简介:PolycrystallinesamplesofLa12x(Sr12yAgy)xMnO3(y=0.0,0.2,0.4,0.6,1.0)werepreparedbythesolid-statereactionmethod.ThetemperaturestabilityofmagnetoresistanceandmagnetoresistanceenhancementinLa1-x(Sr1-yAgy)xMnO3systemwithbothunivalentandbivalentelementsdopedatAsiteandwithunchangedvalueofMn3+/Mn4+ratiowereexploredthroughthemeasurementsofX-raydiffractionpatterns,magnetiza-tion-temperature(M-T)curves,resistivity-temperature(q-T)curvesandmagnetoresistance-temperature(MR-T)curves.Theresultsareasfollows:therearetwopeaksintheq-TcurvesofthesampleswithAgdoping,oneiscausedbyresistancechangeduringtheparamagnetism-ferromagnetismtransition,andtheotherisfromboundary-dependentscatteringofconductionelectronsontheboundariesofgrains.ThepeakvalueofMRincreaseswithincreasingAgdopingcontent,anditincreasesfrom8.2%fory=0.2to29.6%fory=1.0underthemagneticfieldofB=0.8T;MRremainsaconstantof12%inthetemperaturerangeof218-168Kforthesamplewithy=1.0,andthetemperaturestabilityofMRisinfavorofthepracticalapplicationofMR.
简介:Inthiswork,transformationbehaviorsandmechanicalpropertiesofcold-rolledshapememoryalloyTi50Ni49Fe1bysevereplasticdeformation(SPD)wereintensivelyinvestigated.Thephasetransformationbehaviors,phaseanalysis,andmicrostructureswerecharacterizedbydifferentialscanningcalorimetry(DSC),X-raydiffraction(XRD),andtransmissionelectronmicroscopy(TEM),respectively.TensiletestingwasperformedtoanalyzetheeffectofSPDonthemechanicalpropertiesandshapememoryofTi50Ni49Fe1alloy.Whenthethicknessreductionisbeyond30%,themartensitictransformationissuppressed.Aftercold-rolling,thealloyismainlycomposedofB2parentphaseswithsomestress-inducedmartensiticB190phases,andhighdensityofdislocationsaregeneratedandthegrainsareobviouslyrefined.Theyieldstressrbsignificantlyraisesfrom618MPaof0%coldrollingto1,338MPaof50%SPD.Shape-memoryeffectincreasesfrom6.5%withoutcoldrollingto8.5%after30%SPD,ascribedtotheinduceddefectsincoldrolling.ThoseresultsindicatethatTi50Ni49Fe1alloyhasimprovedmechanicalpropertiesandpotentialcommercialapplicationsafterSPD.
简介:采用Gleeble热模拟方法研究Mg-6Zn-1Al-0.3Mn变形镁合金在温度为200-400°C,应变速率为0.01-7s-1条件下的热压缩变形行为。结果表明,变形温度和应变速率显著影响其热变形行为。通过计算获得了热变形激活能及应力指数分别为Q=166kJ/mol,n=5.99,且其本构方程为ε&=3.16×1013[sinh(0.010σ)]5.99exp[-1.66×105/(RT)]。热压缩显微组织观察表明:在应变速率为0.01-1s-1的条件下,在250°C热压缩变形时初始晶粒晶界及孪晶处发生了部分动态再结晶,而在高温(350-400°C)条件下,发生了完全动态再结晶且再结晶晶粒尺寸随着应变速率的增加而减小。获得的较优的变形条件为温度330-400°C、应变速率为0.01-0.03s-1以及350°C、应变速率为1s-1。
简介:激光冲击强化是一种新型表面处理技术,利用高功率激光束冲击金属零件表面,在零件表面形成较大的残余压应力,可有效改善零件的疲劳性能。以发动机1Cr11Ni2W2MoV叶片为研究对象,对其进行了激光冲击强化处理,研究强化处理对材料的微观组织和疲劳性能的影响。研究结果表明:相比未处理试样,激光冲击强化在1Cr11Ni2W2MoV叶片材料表层形成较大的残余压应力,表层晶粒更为细化,叶片的疲劳寿命提高1.7倍。