以有机溶剂热生长技术制备金属硫族化合物[Mn(en)_3]PdSe_2及其晶体结构分析

以有机溶剂热生长技术 (solvothermaltechnique) ,即在 180℃乙二胺 (en)溶液中 ,以MnCl3,PdCl2 ,K2 Se在密闭容器中反应 7d ,制备出新的硫族化合物 [Mn(en) 3]PdSe2 ,其阴离子基团为 [PdSe2 ]2 -,阳离子基团为过渡金属Mn与乙二胺 (en)的配合物 :[Mn(en) 3]2 +.以单晶X射线衍射技术解得该晶体结构属正交晶系 ,空间群为Pbcn ,[Mn(en) 3]·PdSe2 (Ⅰ )的晶胞数据 :a =1.1484( 2 ) ,b=1.5 0 5 7( 3 ) ,c =0 .93 62 2 ( 19)nm ,Z =4.     

以有机溶剂热生长技术制备金属硫族化合物 [Mn(en)~3]PdSe~2及其晶体结构分 析

以有机溶剂热生长技术(solvothermaltechnique),即在180℃乙二胺(en)溶液中,以MnCl~3,PdCl~2,K~2Se在密闭容器中反应7d,制备出新的硫族化合物[Mn(en)~3]PdSe~2,其阴离子基团为[PdSe~2]^2^-,阳离子基团为过渡金属Mn与乙二胺(en)的配合物：[Mn(en)~3]^2^+。以单晶X射线衍射技术解得该晶体结构属正交晶系,空间群为Pbcn,[Mn(en)~3]PdSe~2(Ⅰ)的晶胞数据：a=1.1484(2),b=1.5057(3),c=0.93622(19)nm,Z=4。     

水热/溶剂热制备金属氧族化合物纳米微粒

介绍了近几年来以水热法及以此基础上发展起来的溶剂热生长技术在一系列重要的金属氧化物、硫族化合物纳米微粒的制备与尺寸和形状控制及其在生长机理中的应用。     

有机杂化硫代碲酸盐化合物(H_2en)TeS_3和[Ni(en)_3]TeS_3的溶剂热合成与表征

用低温溶剂热法合成了2种分立结构的有机杂化硫代碲(Ⅳ)酸盐化合物(H2en)TeS3(1)和[Ni(en)3]TeS3(2)(en=乙二胺),通过X-射线单晶衍射,红外光谱,元素分析等手段对它们的结构进行了表征。晶体结构解析结果表明:2个化合物均属单斜晶系,空间群分别为P21和P21/c。化合物1和2具有孤立三角锥[TeS3]2-阴离子,化合物1的平衡阳离子为双质子化乙二胺[H2en]2+,阴离子基团[TeS3]2-和阳离子基团[H2en]2+之间通过N-H…S氢键连接。化合物2的阳离子基团为过渡金属Ni与乙二胺的配合物[Ni(en)3]2+。另外,对该2种晶体进行了紫外-可见漫反射光谱测试和热重分析。     

有机杂化锡硫化合物[Ni(tepa)]2 (μ2 -Sn2 S6 )的溶剂热合成及晶体结构

利用溶剂热法合成了有机杂化锡硫化合物[Ni(tepa)]2(μ2-Sn2S6)(1,tepa=四乙烯五胺),其结构和光吸收特性经IR,元素分析和UV表征,晶体结构由X-射线单晶衍射仪测定。1属于四方晶系,空间群为I41/a,晶胞参数:a=0.909 0(17)nm,b=1.305 1(2)nm,c=1.299 2(2)nm,β=92.918(4)°,V=1.539 3(5)nm3,Z=4,Mr=462.89 g.mol-1,Dc=1.997 g.cm-3,μ=3.243 mm-1,F(000)=928,R1=0.070 2,wR2=0.151 2[I>2σ(I)],S=1.075。1中Ni2 离子与tepa配体的5个N原子和[Sn2S6]4-阴离子的一个端基S原子配位,形成了畸变八面体几何构型。[Sn2S6]4-阴离子作为桥连配体,通过端基S原子与[Ni(tepa)]2 配阳离子连接形成了中性的中心对称化合物[Ni(tepa)]2(μ2-Sn2S6)。     

有机杂化含Te2^2-／Se3^2-过渡金属化合物的溶剂热合成及晶体结构

本文通过溶剂热法合成了2种新的有机杂化锌碲化物[Zn(dien)2](Te2)(1)和镍硒化物[Ni(dien)2](Se3)(2)(dien=二乙烯三胺),单晶X射线衍射分析结果表明,化合物1属于正交晶系,Cmca空间群,晶胞参数:a=9.212(2),b=10.854(3),c=15.723(4),Z=4。化合物2属于正交晶系,Pna21空间群,晶胞参数:a=18.047(4),b=9.8236(19),c=9.0079(19),Z=4。在两种化合物中,1的阳离子中Zn2 与2个dien螯合形成稍变形的八面体几何构型,阴离子为哑铃型的Te22-。2的阳离子中Ni2 离子与2个dien螯合形成稍变形的八面体几何构型,阴离子为‘V’字型的Se32-。     

金属硫族化合物CsSb2(Se2)0.5Se3的溶剂热合成及其晶体结构分析

以有机溶剂热生长技术(Solvothermal Technique)在180 ℃乙二胺(en)溶液中以SbCl₃与碱金属硒化物Cs₂Se和Se在密闭容器中反应7 d,制备出新的金属硫族化合物CsSb₂(Se₂)_0.5Se₃。以单晶X射线衍射技术测得晶体结构属三斜晶系,空间群为P1,晶胞参数：a=0.653 0(2) nm,b=0.707 1(3) nm,c=0.979 9(4) nm,α=80.37(3)°,β=86.28(3)°,γ=74.61(3)°,V=0.430 0(3) nm³,Z=2。     

二维层状金属碲化物[Mn（en）3]Ag2Sn2Te8的制备及其晶体结构的分析

鉴于硫族金属化合物特殊的物理化学性质及其在半导体材料、催化剂研究、高温超导材料等高科技领域的诸多应用,在近十年内,人们竞相研究,合成出了成百上千新的二元、三元、四元的金属硫化物,金属硒化物和金属碲化物.高温直接反应方法是制备金属碲化物的一种最常用的方法,如:K2BaSnTe4,RbTaCu2Te4,K2Ag2SnTe4,K2HgSnTe4等均是在400～500℃左右的温度下,以单质元素与二元的碲化物直接反应得到的.在该领域中,近年来低温合成技术,如电解法[1],水热法[2]的应用日益受到重视.采用以有机物为溶剂的低温合成技术是90年代以来才取得发展并逐渐成熟起来的.如RbHgSbTe3[3],Rb2Hg3Te4[4]都是采用该低温合成技术而制备成功的.有机溶剂热生长技术与传统的水热法(Hydrothermal)不同之处在于可以根据实验的需要而选用具有不同沸点、带有不同极性及不同官能团的有机溶剂,从而拓宽了该技术的应用范围.本文报道的[Mn(en)3]Ag6Sn2Te8就是以乙二胺为溶剂,以SnTe,MnCl2,AgCl与Te为原料,在180℃下反应得到的.     

三维氢键超分子稀土锑硒化合物[Tb(en)_4]SbSe_4·0.5en的溶剂热合成与晶体结构

<正>锑和锡等主族金属多元硫属化合物具有独特的物理和化学性质,这类化合物作为多功能材料,因其在半导体、光电导体、光致发光、非线性光学等方面的广泛应用而受到人们的关注[1,2]。自溶剂热法合成含钴的锑硫化物[Co(en)3]CoSb4S8以来[3],人们利用溶剂热技术,在乙二胺(en)水溶液中合成了一系列含过渡金属配离子的多元锑硫属化合物,如[M(en)3]Sb2S4(M=Co,Ni)、[M(en)3]Sb4S7(M=Fe,Ni)[4]、[Fe(en)3]2(Sb2 Se5)[5]、     

二维层状金属碲化物[Mn(en)3]Ag6Sn2Te8的制备及其晶体结构的分析

鉴于硫族金属化合物特殊的物理化学性质及其在半导体材料、催化剂研究、高温超导材料等高科技领域的诸多应用,在近十年内,人们竞相研究,合成出了成百上千新的二元、三元、四元的金属硫化物,金属硒化物和金属碲化物.高温直接反应方法是制备金属碲化物的一种最常用的方法,如:K2BaSnTe4,RbTaCu2Te4,K2Ag2SnTe4,K2HgSnTe4等均是在400～500℃左右的温度下,以单质元素与二元的碲化物直接反应得到的.在该领域中,近年来低温合成技术,如电解法[1],水热法[2]的应用日益受到重视.采用以有机物为溶剂的低温合成技术是90年代以来才取得发展并逐渐成熟起来的.如RbHgSbTe3[3],Rb2Hg3Te4[4]都是采用该低温合成技术而制备成功的.有机溶剂热生长技术与传统的水热法(Hydrothermal)不同之处在于可以根据实验的需要而选用具有不同沸点、带有不同极性及不同官能团的有机溶剂,从而拓宽了该技术的应用范围.本文报道的[Mn(en)3]Ag6Sn2Te8就是以乙二胺为溶剂,以SnTe,MnCl2,AgCl与Te为原料,在180℃下反应得到的.     

Solvothermal synthesis and crystal structure of Sb(III) and Sb(V) thioantimonates: [Mn(en)3]2Sb2S5 and [Ni(en)3(Hen)]SbS4

Thioantimonate compounds of [Mn(en)₃]₂Sb₂S₅ (1) and [Ni(en)₃(Hen)]SbS₄ (2) (en=ethylenediamine) were prepared by reaction of transition metal chloride with Sb and S₈ powders under solvothermal conditions. Compound 1 consists of discrete [Sb₂S₅]⁴⁻ anion, which is formed by corner-sharing SbS₃ trigonal pyramids. Compound 2 is composed of discrete tetrahedral [SbS₄]³⁻ anion. The compounds 1 and 2 are charge compensated by [M(en)₃]²⁺ cations, whereas in the crystal of 2 there is another counter ion of [Hen]⁺. The results of the synthesis suggest that the temperature, the concentration and the existing states of the starting materials and so on are important for the structure and composition of the final products. In addition, the oxidation-state of antimony might be related to the molar ratio of the reactants. Excess amount of elemental S is beneficial to the higher oxidation-state of thioantimonate (V). Compound 1 decomposes from 150°C to 350°C, while compound 2 decomposes from 200°C to 350°C remaining Sb₂S₃ and NiSbS as residues.     

Temperature Influence on the Formation of Selenidoantimonates: Solvothermal Syntheses,Crystal Structures and Thermal Properties of [Ni(dien)2]2Sb2Se6, [Mn(dien)2]2(SbSe4)(Cl), [Co(dien)2]2(SbSe4)(Br), and [Co(dien)2]3(SbSe4)2

New selenidoantimonats [Ni(dien)₂]₂Sb₂Se₆ ( 1 ), [Mn(dien)₂]₂(SbSe₄)(Cl) ( 2 ), [Co(dien)₂]₂(SbSe₄)(Br) ( 3 ), and [Co(dien)₂]₃(SbSe₄)₂ ( 4 ) (dien = diethylenetriamine) were solvothermally synthesized in dien solvent at 180 °C. The crystal structure of 1 consists of two octahedral [Ni(dien)₂]²⁺ cations and a mixed‐valent [Sb₂Se₆]^4? anion. The isolated [Sb₂Se₆]^4? anion is formed by a Sb^IIISe₃ trigonal pyramid and a Sb^VSe₄ tetrahedron sharing a common corner. 2 and 3 are composed of octahedral [M(dien)₂]²⁺ cations, tetrahedral [SbSe₄]^3? anions and halide ions forming an extended network through hydrogen‐bonding interactions. In 4 the [Co(1)(dien)₂]²⁺, [Co(2)(dien)₂]²⁺ and [SbSe₄]^3? ions form layered structures via N–H···Se hydrogen bonds. The [Co(3)(dien)₂]²⁺ ion is located between the layers, and interacts with the layers by N–H···Se bonds. The synthesis and solid state structural studies on the title compounds show that the higher reaction temperature is helpful for the formation of selenidoantimonate(V) compounds in the synthesis of selenidoantimonate from the M²⁺/Sb/Se/dien system. 1 – 4 start to decompose at temperature about 210 °C in N₂ atmosphere. They lose dien ligands at a wide temperature range of 210–450 °C with multisteps for 1 – 3 and a single step for 4 .     

Solvothermal Syntheses and Characterization of Three One-dimension Cadmium Selenidoarsenates [Ni(1,2-dap)3][As2CdSe4],[Zn(1,2-dap)3][As2CdSe4] and [Ni(en)3][As2CdSe4]

Three new cadmium selenidoarsenates,[Ni(1,2-dap)3][As2CdSe4](1)(1,2-dap=l,2-diaminopropane),[Zn( 1,2-dap)3][As2CdSe4](2) and [Ni(en)3][As2CdSe4](3)(en=ethylenediamine), were synthesized under solvothermal conditions. And they are isostnictural and monoclinic crystalls. As seen from their structures, they exhibited one-dimensional(1D) chains composed of [As2CdSe4]^2- anions and [TM(amine)3]^2+(TM=Ni,Zn;amine=1,2-dap, en) cations. Their absorption edges are 2.32, 1.84 and 2.38 eV and they show the properties of the semiconductor. These compounds were also characterized by means of single-crystal X-ray ditlraction(XRD), powder X-ray diflraction (PXRD), solid-state optical absorption spectrometry, and so on.     

Three New Thioantimonates(V): Solvothermal Syntheses and Crystal Structures of [M(chxn)3]3(SbS4)2·4H2O (M = Ni,Co) and [Co(dien)2][Co(tren)SbS4]2·4H2O

The three new thioantimonates(V) [Ni(chxn)₃]₃(SbS₄)₂·4H₂O ( I ), [Co(chxn)₃]₃(SbS₄)₂·4H₂O ( II ) (chxn is trans‐1,2‐diaminocyclohexane) and [Co(dien)₂][Co(tren)SbS₄]₂·4H₂O ( III ) (dien is diethylenetriamine and tren is tris(2‐aminoethyl)amine) were synthesized under solvothermal conditions. Compounds I and II are isostructural crystallizing in space group C2/c. The structures are composed of isolated [M(chxn)₃]²⁺ complexes (M = Ni, Co), [SbS₄]^3? anions and crystal water molecules. Short S···N/S···O/O···O separations indicate hydrogen bonding interactions between the different constituents. Compound III crystallizes in space group and is composed of [Co(dien)₂]²⁺ and [Co(tren)SbS₄]^? anions and crystal water molecules. In the cationic complex the Co²⁺ ion is in an octahedral environment of two dien ligands whereas in [Co(tren)SbS₄]^? the Co²⁺ ion is in a trigonal bipyramidal coordination of four N atoms of tren and one S atom of the [SbS₄]^3? anion, i.e., two different coordination polyhedra around Co²⁺ coexist in this compound. Like in the former compounds an extended hydrogen bonding network connects the complexes and the water molecules into a three‐dimensional network.     

Solvothermal Synthesis and Crystal Structure of the New Layered Thioantimonate(III) [Ni(C4H13N3)2]9Sb22S42 · 0.5H2O: Interconnection of the SbS3, SbS4, and SbS5 Primary Building Units Yielding the Very Large Sb30S30 Heteroring

The novel thioantimonate(III) [Ni(dien)₂]₉Sb₂₂S₄₂ · 0.5H₂O was synthesised under solvothermal conditions by reacting elemental Ni, Sb and S in an aqueous solution of diethylenetriamine (dien) (80%). The compound crystallises in the triclinic space group P1¯, a = 8.997(2) Å, b = 15.293(3) Å, c = 34.434(7) Å, α = 85.51(3)°, β = 84.16(3)°, γ = 83.54(3)°, V = 4672.7 (16) ų, Z = 1. The layered [Sb₂₂S₄₂^18—] anion in [Ni(dien)₂]₉Sb₂₂S₄₂ · 0.5H₂O is composed of nine SbS₃ trigonal pyramids, one SbS₄ and one SbS₅ unit. The interconnection of these units by sharing common S atoms yields Sb‐S heterorings of different sizes. Besides the smaller Sb₂S₂ and Sb₃S₃ rings a very large Sb₃₀S₃₀ heteroring is observed. The structure directing effect of the [Ni(dien)₂]²⁺ cations is obvious as they are located above and below the pores of the anion. The nine [Ni(dien)₂]²⁺ cations exhibit different conformations. All Ni²⁺ cations are in an octahedral environment of six N atoms of two dien ligands. The anions and cations are stacked perpendicular to [100] in an alternating fashion.     

On the Flexibility of Thioantimonate Networks: Solvothermal Syntheses and Crystal Structures of Six New Thioantimonates(III) with the [Sb4S7]2− Anion

Six new thioantimonates(III) with the [Sb₄S₇]²⁻ anion were obtained under solvothermal conditions with in‐situ formed transition metal complexes as structure directors. In the two isostructural compounds [Fe(dien)₂]Sb₄S₇·H₂O ( 1 ) and [Co(dien)₂]Sb₄S₇·0.5 H₂O ( 2 ) (dien = diethylenetriamine; space group: P2₁/c) the layered [Sb₄S₇]²⁻ anion is characterized by Sb₈S₈ rings with a diameter of about 9.6·7.6Å. The cation complexes are located above and below the pores of the rings. Despite the larger size of the cation complex the network topology of the third thioantimonate [Ni(dien)(tren)]Sb₄S₇ ( 3 ) (tren = tris(2‐aminoethyl)amine; space group: P2₁/n) is similar to that of the first two compounds. In the isostructural thioantimonates [M(trien)]Sb₄S₇ (M = Zn ( 4 ); M = Mn ( 5 ); trien = triethylenetetramine; space group: ) the M²⁺ ions are fivefold coordinated by four N atoms of the amine molecule and by one S atom of the thioantimonate anion forming a MN₄S trigonal bipyramid. Sb₈S₁₆ building blocks are the central structural motifs of the anion. Two of the terminal S atoms at the periphery of the Sb₈S₁₆ units are bound to M²⁺ ions and the four remaining terminal S atoms connect adjacent Sb₈S₁₆ groups into the final [Sb₄S₇]²⁻ chain. [Ni(tren)]Sb₄S₇ ( 6 ) (space group: ) contains a one‐dimensional anionic chain. The Ni²⁺ ion has two bonds to the [Sb₄S₇]²⁻ anion which is a unique feature in the thioantimonate(III) chemistry. The NiN₄S₂ octahedron is severly distorted with one very long Ni‐S bond of 2.782(2) Å. In all compounds several short S···H distances indicate hydrogen bonding interactions.     

Solvothermal Synthesis,Crystal Structure and Properties of a New Organic Templated Lanthanum Sulfate [C4N3H16][La(SO4)3(H2O)]

A new organic templated lanthanum sulfate [C₄N₃H₁₆][La(SO₄)₃(H₂O)] ( 1 ) has been solvothermally synthesized by using n‐butanol as solvent. The colorless block crystals were characterized by IR, TGA, ICP, and XRD. The structure was determined by single‐crystal X‐ray diffraction: Monoclinic, P2₁/c, a = 10.8878(19), b = 15.478(3), c = 9.9639(18) Å, β = 114.062(2)°, V=1533.2(5) ų, Z = 4]. Crystal structure analysis shows that the one dimensional chain of 1 consists of the LaO₉ polyhedra and the sulfate groups. Coordination water molecules link adjacent chains by using hydrogen bonds to generate 2D layers, whereas the organic amines are inserted between the layers. The formation of 1 demonstrates that solvents play an important role during the synthesis.     

Solvothermal Syntheses and Characterization of Thiostannates [M(en)3]2Sn2S6 (M = Mn,Co, Zn), the Influence of Metal Ions on the Crystal Structure

Three new thiostannates [M(en)₃]₂Sn₂S₆ (en = ethylenediamine, M = Mn( 1 ), Co( 2 ) and Zn( 3 )) were synthesized by solvothermal method. The crystals were grown up in a Teflon‐lined steel autoclave at temperature about 180 °C. All the three compounds consist of discrete [Sn₂S₆]^4— anions, which are dimer of two tetrahedral SnS₄ sharing a common edge. The transition metal cations are six‐coordinated by three ethylenediamine molecules forming octahedral complex ions. Although the synthetic procedures, the mole ratio of the reactants and the solvent are essentially the same, the compound of Mn^II is quite different in structure from that of compounds of Co^II and Zn^II. Compound 1 crystallizes in monoclinic crystal system, C2/c, whereas compounds 2 and 3 crystallize in the orthorhombic crystal system, Pbca. Unlike compound 1 , the [M(en)₃]²⁺ cations in 2 and 3 are disordered. The difference of molecular packing between 1 and 2 ‐ 3 is considered due to the influence of the entities of the metal ions, such as radii and the coordination properties. The thermal chemical behaviors of the compounds 1 ‐ 3 were discussed and the results are also related to the property of the metal ions.     

Synthesis,Crystal Structure,Optical, Magnetic,and Thermal Properties of the New Heteroleptic Chromium Complex [Ph4P][Cr(en)(S5)2]

The new heteroleptic chromium complex [Ph₄P][Cr(en)(S₅)₂] has been synthesised under mild solvothermal conditions by the reaction of chromium trichloride, sulfur, and tetraphenylphosphoniumbromide in a solution of ethylendiamine ( en ) in water. The crystal structure consists of isolated tetraphenylphosphonium cations and [Cr(en)(S₅)₂]^– anions. The Cr³⁺ cations are in an octahedral coordination of two bidentate S₅^2– polysulfide anions and one bidentate en ligand. The N atoms of the en ligand and the terminal S atoms of the S₅^2– anions bonded to the Cr³⁺ ions are in a cis-position. The six-membered CrS₅ rings are in a chair conformation. The three dimensional arrangement of the cations and anions is achieved via intermolecular hydrogen bonds. Investigations with differential thermal analysis (DTA) combined with thermogravimetry (TG) show a stepwise decomposition. In the first step the en ligand is removed completely followed by the emission of a part of the tetraphenylphosphonium cations and the sulfur atoms in the second step. The temperature dependence of the magnetic susceptibility exhibits a Curie-Weiss behaviour with an effective magnetic moment typical for a Cr³⁺ (d³) ion and a value for the Weiss constant of 1.3(2) K. Fourier transform infrared spectroscopy (FTIR) was also performed to characterise the optical properties.