K_5CoW_(12)O_(40)·3H_2O催化合成环己酮1,2—丙二醇缩酮

研究了杂多化合物K_5CoW_(12)O_(40)·3H_2O作为催化剂对环己酮和1,2-丙二醇缩酮的催化活性。系统考察了酮醇物质的量比、催化剂质量、带水剂体积、反应时间和催化剂重复使用性等因素对产品收率的影响。实验结果表明,杂多化合物K_5CoW_(12)O_(40)·3H_2O是合成环己酮1,2-丙二醇缩酮的良好催化剂,在酮醇物质的量比为1:1.4、催化剂质量为0.5 g、带水剂环己烷体积为9 mL、反应时间为70 min的最佳条件下,环己酮1,2-丙二醇缩酮的收率最高可达94.2%。

La_(2)O_(3)掺杂SiO_(2)-B_(2)O_(3)-Nb_(2)O_(5)复相微晶玻璃相界及储能性能研究

采用可控析晶法制备了La_(2)O_(3)掺杂的SiO_(2)-B_(2)O_(3)-Nb_(2)O_(5)(SBN)复相微晶玻璃,利用DSC、Raman、XRD、SEM、铁电和介电性能测试等分析表征了La_(2)O_(3)掺杂对SBN复相微晶玻璃结构与储能性能的影响。结果表明:La_(2)O_(3)掺杂能够有效提高复相微晶玻璃的热稳定性,随着La_(2)O_(3)含量增加,系统析晶势垒增大,热膨胀系数先降低后升高,价键振动加剧,介电常数先增大后减小,介电损耗先减小后增大;掺杂1.00%(摩尔分数)La_(2)O_(3)时,复相微晶玻璃在40 kV/cm电场下的储能密度和储能效率最大,分别为0.031 J·cm^(-3)和77.6%;储能性能主要通过介电常数和击穿场强的协同作用来评价,La_(2)O_(3)能通过提高结构热稳定性和降低介电损耗来提高介电常数,当其引入体系后处于玻璃网络的空隙中,可有效增强材料耐击穿性能;复相微晶玻璃结构可以增加结构无序度,从而降低弛豫损耗,有效提高材料的储能性能。

新铌酸盐K_6CrNb_(15)O_(42)

在K_2O—Cr_2O_3—Nb_2O_5三元系统中,作者发现一种六方晶系化合物K_6CrNb_(15)O_(42)。将分析纯K_2CO_3、Cr_2O_3、Nb_2O_5按分子比6:1:15混匀(随温度制度不同,K_2CO_3可略过量),在中性保护气氛下于1350℃到1060℃间加热,保温一定时间,得到晶粒细小,但很纯净的未知晶体(可用来作X射线粉晶谱、化学分析及其它测试)。延长保温时间并在更低温度出炉,则可获得较大晶粒,个别晶粒可大于2mm,从中可选出生长良好的单晶体作X射线单晶衍射。后一方法可能出现杂质K_2Nb_(16)O_(41)。

非醇盐法制备铌酸钾钠薄膜的工艺及性能研究

为了利用低成本的Nb_(2)O_(5)为原料在传统硅衬底上制备高质量的K_(0.5)Na_(0.5)NbO_(3)(KNN)薄膜,利用溶胶-凝胶法非醇盐法制备KNN薄膜,对比了典型和改良的两种工艺流程,并利用表征工具分析两种工艺制备薄膜结构和性能。同时,通过改良的工艺制备不同层数的薄膜,利用表征工具和理论计算分析层数对KNN薄膜的晶体结构、应变、表面形貌和电性能的影响。XRD结果表明利用改进的工艺可以在硅衬底上制备出(100)高度择优取向的KNN薄膜,薄膜的最佳热解温度从500℃降低为150℃,并且薄膜的介电性能和铁电性能都得到改善。利用Scherrer和SSP公式计算表明随着薄膜层数的增加,薄膜的晶粒尺寸随之增加,晶相由四方相向立方相转变。当层数为14层时,观察到这种转变,此时薄膜应变达到最低值。SEM再次表明随着层数的增加,薄膜的晶粒尺寸随之增加,薄膜表面缺陷也得到改善。在层数为18时,1 kHz下薄膜的介电常数值达到最大值622.9。

New insights into the relationships between performance and physicochemical properties of FeO_(x)-NbO_(x)mixed oxide catalysts for the NH_(3)-SCR reactions

In this study,we prepared Fe_(2)O_(3)-Nb_(2)O_(5)binary mixed oxide catalysts using co-precipitation(CP),sol-gel(SG),and solid process(SR)methods and tested their performance.All the catalysts exhibited over 75%NO_(x)removal efficiency between 250℃and 400℃.Compared with the samples prepared by the SR method,catalyst synthesized using CP and SG methods possessed a larger specific surface area,which could compensate for the lower surface area-normalized reaction rate originat-ing from the insufficient reactive surface oxygen species,hence exhibiting a relatively high low-temperature apparent deNO_(x)activity.However,at a high-temperature region,limited amount of reactive surface oxygen species,together with abundant strong acid sites,facilitated the proceeding of NH_(3)reduction of NO_(x),which well explained the higher apparent activity of the catalyst prepared by SG method than the other two samples.It seemed that specific surface area had an important role to play in the low-temperature apparent performance of the catalysts,while chemical properties mainly decided the activity at an elevated temperature.