K_2NiF_4型Dy_(0.5)Sr_(1.5)MO_4(M=Mn,Fe,Co,Ni)稀土复合氧化物的合成和催化性能考察

用重稀土镝的氧化物与锶、锰、铁、钴、镍的硝酸盐为原料,制备了A_2BO_4型Dy_(0.5)Sr_(1.5)MO_4(M=Mn,Fe,Co,Ni)稀土复合氧化物,用XRD技术考察了物相,合成了K_2NiF_4型四方结构的Dy_(0.5)Sr_(1.5)MO_4,并研究了其催化性能。对结构容纳因子的适用性作了讨论。     

MAPO-CHA(M=Mn,Fe,Co,Zn)系列过渡金属取代磷酸铝化合物的合成、结构与性质

在水热体系中, 以2-胺乙基哌嗪分解得到的二乙胺为模板剂, 合成了一系列具有CHA结构的过渡金属取代磷酸铝化合物MAl(PO₄)₂[(C₂H₅)₂NH₂](命名为MAPO-CHA, M=Mn, Fe, Co, Zn), 其M/Al原子比为1. 单晶结构分析表明, MnAPO-CHA晶体属于三方晶系, R3空间群, 晶胞参数a=1.4003(2)nm, c=1.5236(3) nm, V=2.5873(7) nm³, Z=9, 其无机骨架由Al(Mn)O₄四面体和PO₄四面体交替连接形成具有分子筛CHA的拓扑结构, 单质子化的二乙胺离子位于八元环孔道中. X射线粉末衍射分析表明, 这些化合物是同构的, 并均具有荧光性质, 其中, 化合物MAPO-CHA(M=Mn, Fe, Co)还具有弱的反铁磁交换作用.     

Bi_(4-x)Eu_xTi_(3-y)M_yO_(12)(M=Fe,Co,Ni)纳米颗粒的制备及光学和磁学性能

三层结构的Aurivillius相的Bi_(4-x)Eu_xTi_(3-y)M_yO_(12)(x=0~0.6;M=Fe/Co/Ni,y=0.01,0.02,0.04,0.06,0.08,0.10)纳米颗粒,是通过共沉淀法和后续的高温煅烧处理所制备的。利用XRD,SEM,PL,Raman,PPMS等方法对样品进行表征,研究了不同掺杂浓度下的产物的物相、形貌和性能等。实验结果表明,通过掺杂,发现纳米颗粒的粒径变小,形貌更均一,分散性也更好。通过对掺杂离子浓度的优化,发现Eu~(3+)离子的掺杂浓度为x=0.4时,发光强度是最强的。此外,对Ti位进行了磁性离子(Fe~(3+),Co~(3+)和Ni~(2+))的掺杂,实验结果发现随着掺杂的磁性离子浓度的减少,发光强度是逐渐增强,而且产物具有很好的铁磁性。     

草酰胺桥联大环二羰四胺Cu(Ⅱ)-M(Ⅱ)(M=Mn,Ni,Cu,Zn)异双核配合物的合成与表征

合成了四种新型具有草酰胺桥联大环二羰四胺结构Cu(Ⅱ ) -M(Ⅱ ) (M =Mn ,Ni,Cu ,Zn)的双核配合物 ,并用元素分析 ,红外光谱 ,紫外光谱 ,摩尔电导 ,热重分析 ,室温磁矩等手段对其进行了结构表征 .经研究推定 ,此配合物具有草酰胺桥联结构 ,Cu(Ⅱ )处于平面正方场M(Ⅱ )处于八面体场中 .室温磁矩测定表明通过草酰胺桥联配体金属离子间有一定的反铁磁性自旋偶合相互作用     

二维层状磷酸亚磷酸钒(Ⅳ)化合物[V_2O_2(OH)(HPO_3)(HPO_3)_(0·7)(PO_3OH)_(0·3)]·(C_6N_2H_(16))_(0·5)的水热合成与结构表征

迄今,在中温水热条件下已合成了大量具有空旷骨架结构的过渡金属磷酸盐微孔材料[1],这类材料在非线性光学材料、磁性材料、超导材料及催化等诸多方面具有潜在的应用前景[2~5].自从第一个以有机胺为模板的磷钒氧化合物[(CH3)2NH2]K4[V10O10(H2O)2(OH)4(PO4)7]·4H2O[6]的合成以来,又有几十种结构的磷钒氧化合物被报道.但以亚磷酸为结构基元构筑的磷钒氧化合物的报道较少.1995年,Zubieta等[7]报道了以哌嗪为模板剂的两个亚磷酸钒化合物[HN(Me)(CH2CH2)2N·(Me)H][(VO)4(OH)2(HPO3)4]和[H2N(CH2CH2)2NH2][(VO)3(HPO3)4(H2O…     

M(bpy)_3~(2 )(M=Fe,Ru,Os)电子结构与相关性质

报导了对配合物M(bpy)2 M=Fe,Ru,Os)的量子化学密度泛函(DFT)法研究的结果.在B3LYP/LanL2DZ方法与基组的水平上进行计算 ,探讨M(bpy)32 的电子结构特征及相关性质 ,特别是中心原子对配合物的配位键长、光谱性质、电荷布居及化学稳定性等的影响规律 ,为该类配合物的合成 ,为分析光、电、催化作用机理提供理论参考.     

氧心羧桥异三核过渡金属簇合物[Fe_2MO(CH_3COO)_6Py_3]·Py(1,M=Mn;2,M=Co;3,M=Ni)和[Fe_2MO(CCl_3COO)_6(THF)_3](4,M=Mn;5,M=Co;6,M=Ni)电子光谱的研究

氧心羧桥三核物通式为[M_3O(RCOO)_6L_3]~(n+)(n=1,0)虽然它在三十年代就已合成出来,但是引起人们广泛兴趣的还是近年来发现的它所具有的特殊稳定性和不寻常的物理化学性质。我们测定了不同M~(2+)离子,两种羧桥的铁系列异三核标题簇合物的晶体结构和有关物理性质。该类型化合物的结构可以看成由共享μ_3-O顶点的三个金属离子的配位八面体组     

M_6~(0,±)(M=Os,Ir,Pt)团簇结构与性质的密度泛函理论研究

采用密度泛函理论(DFT)中的杂化密度泛函(B3LYP)方法,在LANL2DZ基组水平上对M06,±(M=Os,Ir,Pt)团簇的各种可能构型进行了几何结构优化,得出各团簇的最稳定构型,并对其能量、振动频率、热力学性质、核独立化学位移(NICS)和极化率进行了理论研究.结果表明,M06,±(M=Os,Ir)团簇的基态都是三棱柱结构,Pt-6团簇的基态是平面三角形结构;M06,±(M=Os,Ir,Pt)团簇生成焓都为负值,热力学上是稳定的;NICS值都为负值,表明M06,±(M=Os,Ir,Pt)团簇都具有芳香性,其中Os-6团簇的芳香性最强;从光谱分析来看,Os6的IR和Raman谱的较强吸收峰的个数最多,Ir6的IR和Raman谱的最强吸收峰都只有一个,IR最强吸收峰在137.0和143.5 cm-1之间,Raman谱最强的吸收峰位于169.5 cm-1处;Pt6的IR和Raman谱的最强吸收峰分别位于50.2和194.7 cm-1处.     

六聚同多酸阴离子M_6O_(19)~(n-)(M=Mo,W,n=2;M=Nb,Ta,n=8)电子结构和化学性质的密度泛函理论研究

采用B3LYP方法在LanL2DZ水平上计算了六聚同多阴离子 (M6On-19,M =Mo和W ,n =2 ;M =Nb和Ta ,n =8)的电子结构 ,分析了它们的前线轨道、分子静电势 (MEP) .计算结果表明 ,Nb6O8-19和Ta6O8-19是电子给体 ,而Mo6O2 -19和W6O2 -19则是电子受体 ,这与它们在溶液中具有不同的化学性质是一致的     

OXO-CENTERED HETEROTRINUCLEAR TRANSITION METAL CARBOXYLATE COMPLEXES 3, SYNTHESES AND X-RAY STRUCTURAL CHARACTERISTICS OF COMPOUNDS Fe_2MO(O_2CCCl_3)_6(THF)_3 (1,M = Mn;2,M=Co;3, M = Ni;THF=TETRAHYDROFURAN)

<正> The title compounds have been synthesized and characterized by x-ray analysis. They are isomorphous, belonging to trigonal space group R3m,with crystallo-graphic parameters; (1)α =b =c= 13. 713(5) A ;α= β=γ=83. 66(3)°;V = 2535A3;Z = 2;DC=1. 80gcm-3;F(000) = 1358;M= 1373. 23;(2)α= b = c=13. 687(2) A;α = β = γ = 84. 27(1)°/;V = 2528. 0A3;Z = 2; Dc = 1. 81gcm-3; F (000)= 1362; M = 1377. 23;(3)α = b=c=13. 671(6) A ;α = β = γ=84. 12(3)°;V=2518A3;Z=2;DC = 1. 82 gcm-3;F(000)= 1364;Mr= 1376. 99.The structure of comp ound 2 has been determined with the final R= 0. 061 for 845 reflections with I≥3σ(Ⅰ).The three metal atoms are crystallographically equivalent because of the arbitrariness of orientation of the molecules,and in the sense of crystallography the molecule Fc2CoO(O2CCCl3)6(THF)3 is of C3vsymmetry with centered oxygen atom on the 3-fold axis. The atoms M,C(1~4),C1(1) and O(1) lie on the mirror. Three CC13 groups on one side the Fe2CoO plane and three terminal THF ligands are dynamically     

Syntheses,structures, and magnetism of {V15M6O42(OH)6(Cl)} (M = Si,Ge)

Two [V₁₅M₆(OH)₆O₄₂(Cl)]^7? (M = Si for 1, Ge for 2) cluster anions with protonated amines as counterions have been synthesized under hydrothermal conditions and characterized by FT-IR, energy dispersive spectroscopy, XPS, powder X-ray diffraction, thermogravimetric analysis (TGA), elemental analysis, and single-crystal X-ray analyses. Both compounds consist of {V₁₅M₆O₄₂(OH)₆(Cl)} (M = Si for 1, Ge for 2), which are derived from {V₁₈O₄₂} by substitution of three {VO₅} square pyramids with three {Si₂O₅(OH)₂/Ge₂O₅(OH)₂} units. It represents the first example of cage-like polyoxovanadates (POVs) containing three (Si/Ge)₂O₅(OH)₂ units. There are extensive hydrogen bonding interactions between POVs and organoamines in 1 and 2. Compound 1 presents a close-packed layer aggregate, while 2 exhibits the packing of six-membered rings with a 1-D channel. Magnetism measurements demonstrate the presence of strong antiferromagnetic interaction between V^IV centers in 1.     

Crystal Structures,Dimorphism and Lithium Mobility of Li7MO6 (M = Bi,Ru, Os)

Li₇MO₆ (M = Bi, Ru, Os) have been synthesized by solid state reaction of Li₂O with Bi₂O₃, or MO₂ (M = Ru, Os) and characterized using powder X‐ray diffraction, differential scanning calorimetry, magnetic susceptibility (for M = Ru, Os), ionic conductivity and ⁶Li solid state NMR (for M = Bi) measurements. All three compounds exhibit a temperature induced triclinic – rhombohedral phase transition. Structures of the new low temperature triclinic phases have been refined by the Rietveld method from powder X‐ray data using atomic parameters of Li₇TaO₆ as a starting model ( Li₇BiO₆ : triclinic, , a = 5.5071(1), b = 6.0425(1), c = 5.5231(1) Å, α = 116.912(1), β = 120.867(1), γ = 62.234(1)°, V = 133.96(1) ų, Z = 1, T = 230 K; Li₇RuO₆ : triclinic, , a = 5.3654(1), b = 5.8584(1), c = 5.3496(1) Å, α = 117.182(1), β = 119.117(1), γ = 62.632(1)°, V = 124.43(1) ų, Z = 1, T = 295 K; Li₇OsO₆ : triclinic, , a = 5.3786(1), b = 5.8725(1), c = 5.3591(1) Å, α = 117.193(1), β = 119.277(1), γ = 62.700(1)°, V = 125.15(1) ų, Z = 1, T = 295 K). Upon cooling, Li₇RuO₆ and Li₇OsO₆ undergo a magnetic transition at 12 and 13 K, respectively, from the paramagnetic to the antiferromagnetic state. The higher ionic conductivity of Li₇BiO₆ at T < 300 °C, as compared to Li₇RuO₆ and Li₇OsO₆, can be ascribed to the undergoing of the triclinic – rhombohedral transition at a much lower temperature. At T > 300 °C, the ionic conductivity of all three compounds increases sharply due to the melting of the lithium sublattice; for Li₇RuO₆ and Li₇OsO₆ the latter effect is superimposed by the phase transitions to the rhombohedral modifications.     

Sm（0.5）Sr（0.5）Co（0.4）M（0.6）O3（M=Co,Mn,Fe）作为IT-SOFCs阴极的结构与性能

通过X射线衍射(XRD)、热重、热膨胀、电导率以及交流阻抗等测试方法,研究了Sm0.5Sr0.5Co0.4M0.6O3(M=Co,Mn,Fe;分别简写为SSCC,SSCM,SSCF)作为中低温固体氧化物燃料电池(IT-SOFCs)阴极的结构与性能.研究表明,同相法合成的Sm0.5Sr0.5Co0.4M0.6O3均为正交钙钛矿型结构,材料的结构参数和性能都与M元素半径及M-O的键能有关.晶胞参数随着Co、Mn、Fe的顺序增大.材料的氧空位浓度、热膨胀系数、电导率、电极催化活性随着Co、Fe、Mn的顺序降低.同时由于SSCM较低的氧空位浓度,使得电极反应受到氧在电极内的扩散过程控制,具有较差的电极催化性能,而SSCC和SSCF较高的氧空位浓度,电极反应同时受到电极表面氧还原反应和氧离子在电极中的扩散过程混合控制.由于SSCF具有较高的氧扩散系数,使得700 ℃以上SSCF电极表面氧还原电阻(ASR)也低于SSCC的,因而出现了SSCF的总电极催化活性高于SSCC的现象.     

Syntheses and Crystal Structures of Four New Complexes [Mn(4,4''-bip)2(OH2)4](DBA)·4H2O and [M(OH2)(HDPA)2]·3H2O (M = Mn, Co, Ni)

Four new transition metal complexes, [Mn(4,4'-bip)2(OH2)4](DBA)·4H2O 1(4,4'-bip = 4,4'-bipyridine, H2DBA = benzene-1,3-dicarboxylic acid) and [M(OH2)(HDPA)2]·3H2O (M = Mn 2, M = Co 3, M = Ni 4,H2DPA = 2,6-pyridine-dicarboxylic acid), have been prepared from the reaction of transition metals and carboxylic acids, and characterized by X-ray and elemental analyses. For compound 1, the packing diagram shows that a three-dimensional network is formed via hydrogen bonds and strong π-π interactions. For compounds 2, 3 and 4,a double-helical chain is formed through hydrogen bonds. Moreover, a three-dimensional network is constructed from chains via complicated hydrogen bonds between crystal water molecules and oxygen atoms of HDPA-.     

钴、镍-氨基三乙酸配位聚合物Na[M(nta)]·H2O(M=Co,Ni)的水热合成、结构与磁性

由有机配体同金属离子作用构建的配位聚合物具有与无机微孔晶体类似的空旷骨架结构,并在非线性光学材料、磁性材料、超导材料及催化等诸多方面具有潜在的应用前景[1～4].在配位聚合物的合成中,配体的种类不仅直接影响到聚合物的合成,而且还涉及到聚合物的结构维数[5～7].目前,用来构建这些配合物的有机配体大多数都带有相同的可配位基团,较少应用具有两种以上的配位基团的有机配体.本文采用同时含有氮和氧两种配位原子的多齿配体氨基三乙酸[8～12],在水热条件下分别以Co2+和Ni2+作为组装基元,通过自组装合成了具有三维骨架结构的Na[M(nta)]·H2O [M=Co(1),Ni(2)]配位聚合物,并进行了结构与磁性研究.     

Syntheses and Crystal Structures of(H_3O)(C_3H_5N_2)[Mn(OH)_6Mo_6O_(18)]·3.5H_2O and (H_3O)_3[Co(OH)_6Mo_6O_(18)]·7H_2O

1 INTRODUCTION Polyoxometalates, a rich and remarkable classof inorganic cluster system[1], exhibit diverse appli-cation possibilities due to their topological and elec-tronic properties, ranging from their well-known roleas reagents in analytical, b…     

Syntheses of MSn(OH)6 by coprecipitation and of MSnO3 by thermal decomposition (M = Mg,Co, Zn,Mn, Cd,Ca, Sr,Ba)

MSn(OH)₆ (M = Mg, Co, Zn, Mn, Cd, Ca, Sr, and Ba) and their solid solutions were synthesized by coprecipitation from aqueous solutions of Na₂Sn(OH)₆ complex and MCl₂. MSnO₃ and their solid solutions were prepared by thermal decomposition of these MSn(OH)₆ precipitates. Coprecipitation procedures were established, and structures of MSn(OH)₆ and MSnO₃ were discussed in relation to mean radius of M²⁺ ions. The morphology of particles of these hydroxides and oxides were also observed. In order to obtain a single phase precipitate MSn(OH)₆, the concentration of both solutions of Na₂Sn(OH)₆ and MCl₂ had to be as low as 0.1 mol/l. The pH-value was kept above 11, and so acidic solution of MCl₂ was added slowly to basic solution of Na₂Sn(OH)₆. The structure of MSn(OH)₆ depended strongly of mean radius of M²⁺ ions, being cubic with NaCl-type arrangement of M²⁺ and Sn⁴⁺ cations below 1.26 Å and hexagonal above 1.26 Å. Crystalline MSnO₃ was obtained by the decomposition of MSn(OH)₆ precipitates above 500–600°C. The structure of MSnO₃ was also related with mean radius of M²⁺ ions closely, ilmenite-type below 1.09 Å and pervoskite-type above 1.14 Å. In perovskite-type structure, a gradual decrease in lattice distortion and rapid increase in crystal volume were observed with the increase in radius of M²⁺ ions. An interesting morphology change was observed from CaSn(OH)₆ precipitates to CaSnO₃, the particles with either cubic or flower-like appearance in hydroxide becoming porous in oxide without appreciable change in particle appearance.     

Sr3GdRhO6 - The First RhIII Compound with the K4CdCl6 Structure-type: Synthesis,Crystal Structure,and Magnetic Properties

The compound Sr₃GdRhO₆ has been synthesized and structurally characterized by Rietveld refinement of powder X-ray diffraction data. (space group R3 c; Z = 6; a = 9.7840(5) Å; c = 11.4196(7) Å) This compound is isostructural with K₄CdCl₆. The structure consists of infinite one-dimensional chains of alternating face-shared RhO₆ octahedra and GdO₆ trigonal prisms. The strontium cations are located in a distorted square antiprismatic environment. Magnetic susceptibility data show that Sr₃GdRhO₆ obeys the Curie law with η_eff = 7.80 B.M., consistent with an oxidation state of +3 for both rhodium and gadolinium.