简介:双相不锈钢1Cr18Ni11Si4AlTi由前苏联研制,目前在我国某些特殊行业中有重要的作用。根据我国现有标准GJB2294—95和GB/T1220—92组织生产,发现按标准中现行成分设计、热处理制度生产的产品与标准要求的力学性能(屈服强度σ0.2)需达到的规定值存在较大差异,很难达到所需要的屈服强度。通过完善相关成分和工艺参数,获得了满意的金相组织和优良的综合力学性能。通过试验探讨了生产实际与标准中的部分规定存在的差距。
简介:Er^3+-dopedSrBi4Ti4O15-Bi4Ti3O12(SBT-BIT-xEr^3+,x=0.00,0.05,0.10,0.15and0.20)inter-growthceramicsweresynthesizedbythesolid-statereactionmethod.Structural,electricalandup-conversionpropertiesofSBT-BIT-xEr^3+wereinvestigated.Allsamplesshowedasinglephaseoftheorthorhombicstructure.RamanspectroscopyindicatedthattheEr^3+substitutionforBi^3+atAsitesofthepseudo-perovskitelayerincreasesthelatticedistortionofSBT-BIT-xEr^3+ceramics.ThesubstitutionofBi^3+byEr^3+leadstoadecreaseofdielectriclosstanδandanincreaseofconductivityactivationenergy.Piezoelectricconstantd33wasslightlyimproved,butdielectricconstantwasdecreasedwiththeEr^3+doping.TheSBT-BIT-xEr^3+ceramicwithx=0.15exhibitstheoptimizedelectricalbehavior(d33~17pC/N,tanδ~0.83%).Moreover,twobrightgreen(532and548nm)andonered(670nm)emissionbandswereobservedunderthe980nmexcitation.Optimizedemissionintensitywasalsoobtainedwhenx=0.15fortheSBT-BIT-xEr^3+ceramic.Therefore,thiskindofceramicsoughttobepromisingcandidatesformultifunctionaloptoelectronicapplications.
简介:四氧化四银(Tetrasilvertetxoxide,Ag4O4)是一种具有活跃电子、反磁性和半导电性的分子晶体,可与表面裸露的蛋白质-N基(-NH,-NH2)和-S基(S-S,-SH)发生热力学吸附并触发氧化还原反应,改变微生物蛋白质构象而起到抑菌效果,具有潜在应用价值。为了开发基于纳米高价银氧化物的生物医用材料,采用软化学方法制得Ag4O4,并利用扫描电镜、纳米粒度与电位分析仪、X射线衍射仪、热分析仪和激光显微拉曼光谱仪对其理化性质进行了表征,利用抑菌圈法和液体光电比浊法对其抗茵性能进行了评价。结果表明,实验制备的四氧化四银性质完全符合预期,抗茵性能优良,为进一步研制抗菌性能良好的医用材料提供了有益借鉴。
简介:1.IntroductionLightrareearthadditioncanremarkablyenhancetheservicelifeofFe-Cr-Alalloyforelectricalheatingelement,butitscontentinthealloymustbecontrolledbelowthelevelof0.1wt-%.Whenthecontentexceedsthat,theperformance
简介:Si3N4/TiCnanocompositeceramicshavebeenfabricatedbyhotpressingtechniquewithAl2O3andY2O3asadditives.TheresultsshowedthatwelldispersedcompositepowderwascarriedoutbyaddingdispersantandadjustingpHvaluesofsuspensions.RemarkableincreaseinflexuralstrengthatroomtemperatureswasobtainedbyaddingnanoparticlesinSi3N4matrixwith10%(wtpct)ofnano-Si3N4and15%ofnano-TiC.Theflexuralstrength,fracturetoughnessandhardnesswere1025MPa,7.5MPa·1/2and15.6GPa,respectively.Themicrostructuresofmaterialswereanalyzedbyscanningelectronmicroscopy(SEM)andtransmissionelectronmicroscopy(TEM),whichindicatedthatTiCnanoparticlesdistributeinthematrixandatthegrainboundaries.Accordingtothefractureform,lowcontentsofnanoparticlescouldrefinematrixgrainsandleadtothecrackdeflectionaswellascrackpinning.Themultiplexmicrostructurewasformedbymixingnano-Si3N4particles.Thecracktrajectoriesexhibitedcrackdeflection,rod-likegrainbridgingandpull-out.