming performance.Introducing long-chain branches(LCBs)via grafting can significantly enhance its melt strength.However,the relationship between the LCB level of high melt strength polypropylene(HMSPP)and its foaming behavior remains unclear.In this study,a series of HMSPP with different LCB levels was prepared using vinyl polydimethylsiloxane(VS)of varying viscosities as grafting monomers to investigate this relationship.Rheological analysis showed that the increase in viscosity of VS led to higher LCB levels in HMSPP.The melt strength of HMSPP increases with the increase of LCB levels,reaching up to 0.62 N,which is 13 times higher than that of the raw material.Supercritical CO_(2)foaming results revealed that the expansion ratio of HMSPP first increased and then decreased with the increase of melt strength,reaching a maximum of 39.4 times.Combining experiments with simulations,the influence of LCB levels on the dissolution and diffusion behavior of CO_(2)in HMSPP was clarified.This study deepens the understanding of the relationship between LCB and the foaming behavior of HMSPP,providing valuable insights for designing HMSPP with optimized foaming properties.展开更多
Different stress states have a significant influence on the magnitude of the microscopic plastic strain and result in the development of the microstructure evolution.As a result,a comprehensive understanding of the di...Different stress states have a significant influence on the magnitude of the microscopic plastic strain and result in the development of the microstructure evolution.As a result,a comprehensive understanding of the different scale variation on microstructure evolution during bending deformation is essential.The advanced high strength dual-phase(DP1180)steel was investigated using multiscale microstructure-based 3D representative volume element(RVE)modelling technology with emphasis on understanding the relationship between the microstructure,localised stress-strain evolution as well as the deformation characteristics in the bending process.It is demonstrated that the localised development in bending can be more accurately described by microscopic deformation when taking into account microstructural properties.Microstructure-based 3D RVEs from each chosen bending condition generally have comparable localisation properties,whilst the magnitudes and intensities differ.In addition,the most severe localised bands are predicted to occur close to the ferrite and martensite phase boundaries where the martensite grains are close together or have a somewhat sharp edge.The numerically predicted results for the microstructure evolution,shear bands development and stress and strain distribution after 3-point bending exhibit a good agreement with the relevant experimental observations.展开更多
This article reports a systematic investigation on the relationship between the microstructure evolution and mechanical properties of as-cast Mg-9.5Gd-2.3Y-1Zn-0.5Zr(VW92,wt.%)alloy during aging treatment.The results ...This article reports a systematic investigation on the relationship between the microstructure evolution and mechanical properties of as-cast Mg-9.5Gd-2.3Y-1Zn-0.5Zr(VW92,wt.%)alloy during aging treatment.The results indicate that the alloy exhibits obvious double peak-aging characteristics at 180℃,200℃,and 220℃;the first peak-aging appeared at 96 h,48 h,and 48 h,respectively,while the second peak-aging occurred at 204 h,180 h,and 180 h,respectively.Moreover,the strengths of the first peak-aging were higher than those of the second peak-aging.Consequently,the first peak-aging at 200℃ achieved the best mechanical properties,with ultimate tensile strength(UTS),yield strength(YS),and elongation(EL)of 380(±2.0)MPa,255(±1.8)MPa,and 12.8(±1.7)%,respectively.While the strength decreased in the second peak-aging,the elongation increased to 17.2(±0.5)%.The first peak-aging strengthening is ascribed to the participation of the nano-β' phases in the matrix and the long period stacking ordered(LPSO)phases at grain boundaries(GBs).Additionally,the second peak-aging strengthening is associated with the emergence of a relatively new 3D structure comprising longchain-like structural phases β'+β'_(F) tβ_(1),γ' phases,and LPSO phases within the grain,combined with the fine and uniform LPSO phases at the GBs.展开更多
The polycarbonate(bisphenol A)/acrylonitrile—butadiene—styrene(PC/ABS)features excellent mechanical properties,but its high flammability poses a potential safety hazard in practical applications.Although the incorpo...The polycarbonate(bisphenol A)/acrylonitrile—butadiene—styrene(PC/ABS)features excellent mechanical properties,but its high flammability poses a potential safety hazard in practical applications.Although the incorporation of halogen-free additives enhances flame retardancy,it often leads to substantial smoke emission and compromises the mechanical properties of PC/ABS alloy.Therefore,simultaneous enhancement of both flame retardancy with low smoke and mechanical properties holds significant practical value for material development.Herein,a low-smoke PC/ABS composite with balanced flame retardancy and mechanical properties was achieved through an efficient ternary flame retardant system containing bisphenol A bis(diphenyl phosphate)(BDP),potassium-4-(phenylsulfonyl)benzenesulfonate(KSS),and 3-glycidyloxypropyltrimethoxysilane-modified boehmite(m-BM).PC/ABS/BDP6/KSS2/m-BM2 can achieve the same flame retardant level(V-0)as PC/ABS/BDP14,and the limiting oxygen index is increased to 26.8%.Meanwhile,the tensile strength and impact strength are increased by 16.1%and 81.4%respectively.The ternary system can significantly inhibit the release of smoke and heat,under the same flame retardant load(10%(mass)),the total heat release and total smoke production of PC/ABS loaded with ternary flame-retardant system decreased by 18.1%and 21.9%respectively compared to only BDP loaded.This ternary flame-retardant system provides a practical solution for developing high-performance,low-smoke flame-retardant PC/ABS composites.展开更多
Austenitic stainless steels(ASSs)are widely used in various in-dustries such as aerospace,nuclear energy,food,and biotechnol-ogy owing to their exceptional combination of corrosion resistance,weldability,toughness,and...Austenitic stainless steels(ASSs)are widely used in various in-dustries such as aerospace,nuclear energy,food,and biotechnol-ogy owing to their exceptional combination of corrosion resistance,weldability,toughness,and formability[1,2].However,a signifi-cant drawback of ASSs is their low yield strength,which limits their applications in extreme environments[3].Grain boundary(GB)engineering plays a crucial role in enhancing the strength of ASSs[4,5].For instance,grain refinement techniques such as cold rolling followed by annealing[6],severe plastic deformation(SPD)[7],and surface mechanical attrition/rolling treatments[8,9]introduce high-angle GBs(HAGBs)into ASSs,thereby improving their strength.However,the high density of HAGBs limits their ca-pacity for dislocation storage and multiplication,leading to a sig-nificant loss of ductility[10,11].Additionally,several studies have shown that twin boundaries(TBs)can simultaneously enhance the strength,toughness,and corrosion resistance of ASSs[12,13].展开更多
Laser powder bed fusion(LPBF)of Mg alloys mainly focuses on the traditional commercial casting Mg alloys such as AZ91D,ZK60 and WE43,which usually display relatively low tensile strengths.Herein we developed a novel h...Laser powder bed fusion(LPBF)of Mg alloys mainly focuses on the traditional commercial casting Mg alloys such as AZ91D,ZK60 and WE43,which usually display relatively low tensile strengths.Herein we developed a novel high-strength Mg-12 Gd-2 Y-1 Zn-0.5 Mn(wt.%,GWZ1221M)alloy for the LPBF additive manufacturing process,and the evolution of microstructure and mechanical properties from the as-built state to LPBF-T4 and LPBF-T6 states was systematically investigated.The as-built GWZ1221M alloy exhibited fine equiaxed grains with an average grain size of only 4.3±2.2μm,while the as-cast alloy displayed typical coarse dendrite grains(178.2±73.6μm).Thus,the as-built alloy showed significantly higher tensile strengths than the as-cast counterpart,and its yield strength(YS),ultimate tensile strength(UTS)and elongation(EL)were 315±8 MPa,340±7 MPa and 2.7±0.5%respectively.Solution treatment transformed hard and brittleβ-(Mg,Zn)_(3)(Gd,Y)phase into basal X phase and lamellar long period stacking ordered(LPSO)with better plastic deformability,leading to the improvement of EL.Then peak-aging heat treatment introduced numerous nano-sized prismaticβprecipitates inside grains,resulting in the enhancement of YS.Finally,the LPBF-T6 alloy achieved appreciably high strength with YS,UTS and EL of 320±3 MPa,395±4 MPa and 2.1±0.4%respectively.Both as-built and LPBF-T6 GWZ1221M alloys showed remarkably higher tensile strengths than the as-cast counterparts and as-built commercial Mg alloys,highlighting the great potential of high-strength as-built Mg-Gd based alloys for structural applications.展开更多
The moment a media delegation from the Republic of the Congo arrived at the Othello Kitchenware Museum on 18 November 2025,they were greeted with a vivid show of Guangdong’s industrial strength.Standing before them w...The moment a media delegation from the Republic of the Congo arrived at the Othello Kitchenware Museum on 18 November 2025,they were greeted with a vivid show of Guangdong’s industrial strength.Standing before them was not a typical exhibition hall,but a building shaped like a gleaming stainless-steel cooking pot.展开更多
Fine-grained Mg-6Zn-4Y alloy was prepared by an ingot metallurgy process with hot extrusion at 300 ℃.The microstructure was studied by XRD,OM,SEM and TEM,and the tensile properties were tested at room temperature.The...Fine-grained Mg-6Zn-4Y alloy was prepared by an ingot metallurgy process with hot extrusion at 300 ℃.The microstructure was studied by XRD,OM,SEM and TEM,and the tensile properties were tested at room temperature.The results show that the alloy is composed of α-Mg and W-phase.The microstructure of the as-extruded alloy has a bimodal grain size distribution.The fine grains with the mean size of 1.2 μm are formed by dynamic recrystallization.The coarse grains(about 23% in area fraction) are unrecrystallized regions which are elongated along extrusion direction.The engineering stress—strain curve shows a pronounced yield point.The ultimate tensile strength,yield strength,and elongation are(371±10) MPa,(350±5) MPa and(7±2)%,respectively.The high strengths are attributed to the fine-grained matrix structure enhanced by W-phase particles,nano-scaled precipitates,and strong basal plane texture.展开更多
Eight high strength concrete (HSC) prisms strengthened with continuous carbon fiber sheet(CFS)were tested.As a result of the confinement provided by CFS,the concrete would fail at a greater strain than the unconfined ...Eight high strength concrete (HSC) prisms strengthened with continuous carbon fiber sheet(CFS)were tested.As a result of the confinement provided by CFS,the concrete would fail at a greater strain than the unconfined and then a significant increase in ductility can be achieved.The lateral pressure exerted by CFS would increase the compressive strength of the concrete,resulting in higher load bearing capacity.This paper proposes the stress strain curve of this kind of hybrid specimen,which agrees well with the test results.Based on the stress strain relationship and the assumptions proposed in this paper,a computer program was developed to analyze HSC columns,confined by CFS,which were subjected to axial compression and biaxial bending.The results shown in this paper indicate that the ductility of HSC column is significantly improved and the strength is also increased by some degree.展开更多
Aim To research on a solid cemented carbide multi facet drill for drilling high strength steel. Methods Assimilating some features of multi facet drill edge structures, through systematic drilling experiments, a n...Aim To research on a solid cemented carbide multi facet drill for drilling high strength steel. Methods Assimilating some features of multi facet drill edge structures, through systematic drilling experiments, a new type of solid cemented carbide drill was developed and the drill geometry was optimized. Results With the new type drill,the drilling force decreases by 10%-20%, the drilling productivity (drilled holes per hour) increases by 2-3 times, and the drilling precision and surface finish increase by one level. Conclusion The new type drill possesses excellent drilling performance.展开更多
Based on experiments, a computer program is developed. The calculated results agree well with the experimental results. The flexural behavior of T shaped high strength concrete members subjected to axial compression ...Based on experiments, a computer program is developed. The calculated results agree well with the experimental results. The flexural behavior of T shaped high strength concrete members subjected to axial compression and biaxial bending is studied. The main factors affecting the flexural behavior of T shaped high strength concrete members are loading angle, axial compression ratio and reinforcement ratio.展开更多
基金Projects(51304125,51379114)supported by the National Natural Science Foundation of ChinaProject(BS2013NJ004)supported by Award Fund for Outstanding Young and Middle-Aged Scientist of Shangdong Province,ChinaProject(201301004)supported by the Innovation Fund for Postdoctor of Shandong Province,China
文摘In deep underground mining, the surrounding rocks are very soft with high stress. Their deformation and destruction are serious, and frequent failures occur on the bolt support. The failure mechanism of bolt support is proposed to solve these problems. A calculation theory is established on the bond strength of the interface between the anchoring agent and surrounding rocks. An analysis is made on the influence law of different mechanical parameters of surrounding rocks on the interfacial bond strength. Based on the research, a new high-strength bolt-grouting technology is developed and applied on site. Besides, some helpful engineering suggestions and measures are proposed. The research shows that the serious deformation and failure, and the lower bond strength are the major factors causing frequent failures of bolt support. So, the bolt could not give full play to its supporting potential. It is also shown that as the integrity, strength, interface dilatancy and stress of surrounding rocks are improved, the bond strength will increase. So, the anchoring force on surrounding rocks can be effectively improved by employing an anchoring agent with high sand content, mechanical anchoring means, or grouting reinforcement. The new technology has advantages in a high strength, imposing pre-tightening force, and giving full play to the bolt supporting potential. Hence, it can improve the control effect on surrounding rocks. All these could be helpful references for the design of bolt support in deep underground mines.
基金financial supported by the Natural Science Foundation of Jiangsu Provincial Education Department(No.24KJB430003)the Natural Science Foundation for Young Scholars of Jiangsu Province(No.BK20240979)+3 种基金support of Natural Science Foundation for Young Scholars of Jiangsu Province(No.BK20220628)the National Natural Science Foundation for Young Scholars of China(52301130)the Changzhou Sci&Tech program(No.GJ20220153)support of the Natural Science Foundation of Jiangsu Provincial Education Department(No.21KJB430001).
文摘Traditional metals often exhibit a trade-offbetween strength and plasticity,limiting their wide application of metals in aerospace,transportation,energy industry and other fields[1-3].In order to overcome this dilemma,high-entropy alloys(HEAs),proposed by Yeh et al.and Cantor et al.,are currently of great interest in the materials community due to their excellent mechanical properties[4-7].To further promote the wide application of HEAs in industrial production,Lu et al.developed a new eutectic high-entropy alloy(EHEAs)by combining the potential advantages of traditional eutectic alloys and HEAs[8-11].
基金supported by Zhejiang Provincial Natural Science Foundation of China under(LD22A020002)National Natural Science Foundation of China(52473116,22322508)+1 种基金International Cooperation Project of Ningbo City(2023H019)the Sino-German mobility program(M-0424).
文摘Supramolecular materials,characterized by dynamic reversibility and responsiveness to environmental stimuli,have found widespread applications in numerous fields.Unlike traditional materials,supramolecular materials that rely on non-covalent interactions can allow spontaneous reorganization and self-healing at room temperature.However,these materials typically exhibit low strength due to the weak bonding energies of non-covalent interactions.This study presents the development of a high-strength self-healing supramolecular material that combines multiple interactions including ionic bonding,hydrogen bonding,and coordination bonding.The material,formed by the aggregation of the negatively charged picolinate-grafted copolymer(PCM)with positively charged hyperbranched molecules(HP),is further enhanced by Eu^(3+)ion complexation.The resulting film exhibits a high modulus of 427 MPa,tensile strength of 10.5 MPa,and toughness of 14.7 MJ m^(−3).Meanwhile,the non-covalent interaction of this supramolecular material endows it with a self-healing efficiency of 92%within 24 h at room temperature,as well as multiple remolding properties.The incorporation of lanthanide ions also imparts tunable fluorescence.This study not only provides insights into the development of high-strength self-healing materials but also offers new possibilities for the functionalization of supramolecular materials.
基金supported by the National Natural Science Foundation of China(Grant Nos.51904278,51974288 and 52071300)the Special Funding Projects for Local Science and Technology Development guided by the Central Committee(YDZJSX2021C007,YDZJSX2021B020 and YDZX20191400004587)+4 种基金the Key Research and Development Project of Shanxi Province(202102050201004,202102150401002,202202050201015)the Scientific and Technological Innovation Talent Team Project of Shanxi Province(202204051002020)the Basic Research Program of Shanxi Province(20210302123218,202203021212126,202203021221096)the Foundation of the State Key Laboratory of Advanced Metallurgy,USTB(K22-11)the Special Project for Transformation of Scientific Achievements(202204021301025).
文摘High strength steels exhibit superior mechanical properties due to the unique microstructure,which successfully solves the drawback of the inevitable strength-toughness trade-off that occurs in traditional alloys.Here we investigated the effect of matrix and precipitates on mechanical properties of Cr-Ni-Mo-V/Nb steel after water quenching and tempering(150-500℃).The results showed that the microstructure of the present steel is noticeably tuned by changing the tempering temperature.An excellent combination of strength(a yield strength of 1308 MPa with a total elongation of 8.2%)and toughness(Charpy V-notch impact toughness of 40.5 J/cm^(2))is obtained upon tempering at 200℃.This is attributed to the lath martensite containing high dislocation density,the martensite-twin substructure,and the strengthening effects of the precipitated needle-likeε-carbides and spherical VC particles.The acicularε-carbides are replaced by the rod-shaped Fe_(3)C at the tempering temperature of 350℃,resulting in the remarkable deterioration in strength,hardness,and elongation.Spheroidized carbides formed at a tempering temperature of 500℃ are beneficial to the enhancement of the elongation and toughness,but the strength decreases due to the matrix softening caused by the recovery of dislocation.
基金supported by the National Natural Science Foundation of China(Nos.U21A6004,U21A20172,61804091,21574076,and U1510121)the Science and Technology Major Project of Shanxi(No.202101030201022)+1 种基金the Fundamental Research Program of Shanxi Province(No.202103021223019)the Open Fund of the Key Lab of Organic Optoelectronics&Molecular Engineering.
文摘Soft self-healing materials are promising candidates for flexible electronic devices due to their excep-tional compatibility,extensibility,and self-restorability.Generally,these materials suffer from low tensile strength and susceptibility to fracture because of the restricted microstructure design.Herein,we pro-pose a hydrothermal-freeze-thaw method to construct high-strength self-healing hydrogels with even in-terconnected networks and distinctive wrinkled surfaces.The integration of the wrinkled outer surface with the three-dimensional internal network confers the self-healing hydrogel with enhanced mechan-ical strength.This hydrogel achieves a tensile strength of 223 kPa,a breaking elongation of 442%,an adhesion strength of 57.6 kPa,and an adhesion energy of 237.2 J m-2.Meanwhile,the hydrogel demon-strates impressive self-repair capability(repair efficiency:93%).Moreover,the density functional theory(DFT)calculations are used to substantiate the stable existence of hydrogen bonding between the PPPBG hydrogel and water molecules which ensures the durability of the PPPBG hydrogel for long-term applica-tion.The measurements demonstrate that this multifunctional hydrogel possesses the requisite sensitivity and durability to serve as a strain sensor,which monitors a spectrum of motion signals including subtle vocalizations,pronounced facial expressions,and limb articulations.This work presents a viable strategy for healthcare monitoring,soft robotics,and interactive electronic skins.
基金the support of the National Natural Science Foundation of China(52471126,52071093)the Natural Science Foundation of Heilongjiang Province of China(LH2023E059)the Scientific and Technological Developing Scheme of Jilin Province(SKL202302038).
文摘The tradeoff between strength and corrosion resistance restricts the development of low-alloyed magnesium(Mg)alloys.In this work,a low-alloyed Mg-1Sm-0.8Mn-0.5Ca-0.4Zn alloy was prepared through a simple process of conventional casting followed by proper hotextrusion.The as-extruded alloy exhibits a very high yield strength of 402 MPa,an acceptable elongation of 5%,and a low corrosion rate of 0.56 mm y^(-1) which is close to that of high-purity Mg,and such comprehensive properties are superior to most reported Mg alloys,whether high alloying or low alloying.The special fine microstructure is responsible for high strength,including fine dynamic recrystallized(DRXed)grains,strong textured un-DRXed grains,dislocations and uniformly dispersed nano-spaced α-Mn nano-precipitates.An important finding of this study is that the corrosion film microstructure has amorphous characteristics,and this inevitably contributes to the high film protectiveness,and finally improves the corrosion resistance of the as-extruded alloy with relatively strong micro-galvanic corrosion tendency.In addition,the influence of micro/submicron-sized Mg_(2)Ca with anodic nature and nano-sized cathode α-Mn precipitates with strong strengthening effect on the corrosion film is also discussed.This study suggests that the strength-corrosion tradeoff can be evaded by regulating the microstructure of alloy substrate and corrosion film in the low-alloyed Mg alloy.
基金supported by the National Natural Science Foundation of China(Nos.52203025,52072193,52361165657,and U22A20131)the Shandong Provincial Natural Science Foundation(Nos.ZR2021JQ16,ZR2023YQ040,and ZR2022QE266)the Shandong Provincial College Students'Innovation and Entrepreneurship Training Program(No.S202311065122)。
文摘As a biomass material with biodegradability and biocompatibility, sodium alginate (SA) is a good candidate for constructing hydrogels for tissue-mimicking and biomedical scaffold fabricating through extrusion-based 3D printing technology. However, the mechanical strength and stiffness of alginate hydrogels are still not comparable with biological tissues such as tendons and the printability of SA solutions is often poor. Here, a novel strategy for 3D printing of alginate hydrogels with high mechanical performance is developed by using glycerol as a co-solvent for SA solutions. The addition of glycerol (GL) enables the formation of a homogenous SA/GL solution with a high solid content of 12–20 wt.% and endows crosslinked SA hydrogels with high stretchability. By applying uniaxial stretches, hydrogel filaments prepared with concentrated SA/GL solutions reveal a high tensile strength of 36.6–161.3 MPa, Young's modulus of 59.2–1964.2 MPa, and elongation at break of 8.5 %–106.2 % due to the high orientated and closely packed SA chains. SA/GL solutions become more solid-like with increasing SA concentration, and the solution with a solid content of 16 wt.% exhibits optimal 3D printability because of the appropriate rheological properties and thixotropic behavior. By designing the deforming-and-fixing process, 3D printed high-strength alginate hydrogels with complex structures are prepared, broadening the application of alginate hydrogels in load-bearing and biomedical fields.
基金supported by the National Natural Science Foundation of China(Nos.52371093 and 52171104)the National Key Research and Development Program of China(No.2021YFB3701100)the Chongqing Research Program of Basic Research and Frontier Technology,China(Nos.CSTB2023NSCQ-BSX0036 and cstc2021ycjh-bgzxm0086).
文摘The low strength of Mg-Li alloys sets a limit to lightweight applications.Introducing crystal defects(twins,dislocations,and SFs)is a distinctive strategy for maintaining good mechanical properties of metallic materials.A lamellar-structured Mg-4Li-3Al-0.4Ca alloy with high performance was prepared by hot extrusion and rotary swaging.The as-swaged alloy exhibits excellent mechanical properties with tensile strength,yield strength,elongation to failure,and specific strength of 391 MPa,312 MPa,14.2%,and 238.4 kN m kg^(-1),respectively.The average grain size of the as-swaged alloy is 160±23 nm,and the microstructure is mainly composed of lamellar structures,twins,ultrafine grains,and nano-grains.The abundant lamellar structures and twins promote the storage of dislocations and SFs,leading to the formation of twin-twin interactions and enhancing strain hardening.The formation of UFG and NG by dynamic recrystallization further improves the yield strength.Shearable second phases play a critical role in enhancing the yield strength and ductility.More importantly,extensive planar dislocation glide and(c+a)dislocations efficiently relax the local stress concentrations,and thus improve the ductility.
基金supported by the National Natural Science Foundation of China(Grant Nos.51979099&51774109)Natural Science Foundation of Jiangsu Province of China(Grant No.BK 20191303)+2 种基金Key Research and Development Project of Jiangsu Province of China(Grant No.BE2017148)Postgraduate Research&Practice Innovation Program of Jiangsu Province(Grant No.KYCX22_0632)Suqian Sci&Tech Program(Grant No.K202113).
文摘The dilemma of choosing between superb grain boundary strengthening and excellent precipitation strengthening is commonly faced in the pursuit of high-strength age-hardenable Mg alloys.Here,a strategy for addressing this dilemma via the balance between grain refinement and weakening of dynamic precipitation is proposed and applied on a Mg-10.95Gd-2.06Ag(wt%)alloy treated by sequential processing of equalchannel angular pressing(ECAP),hot rolling and aging.The hot rolling leads to a noticeable dissolution of the dynamic precipitates intensively formed during prior ECAP,together with a tolerable grain growth.Meanwhile,numerous multi-twinning-induced lamellar bands(LBs)demarcated by coaxial grain boundaries(CGBs)subdivide the grains.For the first time,a quadruple twinning pattern for the formation of CGB with a misorientation of~135°is raised.During post-rolling aging,besides the commonβ’andγ”precipitates and theβnano-particles whose Gd/Ag ratio is much lower than that of dynamically precipitatedβparticles,theβ”/βT precipitates,CGB segregation,and stacking fault(SF)-associated segregation/γ’precipitates within LBs,are also involved with the precipitation structure.Benefiting from this complex precipitation structure,a good age-hardening ability manifested by the aging-induced tensile yield strength(TYS)increment reaching 115 MPa is attained.Combining with the strengthening from grain boundaries,dislocations,solutes,and basal texture,a high TYS of 447 MPa is achieved.
基金the financial support of this work by the National Natural Science Foundation of China(Grant 21878089).
文摘Polypropylene(PP)has a relatively low melt strength due to its linear structure,which seriously limits its supercritical CO_(2)foaming performance.Introducing long-chain branches(LCBs)via grafting can significantly enhance its melt strength.However,the relationship between the LCB level of high melt strength polypropylene(HMSPP)and its foaming behavior remains unclear.In this study,a series of HMSPP with different LCB levels was prepared using vinyl polydimethylsiloxane(VS)of varying viscosities as grafting monomers to investigate this relationship.Rheological analysis showed that the increase in viscosity of VS led to higher LCB levels in HMSPP.The melt strength of HMSPP increases with the increase of LCB levels,reaching up to 0.62 N,which is 13 times higher than that of the raw material.Supercritical CO_(2)foaming results revealed that the expansion ratio of HMSPP first increased and then decreased with the increase of melt strength,reaching a maximum of 39.4 times.Combining experiments with simulations,the influence of LCB levels on the dissolution and diffusion behavior of CO_(2)in HMSPP was clarified.This study deepens the understanding of the relationship between LCB and the foaming behavior of HMSPP,providing valuable insights for designing HMSPP with optimized foaming properties.
基金supported by HBIS Group under the Grant No.IRIS 200506003.
文摘Different stress states have a significant influence on the magnitude of the microscopic plastic strain and result in the development of the microstructure evolution.As a result,a comprehensive understanding of the different scale variation on microstructure evolution during bending deformation is essential.The advanced high strength dual-phase(DP1180)steel was investigated using multiscale microstructure-based 3D representative volume element(RVE)modelling technology with emphasis on understanding the relationship between the microstructure,localised stress-strain evolution as well as the deformation characteristics in the bending process.It is demonstrated that the localised development in bending can be more accurately described by microscopic deformation when taking into account microstructural properties.Microstructure-based 3D RVEs from each chosen bending condition generally have comparable localisation properties,whilst the magnitudes and intensities differ.In addition,the most severe localised bands are predicted to occur close to the ferrite and martensite phase boundaries where the martensite grains are close together or have a somewhat sharp edge.The numerically predicted results for the microstructure evolution,shear bands development and stress and strain distribution after 3-point bending exhibit a good agreement with the relevant experimental observations.
基金supported by National Natural Science Foundation of China(No.U21A2048)the Science and Technology Research Program of the Chongqing Municipal Education Commission(No.KJZDK202201108)+2 种基金Academician in Chongqing Leaded Guidance Project of Science,Technology Innovation(No.CSTB2023YSZX-JCX0006)the Science and Technology Research Project of Chongqing Municipal Education Commission(No.KJQN202101126)Chongqing Natural Science Foundation(No.CSTB2024NSCQ-MSX0574).
文摘This article reports a systematic investigation on the relationship between the microstructure evolution and mechanical properties of as-cast Mg-9.5Gd-2.3Y-1Zn-0.5Zr(VW92,wt.%)alloy during aging treatment.The results indicate that the alloy exhibits obvious double peak-aging characteristics at 180℃,200℃,and 220℃;the first peak-aging appeared at 96 h,48 h,and 48 h,respectively,while the second peak-aging occurred at 204 h,180 h,and 180 h,respectively.Moreover,the strengths of the first peak-aging were higher than those of the second peak-aging.Consequently,the first peak-aging at 200℃ achieved the best mechanical properties,with ultimate tensile strength(UTS),yield strength(YS),and elongation(EL)of 380(±2.0)MPa,255(±1.8)MPa,and 12.8(±1.7)%,respectively.While the strength decreased in the second peak-aging,the elongation increased to 17.2(±0.5)%.The first peak-aging strengthening is ascribed to the participation of the nano-β' phases in the matrix and the long period stacking ordered(LPSO)phases at grain boundaries(GBs).Additionally,the second peak-aging strengthening is associated with the emergence of a relatively new 3D structure comprising longchain-like structural phases β'+β'_(F) tβ_(1),γ' phases,and LPSO phases within the grain,combined with the fine and uniform LPSO phases at the GBs.
基金supported by the National Natural Science Foundation of China(22278140,U22B20143)the Science and Technology Commission of Shanghai Municipality(22DZ1205900)Project supported by Shanghai Municipal Science and Technology Major Project,the Fundamental Research Funds for the Central Universities。
文摘The polycarbonate(bisphenol A)/acrylonitrile—butadiene—styrene(PC/ABS)features excellent mechanical properties,but its high flammability poses a potential safety hazard in practical applications.Although the incorporation of halogen-free additives enhances flame retardancy,it often leads to substantial smoke emission and compromises the mechanical properties of PC/ABS alloy.Therefore,simultaneous enhancement of both flame retardancy with low smoke and mechanical properties holds significant practical value for material development.Herein,a low-smoke PC/ABS composite with balanced flame retardancy and mechanical properties was achieved through an efficient ternary flame retardant system containing bisphenol A bis(diphenyl phosphate)(BDP),potassium-4-(phenylsulfonyl)benzenesulfonate(KSS),and 3-glycidyloxypropyltrimethoxysilane-modified boehmite(m-BM).PC/ABS/BDP6/KSS2/m-BM2 can achieve the same flame retardant level(V-0)as PC/ABS/BDP14,and the limiting oxygen index is increased to 26.8%.Meanwhile,the tensile strength and impact strength are increased by 16.1%and 81.4%respectively.The ternary system can significantly inhibit the release of smoke and heat,under the same flame retardant load(10%(mass)),the total heat release and total smoke production of PC/ABS loaded with ternary flame-retardant system decreased by 18.1%and 21.9%respectively compared to only BDP loaded.This ternary flame-retardant system provides a practical solution for developing high-performance,low-smoke flame-retardant PC/ABS composites.
基金financially supported by the National Key R&D program(No.2022YFB3707501)the GDAS’Project of Science and Technology(No.2022GDASZH-2022010202)the Guangdong Provincial Project(Nos.2022A0505050053,2021B1515120071,and 2020B1515130007)。
文摘Austenitic stainless steels(ASSs)are widely used in various in-dustries such as aerospace,nuclear energy,food,and biotechnol-ogy owing to their exceptional combination of corrosion resistance,weldability,toughness,and formability[1,2].However,a signifi-cant drawback of ASSs is their low yield strength,which limits their applications in extreme environments[3].Grain boundary(GB)engineering plays a crucial role in enhancing the strength of ASSs[4,5].For instance,grain refinement techniques such as cold rolling followed by annealing[6],severe plastic deformation(SPD)[7],and surface mechanical attrition/rolling treatments[8,9]introduce high-angle GBs(HAGBs)into ASSs,thereby improving their strength.However,the high density of HAGBs limits their ca-pacity for dislocation storage and multiplication,leading to a sig-nificant loss of ductility[10,11].Additionally,several studies have shown that twin boundaries(TBs)can simultaneously enhance the strength,toughness,and corrosion resistance of ASSs[12,13].
基金supported by the National Key Research and Development Program of China(No.2021YFB3701000)the National Natural Science Foundation of China(Nos.51971130,52201129,U21A2047,51821001,U2037601)。
文摘Laser powder bed fusion(LPBF)of Mg alloys mainly focuses on the traditional commercial casting Mg alloys such as AZ91D,ZK60 and WE43,which usually display relatively low tensile strengths.Herein we developed a novel high-strength Mg-12 Gd-2 Y-1 Zn-0.5 Mn(wt.%,GWZ1221M)alloy for the LPBF additive manufacturing process,and the evolution of microstructure and mechanical properties from the as-built state to LPBF-T4 and LPBF-T6 states was systematically investigated.The as-built GWZ1221M alloy exhibited fine equiaxed grains with an average grain size of only 4.3±2.2μm,while the as-cast alloy displayed typical coarse dendrite grains(178.2±73.6μm).Thus,the as-built alloy showed significantly higher tensile strengths than the as-cast counterpart,and its yield strength(YS),ultimate tensile strength(UTS)and elongation(EL)were 315±8 MPa,340±7 MPa and 2.7±0.5%respectively.Solution treatment transformed hard and brittleβ-(Mg,Zn)_(3)(Gd,Y)phase into basal X phase and lamellar long period stacking ordered(LPSO)with better plastic deformability,leading to the improvement of EL.Then peak-aging heat treatment introduced numerous nano-sized prismaticβprecipitates inside grains,resulting in the enhancement of YS.Finally,the LPBF-T6 alloy achieved appreciably high strength with YS,UTS and EL of 320±3 MPa,395±4 MPa and 2.1±0.4%respectively.Both as-built and LPBF-T6 GWZ1221M alloys showed remarkably higher tensile strengths than the as-cast counterparts and as-built commercial Mg alloys,highlighting the great potential of high-strength as-built Mg-Gd based alloys for structural applications.
文摘The moment a media delegation from the Republic of the Congo arrived at the Othello Kitchenware Museum on 18 November 2025,they were greeted with a vivid show of Guangdong’s industrial strength.Standing before them was not a typical exhibition hall,but a building shaped like a gleaming stainless-steel cooking pot.
基金Project (50271054) supported by the National Natural Science Foundation of ChinaProject (20070700003) supported by the Doctorate Programs Foundation of Ministry of Education of China+1 种基金Project (102102210031) supported by the Science and Technologies Foundation of Henan Province, ChinaProject (2010A430008) supported by the Natural Science Foundation of Henan Educational Committee of China
文摘Fine-grained Mg-6Zn-4Y alloy was prepared by an ingot metallurgy process with hot extrusion at 300 ℃.The microstructure was studied by XRD,OM,SEM and TEM,and the tensile properties were tested at room temperature.The results show that the alloy is composed of α-Mg and W-phase.The microstructure of the as-extruded alloy has a bimodal grain size distribution.The fine grains with the mean size of 1.2 μm are formed by dynamic recrystallization.The coarse grains(about 23% in area fraction) are unrecrystallized regions which are elongated along extrusion direction.The engineering stress—strain curve shows a pronounced yield point.The ultimate tensile strength,yield strength,and elongation are(371±10) MPa,(350±5) MPa and(7±2)%,respectively.The high strengths are attributed to the fine-grained matrix structure enhanced by W-phase particles,nano-scaled precipitates,and strong basal plane texture.
文摘Eight high strength concrete (HSC) prisms strengthened with continuous carbon fiber sheet(CFS)were tested.As a result of the confinement provided by CFS,the concrete would fail at a greater strain than the unconfined and then a significant increase in ductility can be achieved.The lateral pressure exerted by CFS would increase the compressive strength of the concrete,resulting in higher load bearing capacity.This paper proposes the stress strain curve of this kind of hybrid specimen,which agrees well with the test results.Based on the stress strain relationship and the assumptions proposed in this paper,a computer program was developed to analyze HSC columns,confined by CFS,which were subjected to axial compression and biaxial bending.The results shown in this paper indicate that the ductility of HSC column is significantly improved and the strength is also increased by some degree.
文摘Aim To research on a solid cemented carbide multi facet drill for drilling high strength steel. Methods Assimilating some features of multi facet drill edge structures, through systematic drilling experiments, a new type of solid cemented carbide drill was developed and the drill geometry was optimized. Results With the new type drill,the drilling force decreases by 10%-20%, the drilling productivity (drilled holes per hour) increases by 2-3 times, and the drilling precision and surface finish increase by one level. Conclusion The new type drill possesses excellent drilling performance.
文摘Based on experiments, a computer program is developed. The calculated results agree well with the experimental results. The flexural behavior of T shaped high strength concrete members subjected to axial compression and biaxial bending is studied. The main factors affecting the flexural behavior of T shaped high strength concrete members are loading angle, axial compression ratio and reinforcement ratio.
