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1.
磁性固体超强酸SO42-/ZrO2-Al2O3-Fe3O4的制备与性能研究   总被引:3,自引:0,他引:3  
利用化学共沉淀法将磁性基质与固体酸组装制备磁性纳米固体超强酸催化剂,利用XRD、Raman、TG-DSC、M?ssbauer、TEM、HRTEM等手段对样品性质进行表征。结果表明:磁性基质的引入赋予固体超强酸以超顺磁性;Fe3O4、Al2O3粒子弥散在ZrO2基质中,烧结过程中阻碍了扩散传质的进行以及晶界移动,抑制了ZrO2晶体生长,稳定了四方晶相(T-ZrO2);样品粒径分布集中,平均约为32 nm;HRTEM显示T-ZrO2晶体生长取向于(101)方向,晶面间距d(101)=0.29 nm;Hammett指示剂法测得经600 ℃焙烧后产物的酸强度Ho<-13.8,酸强度大于浓硫酸(Ho=-11.93)。以柠檬酸三丁酯的合成作为磁性固体超强酸SO42-/ZrO2-Al2O3-Fe3O4催化剂的探针反应,结果表明外磁场的引入提高了柠檬酸的转化率。  相似文献   

2.
将Fe2O3纳米粉体经一定浓度的H2SO4浸泡活化后制成纳米固体超强酸SO42-/Fe2O3,将其用于催化合成乙酸乙酯以考察其活性。利用均匀设计分析了超强酸制备过程及酯化反应过程中各因素的影响,研究结果表明较好的制备条件是:H2SO4浓度:2.5mol·L-1;浸泡时间:1h;活化温度:167℃;活化时间:1h,此时获得的固体超强酸SO42-/Fe2O3的粒径小于50nm。当催化剂用量为冰乙酸质量的5%,n(乙醇)∶n(冰乙酸)为3∶1,反应3.5h后乙酸的转化率高于80%。该催化剂经H2SO4溶液浸泡、活化再生后可重新使用,推断出其酸强度H0<-14.5。  相似文献   

3.
以硫酸盐为原料,添加NaOH和NaHCO3以制备出碱式碳酸盐前驱体,合成出新型的纳米固体超强酸催化剂SO42-/ZnFe2O4,经XRD、BET、IR等检测,粒径为35nm,比表面积很大(137m2-1),粒度均匀。首次以该固体酸为催化剂,癸二酸和无水乙醇为原料合成癸二酸二乙酯,考察了影响反应的因素。结果表明,醇酸摩尔比为4.0∶1,催化剂用量为1.0g(癸二酸0.1mol),带水剂苯15mL,反应时间2.5h是最佳反应条件,酯化率可达91%,并推断出该催化剂的酸强度-16.02< Ho< -14.52.  相似文献   

4.
通过浸渍法制备了5%ZrO2/MCM-41、5%ZrO2-5%M2O3/MCM-41(M=La,Ce,Sm,Gd)催化剂,考察其在苯乙酮氢转移还原生成-苯乙醇反应中的催化活性,同时对样品进行XRD、N2吸附-脱附、吡啶吸附原位红外等表征分析,研究添加稀土金属氧化物对催化剂活性的影响机理。结果表明:ZrO2及稀土金属氧化物均以无定型态或粒度低于XRD检测限的细小晶粒较好地分散在MCM-41介孔分子筛内表面;加入稀土金属氧化物对ZrO2/MCM-41的催化活性有较大影响,催化活性按5%ZrO2-5%La2O3/MCM-41>5%ZrO2-5%Sm2O3/MCM-41>5%ZrO2-5%Gd2O3/MCM-41>5%ZrO2/MCM-41>5%ZrO2-5%Ce2O3/MCM-41降低。这一方面归因于加入稀土金属氧化物增强了催化剂表面Zr-OH、L酸中心及B酸中心的酸性,另一方面归因于La2O3的加入使催化剂表面酸中心数目明显提高,Sm2O3、Gd2O3的加入使催化剂表面酸中心数目有所降低,而加入Ce2O3使催化剂表面酸中心数目显著减少。  相似文献   

5.
实验分别采用连续吸附法和传统浸渍法制备Cr/MCM-41催化剂(分别记为Cr/MCM-41-ad和Cr/MCM-41-imp),将制备的Cr/MCM-41催化剂用于丙烷非氧化脱氢制丙烯反应,并对反应过程中的温度、压力、空速等反应条件进行优化,在合适的条件即反应温度为630℃、压力为0.1 MPa、空速为4500 mL·h-1·g-1下比较两种方法制备的催化剂在丙烷脱氢制丙烯反应的催化性能.我们采用XRD、SEM-mapping、XPS、UV-vis、H2-TPR等表征手段对催化剂上α-Cr2O3晶体粒径、活性组分及分布等进行表征分析,结果表明Cr/MCM-41-ad和Cr/MCM-41-imp中同时均存在Cr(VI)、Cr(Ⅲ)和α-Cr2O3.其中XRD和SEM-Mapping结果可知,Cr/MCM-41-ad上获得的α-Cr2O3晶体粒径较小且分散性好;通过UV-vis、XPS和TPR结果证明Cr/MCM-41-imp催化剂存在非活性孤立态Cr(VI),较难还原,影响其反应活性.相比之下,吸附法制备的催化剂使Cr高分散,可避免形成非活性孤立态Cr(VI),进而提高丙烷脱氢催化活性.因此,吸附法制备的铬基催化剂用于丙烷脱氢制丙烯有一定的借鉴作用.  相似文献   

6.
采用共沉淀的方法制备了不同Fe 掺杂量的SO42-/SnO2-Fe2O3固体超强酸催化剂. 利用傅里叶变换红外(FTIR)光谱, 粉末X射线衍射(XRD), N2吸附-脱附实验(BET), 热重(TG)分析和扫描电镜(SEM)等方法对样品进行了表征. 考察了所得催化剂对4-叔丁基环己酮与乙二醇缩合反应的催化性能. 实验结果表明, 与未经过掺杂改性的SO42-/SnO2固体酸催化剂相比, 改性后催化剂的催化性能得到了改善. 研究了以Fe/Sn 摩尔比为0.5的SO42-/SnO2-Fe2O3固体酸为催化剂, 部分醛酮类化合物与乙二醇及1,2-丙二醇的缩合反应. 考察了反应时间、催化剂用量等因素对反应的影响. 同时, 将所得催化剂应用于环酮Baeyer-Villiger 氧化反应中, 催化剂表现出良好的催化活性, 且催化剂具有一定的循环使用性.  相似文献   

7.
采用一步共缩合-水热法合成酸性载体SO42-/ZrO2-SiO2,化学法接枝酸性离子液体磺酸功能化咪唑硫酸氢盐([Ps-im]HSO4),构筑拥有Brönsted与Lewis双酸位的离子液体固载型催化剂SO42-/ZrO2-SiO2-IL。采用X射线衍射、傅里叶红外、N2吸附-脱附、X射线光电子能谱、热重以及透射电镜对催化剂的结构进行表征,结果表明:锆原子和酸性结构SO42-被成功引入纯硅材料,所合成的载体具有一定酸性;离子液体成功固载于酸性介孔材料SO42-/ZrO2-SiO2,且固载后的催化剂保持其介孔结构。以大豆油和甲醇的酯交换反应为探针,考察了SO42-/ZrO2-SiO2-IL催化剂的催化性能。在反应温度为150℃、反应时间为4 h、催化剂量5%(w/w)、醇油物质的量之比为24:1的反应条件下,生物柴油的收率超过92%,且回收利用5次后,生物柴油的收率仍达86%。  相似文献   

8.
宋华  董鹏飞  张旭 《物理化学学报》2010,26(8):2229-2234
通过向SO2-4 /ZrO2催化剂中同时引入适量的Pt和Al2O3, 制备出了具有较高催化性能和稳定性的Pt-SO2-4 /ZrO2-Al2O3型固体超强酸催化剂. 以正戊烷异构化反应为探针, 考察了Al含量对催化剂性能的影响; 并采用X射线衍射(XRD)、比表面积测定(BET)、红外(IR)光谱、程序升温还原(TPR)、热重-差热分析(TG-DTA)和氨-程序升温脱附(NH3-TPD)手段对催化剂进行了表征. 结果表明, Al能够提高ZrO2的晶化温度, 抑制硫的分解, 增加催化剂的比表面积, 增强硫氧键的结合, 提高催化剂的还原性能, 增加催化剂的酸强度和酸总量. 当Al2O3含量(质量分数, w)为5.0%时, Pt-SO2-4 /ZrO2-Al2O3固体超强酸催化剂的催化活性最好, 在100 h内异戊烷收率可稳定在52.0%以上, 选择性在98.2%以上.  相似文献   

9.
通过微波辅助水热法合成MCM-41介孔材料,经溶胶凝胶组装过程将EuPO4∶Zn分散到MCM-41表面上和孔道中,制备成以MCM-41为基质的复合发光材料EuPO4∶Zn@MCM-41粉末。通过XRD、FTIR、氮吸附、SEM、HRTEM、EDS对该材料进行了表征,用单因素法探究了原料配比(Eu(NO3)3、Zn(NO3)2的加入量和反应条件(煅烧的温度、时间)对EuPO4∶Zn@MCM-41在593 nm处发光强度的影响,并研究其影响机理。荧光分析发现,EuPO4∶Zn基本不发射荧光,而EuPO4∶Zn@MCM-41材料具有蓝光段和红光段的荧光发射,主要发光带以468和593 nm为中心。593 nm处的发射归因于Eu3+的4f组内5D07F1跃迁,即Eu3+中心离子所在晶格格位对称性决定的磁偶极跃迁。研究表明以MCM-41为载体,能够大大降低颗粒的团聚程度,并使EuPO4:Zn颗粒具有更小的粒径;同时EuPO4∶Zn@MCM-41中Eu3+发光中心具有更大的裂分,MCM-41的纳米孔道使Eu3+的发光中心分离,降低了Eu3+之间电子云之间的重叠,大大减小了荧光的猝灭,因此MCM-41能有效降低Eu3+复合物荧光猝灭。  相似文献   

10.
采用十二胺为模板剂、氨水做沉淀剂成功制备了介孔α-Fe2O3, 通过粉末X射线衍射(XRD)、透射电镜(TEM)、N2吸附/脱附技术对样品晶相、形貌和比表面积进行了表征. 根据介孔α-Fe2O3悬浮液的酸碱滴定数据, 使用FITEQL软件, 采用双电层恒电容模型计算得出了介孔α-Fe2O3的表面酸碱反应平衡常数. 在此基础上研究了Cu2+, Pb2+, Zn2+在介孔氧化铁表面的吸附行为, 使用WinSGW软件模拟得出了相应的表面配合反应平衡常数并讨论了其吸附机理.  相似文献   

11.
phase diagrams of KCl-KBO2-K2CO3, K2MoO4-KBO2-K2CO3, and K2WO4-KBO2-K2CO3 ternary systems were studied by a calculation-experimental method and differential thermal analysis (DTA). The coordinates of ternary eutectics were determined to be E 1: 622°C, 8.5 mol % KBO2, 56.5 mol % KCl, and 35 mol % K2CO3; E 2: 710°C, 23 mol % KBO2, 43 mol % K2CO3, and 34 mol % K2MoO4; E 3: 710°C, 23 mol % KBO2, 43 mol % K2CO3, and 34 mol % K2WO4. The specific heats of melting of the eutectics were determined.  相似文献   

12.
Solubility in the Na2Cr2O7-(NH4)2Cr2O7-K2Cr2O7-H2O four-component water-salt system at 25, 50, and 75°C was studied for the first time. Phase field boundaries for individual salts and potassium and ammonium dichromate solid solutions, monovariant lines, and invariant points were determined. Experimental data were used to optimize the looped isohydric process of potassium dichromate preparation involving additional salts.  相似文献   

13.
一些具有NASICON型网格结构的固体电解质具有高的电导率和好的稳定性,NASICON的意思是Na Super Ionic Conductor[1]。当NaZr2(PO4)3中P5 被Si4 部分取代时便可以得到具有NASICON结构的Na1 xZr2SixP3-xO12体系,其具有高的钠离子电导率。然而有相同结构的Li1 xZr2SixP3-xO12体系的离子电导率却很低,这是因为Li 半径太小,而NASICON三维网格结构的离子通道太大,两者不匹配而使电导率下降[2]。但当LiZr2(PO4)3中Zr4 被离子半径小些的Ti4 取代,所得LiTi2(PO4)3的通道就与Li 半径相匹配,适合于锂离子的迁移,从而使其电导率…  相似文献   

14.
马修臻  胡斌 《化学通报》2018,81(10):939-943,938
本文用高精度数字式振荡管密度计测定了288K至318K温度范围内Li2SO4 + Na2SO4 + H2O和 Li2SO4 + K2SO4 + H2O三元体系的密度。混合溶液的离子强度范围从0.1到4.5 mol.kg–1,混合溶液中Na2SO4和K2SO4的离子强度分数为0.2,0.4,0.6和0.8。用密度实验值拟合得到了不同温度下Pitzer离子相互作用模型混合参数θV和 ψV,模型的计算值与实验值的偏差在±0.002 g.cm3以内。用Pitzer模型计算了不同离子强度下三元体系的混合体积。  相似文献   

15.
MMe5(dmpe) (M = Nb or Ta, dmpe = Me2PCH2CH2PMe2) reacts with H2 (500 atm) and dmpe in THF at 60°C to give MH5(dmpe)2? NbH5(dmpe)2 readily reacts with two mol of CO or ethylene (L) to give NbHL2(dmpe)2. The exchange of the hydride ligand with the ethylene protons in NbH(C2H4)2(dmpe)2 is not rapid on the 1H NMR time scale (60 MHz) at 95°C.  相似文献   

16.
The lithium-ion-conducting inorganic solid electrolytes in the oxide systems Li2O-SiO2-P2O5 and Li2O-TiO2-SiO2-P2O5 were prepared by the solid-state reaction, and the electrolyte pellet made by cold-pressing method had diameter of 13 mm and was about 1 mm thick. Phase identification and surface morphology of the products were carried out by X-ray diffraction and scanning electron microscopy. Ionic conductivity of the pellets was investigated through ac impedance. The results show that the adding of other cations can improve the ionic conductivity of the solid electrolyte, and the sintering temperature and duration can influence the ionic conductivity. The maximum ionic conductivity in the samples is 9.9 × 10−4 S/cm in the Li2O-TiO2-SiO2-P2O5 system. Original Russian Text ? W. Li, M. Wang, Z.H. Li, X.F. Shang, H. Wang, Y.W. Wang, Y.B. Xu, 2007, published in Elektrokhimiya, 2007, Vol. 43, No. 11, pp. 1341–1345.  相似文献   

17.
This paper examines the structural changes with temperature and composition in the Sc2Si2O7-Y2Si2O7 system; members of this system are expected to form in the intergranular region of Si3N4 and SiC structural ceramics when sintered with the aid of Y2O3 and Sc2O3 mixtures. A set of different compositions have been synthesized using the sol-gel method to obtain a xerogel, which has been calcined at temperatures between 1300 and 1750 °C during different times. The temperature-composition diagram of the system, obtained from powder XRD data, is dominated by the β-RE2Si2O7 polymorph, with γ-RE2Si2O7 and δ-RE2Si2O7 showing very reduced stability fields. Isotherms at 1300 and 1600 °C have been analysed in detail to evaluate the solid solubility of the components. Although, the XRD data show a complete solid solubility of β-Sc2Si2O7 in β-Y2Si2O7 at 1300 °C, the 29Si MAS-NMR spectra indicate a local structural change at x ca. 1.15 (Sc2−xYxSi2O7) related to the configuration of the Si tetrahedron, which does not affect the long-range order of the β-RE2Si2O7 structure. Finally, it is interesting to note that, although Sc2Si2O7 shows a unique stable polymorph (β), Sc3+ is able to replace Y3+ in γ-Y2Si2O7 in the compositional range 1.86?x?2 (where x is Sc2−xYxSi2O7) as well as in δ-Y2Si2O7 for compositions much closer to the pure Y2Si2O7.  相似文献   

18.
The phase diagrams of the NaBO2-NaCl-Na2CO3, NaBO2-Na2CO3-Na2MoO4, NaBO2- Na2CO3-Na2WO4, and NaBO2-NaCl-Na2WO4 ternary systems were studied by a calculation-experimental method and differential thermal analysis. The coordinates of ternary eutectics were determined: E 1: 612°C, 16 mol % NaBO2, 42 mol % NaCl, and 42 mol % Na2CO3; E 2: 568°C, 12 mol % NaBO2, 28 mol % Na2CO3, and 60 mol % Na2MoO4; E 3: 575°C, 12 mol % NaBO2, 32 mol % Na2CO3, and 56 mol % Na2WO4; E 4: 628°C, 8 mol % NaBO2, 20 mol % NaCl, and 72 mol % Na2WO4; and E 5: 655°C, 9 mol % NaBO2, 53 mol % NaCl, and 38 mol % Na2WO4.  相似文献   

19.
The novel, 1D semiconductor (H2NC4H8NCH2CH2NH2)(HNCH2CH2NH2)3Zn2Ge2Se8 has been synthesized under solvothermal conditions using N-(2-aminoethyl)piperazine as solvent and templating agent at 200 °C. The material was characterized by single crystal and powder X-ray diffraction, IR and Raman spectroscopy and thermogravimetric analysis. The compound consists of 1D anionic [Zn2Ge2Se8]4− chains made of alternating edge-shared [ZnSe4] and [GeSe4] tetrahedra that charged balanced by one N-(2-aminoethyl)piperazinium and three piperazinium cations. The optical properties were investigated with solid state UV–Vis/near IR spectroscopy and the results show that the solid is a medium gap semiconductor with an absorption edge at 1.8 eV.  相似文献   

20.
Reactions of [Cp2Ti(btmsa)] (btmsa = bis(trimethylsilyl)acetylene) with R4Sb2 (R = Me, Me3Si) give [Cp2TiSbMe2]2 (1) or [Cp2TiSb(SiMe3)2]2 (2) respectively. [Cp2TiCl]2·2Mes4Sb2 (3) is serendipitously formed from [Cp2Ti(btmsa)] and Mes2SbH containing NH4Cl traces.  相似文献   

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