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简介:WithFe(NO3)39H2OandBi(NO3)35H2Oasrawmaterials,differentsillenite-typecompoundsandelementalbismuthwerepreparedbyafacileone-potsolvothermalmethodusingH2O,C2H5OH,(CH2OH)2andC3H8O3assolvents,respec-tively.Thestructure,morphology,elementalcompositionsandpropertiesofsampleswereexaminedbyXRD,SEM,TEM,ICP,XPS,N2adsorptionanddesorption,UV-visDRSandPL.ThephotocatalyticactivitiesofdifferentsampleswereevaluatedbythephotodegradationofRhBundervisible-lightirradiation(λ>400nm),andresultsshowthatBi36Fe2O57preparedusingC2H5OHasthesolventownstheoptimumperformance.Inordertoexplorethereactionmechanism,anadditionalexperimentwasdesignedtoinvestigatethemainactivespeciesduringthephotodegradationprocessviadissolvingdifferenttrappingagentsinthereactionsolutionbeforelightirradiation.TheresultsshowthatsuperoxideradicalanionsplayamajorroleinthissystemsincetheRhBdegradationwassignificantlysuppressedaftertheadditionofbenzoquinone.
简介:以两种Al2O3-Al2TiO5复合粉体为原料经SPS烧结制备出Al2O3-Al2TiO5复相陶瓷。采用纳米结构复合粉体烧结而成的复相陶瓷有着较优的力学性能,特别是具有较高的断裂韧性和硬度,与其较小的晶粒尺寸相对应。干滑动摩擦磨损试验在4N和6N法向载荷下进行,结果表明,采用微米结构复合粉体烧结而成的复相陶瓷磨损表面较光滑,体积磨损量较小。在磨损试验中,纳米结构复合粉体烧结而成的复相陶瓷的破坏方式为沿晶断裂,有明显的晶粒拔出现象;微米结构复合粉体烧结而成的复相陶瓷呈不连续的微观断裂并产生塑性变形;同时,两种材料在摩擦磨损过程中都发生接触面的氧化和物质转移。
简介:介绍了通过采用水热法合成由纳米片自组装的类球形3D“微纳结构”FeP04·2H2O前驱体,再通过流变相锂化方法在650℃氩气气氛下加热10h,得到3D“微纳结构”LiFePO4锂离子电池正极材料。使用XRD、SEM对产物的晶型和形貌结构进行表征,表明该3D“微纳结构”FeP04·2H2O是由约100nm长、30nm厚的纳米片自组装而成。对该LiFePO4的电化学性能进行测试,结果显示该材料在10C、20C、30C时比容量分别达到116mAh/g、96mAh/g和75mAh/g。同时,该材料的振实密度测试结果为1.4g·cm-3这表明3D“微纳结构”的LiFeP04能较好地兼顾良好的倍率性能和较高的振实密度。
简介:Three-dimensional-printed(3D-P)titaniumimplantsdisplaymanyadvantages,suchasdesignflexibility,higherefficiency,thecapabilitytoeasilyconstructcomplexorcustomizedstructures,etc.,andisbelievedtopotentiallyreplacetraditionalimplants.However,thebiologicalperformanceofthe3D-Ptitaniumsurfacehasnotbeeninvestigatedsystematically.Herein,weanalyzedthesurfacecharacteristicsof3D-PTi6AI4Vimplantsandevaluatedthebiologicalresponsesofbonemarrowderivedmesenchymalstromalcells(BMSCs)tothe3D-Psurfaceinvitro.Moreover,afterimplantationintotheratfemoralcondylefor3and6weeks,theosseointegrationperformaneewasevaluated.Theresultsshowedthe3D-PTi6Al4Vimplantpresenteddistinctfluctuantmacroscaleroughsurfaceandrelativelybetterhydrophilicitywhichenhancedtheadhesion,proliferation,osteogenicdifferentiationandangiogeneticfactorexpressionofBMSCs.Moreover,theinvivoosseointegrationperformancewasalsobetterthanthatofthecontrolgroupattheearlystage.Thepresentstudysuggestedthe3D-Ptitaniumalloyisapromisingcandidatetobeusedasimplantmaterial.
简介:采用机械球磨技术制备了MgH2-10%Al2O3(质量分数)储氢复合体系,通过XRD、SEM、DSC-TG等检测手段考查了微量Al2O3陶瓷颗粒掺杂对MgH2体系组织结构及解氢性能的影响,并对其相关机理进行了分析.结果表明:机械球磨可有效细化MgH2颗粒;在微量Al2O3陶瓷颗粒与机械球磨的协同作用下,MgH2颗粒的细化效果更为显著;相对于纯MgH2球磨体系而言,微量Al2O3的掺杂有效降低了MgH2体系的解氢温度(降低近50℃),且其解氢速率也有所提高;MgH2-Al2O3储氢复合体系解氢性能的改善主要源于Al2O3陶瓷颗粒对MgH2体系的组织细化效应.
简介:钛酸锶钡(BST)陶瓷是一种性能优异的电容器材料、热敏材料和铁电压电材料,具有非常广阔的应用领域。采用溶胶-凝胶法合成了Ba0.6Sr0.4TiO3纳米粉体,通过X射线衍射仪(XRD)、扫描电子显微镜(SEM)、激光粒度分析仪对粉体的物相组成、颗粒大小和形态进行了分析,利用红外光谱仪(FT~IR)研究了表面活性剂在合成纳米Ba0.6Sr0.4TiO3过程中的作用,并重点考察了表面活性剂对Ba0.6Sr0.4TiO3粉体性能的影响。研究结果表明,通过添加适量的表面活性剂能有效改善纳米钛酸锶钡粉体的表面性能,使纳米钛酸锶钡具有较好的分散性,可充分发挥材料的纳米效应。
简介:Anitrate-citratecombustionroutetosynthesizeLa0.9Sr0.1Ga0.8Mg0.2O3-δpowderforsolidoxidefuelcellapplicationwaspresented.Thisrouteisbasedonthegellingofnitratesolutionsbytheadditionofcitricacidandammoniumhydroxide,followedbyanintensecombustionprocessduetoanexothermicredoxreactionbetweennitrateandcitrateions.TheoptimumtechnicalparametersarethatthepHvalueis5,andthemolarratioofcitricacidtothetotalmetallicionis1.5:1.X-raydiffractioncharacterizationofcalcinedgelshowsthatpurephasewassynthesizedaftercalcinationat1400℃for10h,andtheTEMresultshowsthecalcinedpowderwithaverageparticlesizeisabout150nm.Thegrainresistancecontributestothetotalresistanceofsinteredpelletbelow500℃.Theconductivityofthesinteredpellentat800℃was0.07S-1.cm-1higherthantheconductivityofYSZ(0.05S-1.cm-1at800℃)
简介:采用柠檬酸溶胶-凝胶法制备了稀土Gd3+掺杂的LaPU新型热障涂层用陶瓷粉体LaPO4(X=0.0,0.1,0.2,0.3;LGPO)。通过X-ray衍射、扫描电子显微镜、TpDSC、高温热膨胀仪和激光热导仪对样品的相组成、微观形貌、热行为、热膨胀系数和热导率进行表征。结果表明:稀土Gd3+掺杂的LGPO保持了独居石相结构;添加稀土Gd3+不仅可以降低材料的导热系数,还有利于其热膨胀系数的提高;随着稀土Gd3+掺杂量的增加,晶体中点缺陷浓度不断升高,声子平均自由程不断减小,使得稀土Gd3+掺杂的LGPO的热导率在x=0.3时达到最低值(λ=1.22w/(m·K),T=1273K),该值明显低于同温度下8YSZ的热导率。Gd3+掺杂的LaPO4体系是下一代新型热障涂层用陶瓷热门的候选材料之一。