介孔结构Na_(10)[α-SiW_9O_(34)]/TiO_2/Ag的合成及光催化性能研究

本文采用溶胶-凝胶法制备Na10[α-Si W9O34]/Ti O2/Ag复合材料。用IR、XRD、UV‐Vis漫反射光谱、SEM、ED-Mapping等方法进行了表征和分析。用N2吸附-脱附等温线考察了催化剂的比表面、孔径,表明产物为介孔材料。以标题化合物作为光催化剂催化降解亚甲基蓝,探讨催化剂用量、亚甲基蓝的初始浓度、溶液的p H值等条件对亚甲基蓝脱色率的影响,结果表明:催化剂加入量为1 mg·L-1、亚甲基蓝的初始浓度为5 mg·L-1,p H=2.0,脱色率达到94.7%。     

纳米复合Sb2O3/TiO2的光催化性能研究

采用溶胶－凝胶法制备复合纳米Sb2O3/TiO2Sb2O3掺入浓度越大,催化剂中锐钛矿相含量越高,晶粒直径与颗粒直径越小,比表面积越大,在380－460nm,范围内,Sb2O3/TiO2的反射率则减弱,表明光吸收增强,Sb^5＋,占48．42％、Sb^ 占17．58％,以亚甲基蓝溶液光催化降解为模型反应,掺入2％,5％Sb2O3,亚在蓝溶液的光催化脱色降解一致动力学常数与总有机炭（TOC）去除率增大,发射光谱证明,Sb2O3的最佳比例为2％,当其比例大于2％时,其电子空穴对的复合率升高,光催化活性下降。     

Cu_3B_2O_6/CuB_2O_4单晶的制备及其可见光催化降解亚甲基蓝

以醋酸铜/硝酸铜和硼酸为原料,柠檬酸作发泡剂,采用溶胶-凝胶法制得了高纯度的单晶结构硼酸铜(Cu3B2O6/CuB2O4).利用X射线衍射(XRD)、扫描电镜(SEM)、高分辨率透射电镜(HRTEM)、热重-差热分析(TGDTA)等对样品进行了表征,并考察了Cu3B2O6/CuB2O4在可见光(400 nmλ1100 nm)下对亚甲基蓝(MB)溶液的催化降解性能.结果表明,两种结构的硼酸铜都具有良好的光催化性能.当亚甲基蓝的初始浓度为50 mg·L-1,催化剂用量为1 g·L-1,光照6 h后,CuB2O4对亚甲基蓝的光催化降解率为63.36%,Cu3B2O6对亚甲基蓝的光催化降解率为99.52%.紫外-可见漫反射光谱(UV-Vis DRS)结果表明,Cu3B2O6的中间能态宽度为1.78 eV,小于CuB2O4的中间能态宽度(1.95 eV),且Cu3B2O6的禁带宽度较窄(Eg=2.34 eV),不仅可以发生价带顶与中间能态的电子跃迁,同时可以发生禁带间的电子跃迁,所以Cu3B2O6比CuB2O4具有更高的可见光催化性能.     

介孔结构K8SiMo11O39·2H2O/TiO2的合成及光催化性能研究

采用浸渍法制备K8SiMo11O39·2H2O/TiO2复合材料。用IR、XRD、TG-DTA等方法进行了表征。用N2吸附-脱附等温线考察了催化剂的比表面、孔径,表明产物为介孔材料。以标题化合物作为光催化剂催化降解甲基橙,探讨催化剂用量、甲基橙的初始浓度、过氧化氢的用量等条件对甲基橙脱色率的影响,结果表明:催化剂加入量为80 mg·L-1、甲基橙的初始浓度为10 mg·L-1,H2O2的用量为10 mL·L-1时,脱色率达到92%。     

H_3PW_(12)O_(40)/TiO_2(锐钛)的超声制备及降解染料的研究

采用超声法,在80℃下,制备了H3PW12O40/TiO2(锐钛)复合催化剂,并采用XRD、FT-IR等方法对样品进行了表征。通过染料刚果红和亚甲基蓝为模拟污染物的光催化降解实验考察了复合催化剂的光催化活性。结果表明,在太阳光下,复合光催化剂的催化活性高于单体TiO2,H3PW12O40/TiO2(锐钛)在90min内,对溶液中刚果红的去除率达99.17%,对亚甲基蓝溶液的TOC去除率达73.17%。复合催化剂在反复实验5次后,仍能保持有效的催化性能。     

磁性光催化剂BiVO_4/Fe_3O_4降解亚甲基蓝的研究

本文用超声法将磁基体Fe3O4与BiVO4复合,制备了易于固液分离的磁性可见光催化剂BiVO4/Fe3O4,采用X射线衍射(XRD)、透射电子显微镜(TEM)等手段对样品的结构和形貌进行表征。以亚甲基蓝为降解对象,考察了BiVO4/Fe3O4的可见光催化活性,并研究了光催化体系中光催化剂用量、亚甲基蓝初始浓度、溶液的pH值、电子受体的存在对光催化过程的影响。结果表明,催化剂的最佳用量为2.0g/L,亚甲基蓝最佳初始浓度为10mg/L,溶液的最佳pH值为11,加入电子受体K2S2O8时,亚甲基蓝几乎完全降解。催化剂回收后连续使用3次,降解率仍然大于80%。     

纳米La0.8A’0.2Mn1-xCuxO3（A’=Ce and/or Sr）的制备、表征及其高效催化NO+CO的性能研究

采用柠檬酸-溶胶凝胶法制得钙钛矿型复合氧化物La0.8Ce0.2Mn1-xCuxO3(x=0.2,0.3,0.4),La0.8Sr0.2Mn0.6Cu0.4O3,La0.8Ce0.1Sr0.1Mn0.6 Cu0.4 O3,并采用X射线衍射(XRD)、扫描电镜(SEM)、比表面积(BET)、X射线光电子能谱(XPS)对其进行表征,测试了复合氧化物对CO+NO的催化活性。结果表明:La0.8Ce0.1Sr0.1Mn0.6Cu0.4O3催化活性最好,150℃时CO转化率91.8%,300℃时NO转化率100%;对于La0.8Ce0.2Mn1-xCuxO3(x=0.2,0.3,0.4),比表面积和颗粒的大小及分散度是影响催化活性的主要因素;对于La0.8Ce0.2Mn0.6Cu0.4O3,La0.8 Sr0.2 Mn0.6 Cu0.4 O3,La0.8 Ce0.1 Sr0.1 Mn0.6 Cu0.4 O3,催化剂的组成是影响催化活性的关键因素。     

Cu-石墨烯类Fenton催化剂的制备及催化活性

通过一步水热法制备了Cu-石墨烯(Cu-RGO)催化剂,实现了Cu纳米颗粒的可控生长和氧化石墨烯(GO)还原的同步进行,并将所制备的Cu-RGO用于亚甲基蓝(MB)的催化降解研究。在H2O2存在条件下,当GO与Cu的质量比为3∶17时,经过4 h催化反应,Cu-RGO催化剂对亚甲基蓝的降解率可达到99.5%,经过6次循环使用对亚甲基蓝的降解率仍保持在98.1%以上,CuRGO催化剂展现了较高的催化活性及良好的稳定性。     

太阳光活性的ZnTiO3 /TiO2纳米复合催化材料的制备及其表征

通过溶胶-凝胶(Sol-Gel)法制备了ZnTiO3/TiO2纳米复合光催化剂,利用透射电子显微镜(TEM)、X射线衍射(XRD)、紫外-可见光谱(UV-Vis)、红外光谱(FTIR)和ζ电位等技术进行了表征。以亚甲基蓝(MB)的降解为模型反应,考察了煅烧条件对复合材料光催化性能的影响。结果表明:600℃下焙烧3 h时所得样品具有最佳的光催化效果。如太阳光下7 h可使MB溶液的脱色降解率达92.9%,而TiO2的催化脱色率仅为68.9%;该催化剂还具有良好的稳定性能,重复使用5次后仍能保持MB溶液的脱色降解率在80%以上,且该催化剂易于离心分离去除。样品的结构缺陷-氧空位和TiO2-ZnTiO3相结与其催化性能有密切关系。     

g-C3N4/双钙钛矿复合材料的制备及氧催化性能

通过溶胶-凝胶法制备出不同Ni掺杂比例的双钙钛矿Sr_2Ni_xCo_(2-x)O_6(x=0.2,0.4,0.6,0.8),通过热分解法制备出具有层状结构的纳米颗粒g-C_3N_4,并制备其复合物催化剂。将双钙钛矿和g-C_3N_4分别制备成双功能电极片,用于测试其对氧还原(ORR)和氧析出(OER)的催化活性,然后选取具有最佳氧催化活性的Ni掺杂比例x=0.4的双钙钛矿与一定重量比例的g-C_3N_4进行复合,测试复合催化剂的氧催化活性。结果表明,复合后的催化剂催化效果明显优于单一催化剂,当g-C_3N_4添加量占双钙钛矿的30%(w/w)时复合催化剂催化氧还原反应的最大电流密度为395.7 mA·cm~(-2)(-0.6 V vs Hg/HgO),氧析出反应的最大电流密度为372.0mA·cm~(-2)(1 V vs Hg/HgO),这表明g-C_3N_4与Sr_2Ni_(0.4)Co_(1.6)O_6复合后协同催化能够提高双钙钛矿的氧催化活性。     

Sol-gel synthesis of K3InF6 and structural characterization of K2InC10O10H6F9, K3InC12O14H4F18 and K3InC12O12F18

K₃InF₆ is synthesized by a sol-gel route starting from indium and potassium acetates dissolved in isopropanol in the stoichiometry 1:3, with trifluoroacetic acid as fluorinating agent. The crystal structures of the organic precursors were solved by X-ray diffraction methods on single crystals. Three organic compounds were isolated and identified: K₂InC₁₀O₁₀H₆F₉, K₃InC₁₂O₁₄H₄F₁₈ and K₃InC₁₂O₁₂F₁₈. The first one, deficient in potassium in comparison with the initial stoichiometry, is unstable. In its crystal structure, acetate as well as trifluoroacetate anions are coordinated to the indium atom. The two other precursors are obtained, respectively, by quick and slow evaporation of the solution. They correspond to the final organic compounds, which give K₃InF₆ by decomposition at high temperature. The crystal structure of K₃InC₁₂O₁₄H₄F₁₈ is characterized by complex anions [In(CF₃COO)₄(OH_x)₂]^(5−2x)− and isolated [CF₃COOH_2−x]^(x−1)− molecules with x=2 or 1, surrounded by K⁺ cations. The crystal structure of K₃InC₁₂O₁₂F₁₈ is only constituted by complex anions [In(CF₃COO)₆]³⁻ and K⁺ cations. For all these compounds, potassium cations ensure only the electroneutrality of the structure. IR spectra of K₂InC₁₀O₁₀H₆F₉ and K₃InC₁₂O₁₂F₁₈ were also performed at room temperature on pulverized crystals.     

Phase relations in the K2W2O7-K2WO4-KPO3-Bi2O3 system and structure of K6.5Bi2.5W4P6O34

The phase relations in the cross-section of the K₂W₂O₇-K₂WO₄-KPO₃ containing 15 mol% Bi₂O₃ were undertaken using flux method. Crystallization fields of K_6.5Bi_2.5W₄P₆O₃₄, K₂Bi(PO₄)(WO₄), Bi₂WO₆, KBi(WO₄)₂ and their cocrystallization areas were identified. Novel phase K_6.5Bi_2.5W₄P₆O₃₄ was characterized by single-crystal X-ray diffraction: sp. gr. P−1, a=9.4170(5), b=9.7166(4), c=17.6050(7) Å, α=90.052(5)°, β=103.880(5)° and γ=90.125(5)°. It has a layered structure, which contains {K₇Bi₅W₈P₁₂O₆₈}_∞ layers stacked parallel to ab plane and sheets composed by potassium atoms separating these layers. Sandwich-like {K₇Bi₅W₈P₁₂O₆₈}_∞ layers are assembled from [W₂P₂O₁₃]_∞ and [BiPO₄]_∞ building units, and are penetrated by tunnels with K/Bi atoms inside. FTIR-spectra of K₂Bi(PO₄)(WO₄) and K_6.5Bi_2.5W₄P₆O₃₄ were discussed on the basis of factor group theory.     

Li2SO4-Na2SO4-H2O和Li2SO4- K2SO4-H2O溶液的体积性质

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θ_V和 ψ_V,模型的计算值与实验值的偏差在±0.002 g.cm_–3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。     

Li2O-TiO2-SiO2-P2O5和Li2O-TiO2-Al2O3-P2O5体系锂离子固体电解质的制备及性能研究

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…     

KCl-KBO2-K2CO3, K2MoO4-KBO2-K2CO3, and K2WO4-KBO2-K2CO3 ternary systems

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.     

Extension of the La7Mo7O30 structural type with La7Nb3W4O30 and La7Ta3W4O30 compounds

Two compounds of formula La₇A₃W₄O₃₀ (with A=Nb and Ta) were prepared by solid-state reaction at 1450 and 1490 °C. They crystallize in the rhombohedric space group R-3 (No. 148), with the hexagonal parameters: , and , . The structure of the materials was analyzed from X-ray, neutron and electronic diffraction. These oxides are isostructural of the reduced molybdenum compound La₇Mo₇O₃₀, which are formed of perovskite rod along [111]. An order between (Nb, Ta) and W is observed.     

Preparation and structure of NaSr0.5Al2B2O7 and NaCa0.5Al2B2O7

Two compounds NaSr_0.5Al₂B₂O₇ and NaCa_0.5Al₂B₂O₇, have been found to crystallize into a new structure type by Rietveld refinement from X-ray powder diffraction data. Their structure belongs to hexagonal space group P6₃/m, with lattice parameters of , for NaSr_0.5Al₂B₂O₇ and , for NaCa_0.5Al₂B₂O₇, respectively. The structure is built up by [Al₂B₂O₇]²⁻ double layer and Na⁺/Ca²⁺ or Na⁺/Sr²⁺ ions alternatively stacking along the c-axis. The sites in the inter-double layer are fully occupied jointly by Na and Ca or Sr, but the intra-double layer sites are only half occupied solely by Na. A mechanism of the transition of the structure from CaAl₂B₂O₇ to present structure type by replacing only 1% Ca by Na (2%) as observed by Chang and Keszler (Mater. Res. Bull. 33 (1998) 299) is also proposed.     

SnSbBiS4-SnS and SnSbBiS4-Sn2Sb6S11 sections of the SnS-Sb2S3-Bi2S3 ternary system

SnSbBiS₄-SnS and SnSbBiS₄-Sn₂Sb₆S₁₁ sections were studied by physicochemical methods (DTA, X-ray powder diffraction, microstructure observation, and microhardness measurements). These sections were found to be eutectic quasi-binary sections of the SnS-Sb₂S₃-Bi₂S₃ ternary system. Solid solution regions based on the initial components were found on either side of the sections. Alloys in the solid solution region are p-type semiconductors.     

Structural chemistry of Sr3Cr2WO9, Ca3Cr2WO9, and Ba3Cr2WO9

We have studied the preparation and crystallographic structure of three perovskite-type compounds: Sr₃Cr₂WO₉, cubic, the lattice parameter of which is a = 7.812Å; Ca₃Cr₂WO₉, tetragonal, the lattice parameters of which are a = 5.408 Å and c = 7.635Å; and Ba₃Cr₂WO₉, hexagonal, the lattice parameters of which are a = 5.691 Å and c = 13.957Å. We have compared these three structures and shown the relationship between the dimensions of the alkaline-earth metal and the existence of the different structures.     

Solubility in the Na2Cr2O7-(NH4)2Cr2O7-K2Cr2O7-H2O system

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.