NH4VO3在NH4H2PO4-H2O和(NH4)3PO4-H2O体系中的溶解度

采用等温溶解法测定了偏钒酸铵(NH₄VO₃)在NH₄H₂PO₄-H₂O和(NH₄)₃PO₄-H₂O体系中T = 298.15-328.15 K时的溶解度以及溶液的密度和pH值。结果表明, NH₄VO₃的溶解度随着(NH₄)₃PO₄或NH₄H₂PO₄溶液浓度的增大,先降低后升高,这是由于同离子效应、化学反应平衡及离子活度的共同作用。比较T = 298.15K时, NH₄VO₃分别在NH₄H₂PO₄-H₂O、(NH₄)₂HPO₄-H₂O和(NH₄)₃PO₄-H₂O体系中溶解度,发现在相同的磷酸盐浓度下, NH₄VO₃的溶解度在NH₄H₂PO₄-H₂O体系中最大,在(NH₄)₃PO₄-H₂O体系中居中,在(NH₄)₂HPO₄-H₂O体系中最小。进一步地,在T = 298.15 K和磷酸盐浓度C = 0.5 mol·kg^-1时,结合pH值和反应溶度积常数K_SP等计算三个体系中的平均离子活度系数(γ_±),发现γ_±值在(NH₄)₂HPO₄-H₂O体系中最大,在(NH₄)₃PO₄-H₂O体系中居中,在NH₄H₂PO₄-H₂O体系中最小,与溶解度规律一致。     

CuSO4(ZnSO4)-CO(NH2)2-H2O三元体系在30℃时的等温溶度研究

报道了CuSO₄(ZnSO₄)-CO(NH₂)₂-H₂O两个三元体系在30℃时的等温溶度及饱和溶液的折光率,绘制了相应的溶度图和折光率-组成图.两个三元体系中分别形成了组成为CuSO₄·3CO(NH₂)₂·H₂O(异成分溶解)和ZnSO₄·CO(NH₂)·2H₂O(同成分溶解)的化合物,并通过元素分析、红外光谱、X射线粉末衍射及热分析对新相进行了表征.     

三元体系MgCl2-CO(NH2)2-H2O在25℃时的等温溶度与新相研究

测定了25℃时三元体系MgCl₂-CO(NH₂)₂-H₂O的等温溶度及饱和溶液的折光率和密度,且绘制成溶度图和性质-组成图.在三元体系内形成2个三元化合物新相:MgCl₂·CO(NH₂)₂·4H₂O(记作A)和Mgcl₂·4CO(NH₂)₂·2H₂O(记作B),B为新化合物.三元体系的溶度图由4支单饱和线[对应单饱和固相为MgCl₂·6H₂O、三元化合物A和B、CO(NH₂)₂]组成,这4支单饱和线两两交于3个三元无变点[对应双饱和固相为MgCl₂·6H₂O+A、A+B、B+CO(NH₂)₂].     

四元体系KCl-K2SO4-CO(NH2)2-H2O有25℃时的等温溶度研究

测定了四元体系KCl－K₂SO₄－CO(NH₂)₂－H₂O及边界三元体系K₂SO－CO(NH₂)₂-H₂O在25℃时的溶度及饱和溶液密度值和折光率,绘制了相应的溶度图及相应的组成-性质图.测定并绘制了该四元体系K₂SO₄单饱区的溶度面、折光率面和密度面图.两个体系的溶度图均属于低共饱型,平衡固相为组份化合物.     

体系Mg(NO3)2-MgCl2-H2O作为相变储能材料的相图预测

应用修正的BET热力学模型对Mg(NO₃)₂-MgCl₂-H₂O体系在273～373 K的相图进行预测, 发现两个共晶点, 并通过实验对共晶点组成材料的吸热和放热行为进行测定, 发现三元共晶点Mg(NO₃)₂•6H₂O(45.6%)-Mg(NO₃)₂•2H₂O (29.6%)-MgCl₂•6H₂O(24.8%)储能效果较差, 而二元共晶点Mg(NO₃)₂•6H₂O(61.6%)-MgCl₂•6H₂O(38.4%)在熔点附近具有很好的储放热能力, 其相变热焓经差热分析为136.8 J•g^－1, 说明该材料可用作潜在的相变储能材料.     

四元体系H3BO3-MgSO4-MgCl2-H2O在273.15K的溶解度等温线

作者考察了H₃BO₃-MgSO₄-MgCl₂-H₂O四元体系在273.15±0.05K温度下的溶解度等温线。四元体系共饱和点的液相组成为33.44%(重量)MgCl₃,1.77%MgSO₄和0.65%H₃B0₃。     

LaCl3-CH3CONH2-H2O体系的研究

本文报告三元体系LaCl₃-CH₃CONH₂-H₂O 在0℃和30℃的溶度及其饱和溶液的折光指数值。在这两个温度下都没有发现等人^[2]在1976年所报导的LaCl₃·6H₂O的存在。     

新晶态磷酸铝分子筛CFAP-6的合成与性质

磷酸铝分子筛是新的一类晶态无机材料.1982年美国联合碳化物公司首次公布了约廿种不同结构的磷酸铝分子筛的合成专利^[1],作者在研究P₂O₅-Al₂O₃-H₂O系统的水热合成中^[2],发现用Al₂(SO₄)₃溶液作为Al₂O₃源,固体(NH₄)₃PO₄·3H₂O作为P₂O₅源,加入适量的有机胺,也能合成分子筛相,新晶态分子筛CFAP-6就是用上述原料,在二正丁胺-(NH₄)₂O-P₂O₅-Al₂O₃-H₂O系统中水热合成的。     

2,2′-二甲基-4,4′-联苯二甲酸构筑的两个金属有机骨架

以2,2′-二甲基-4,4′-联苯二甲酸(H2L)为配体,采用溶剂热法合成了2个金属有机骨架:[Ni(μ₂-H₂O)(L)(DMF)(H₂O)]·0.5H₂O(1)和[Cd_2.5(L)(trz)₃(H₂O)₂]·2.5DMF(2)(DMF=N,N-二甲基甲酰胺,Htrz=1,2,4-三氮唑)。借助红外、热重、粉末和单晶X射线衍射对其进行了表征。单晶结构分析表明,1结晶于单斜晶系的P2₁/c空间群,镍离子处在拉长的[NiO₆]八面体中且分别被μ₂-H₂O和L^2-配体连接形成二维sql拓扑网络。2结晶于单斜晶系,C2/m空间群,含有3个不同的镉离子且均为扭曲的八面体构型。3个镉离子被三氮唑负离子以μ_1,2,4-桥连,在ab平面形成二维的kgd层,这些层再被L^2-配体沿c轴支撑形成(4,8)双节点的三维flu拓扑网络。热重分析表明,1和2的网络分别在390和230℃发生分解。     

三元体系LaCl3-Am(Am=Gly,Glu,Ser)-H2O(25℃)的研究

测定了3个三元体系LaCl₃-Am-H₂O(Am=Gly,Glu,Ser)在25℃时的溶度和饱和溶液的折光指数。报道了三元体系中生成的三元配合物La(Gly)Cl₃·2H₂O(A₁)、La(Gly)₃Cl₃·3H₂O(A₂)、La₂(Glu)₃Cl₆·8H₂O(C)、La(Ser)Cl₃·3H₂O(E)。用摩尔电导、红外光谱、X射线衍射、热分析及偏光显微镜鉴测定了各配合物的一些物理化学性质。     

4-ClCH2COAP-La(NO3)3-H2O和4-ClCH2COAP-LaCl3-H2O三元体系30℃时溶度测定

安替比林及其4位取代衍生物是较强的配位剂,可与不同的稀土盐作用生成组成各不相同的配合物,为了进一步探讨安替比林的衍生物对稀土离子的配位作用,我们研究了以4-一氯乙酰基安替比林(4-ClCH₂COAP)为配体与硝酸镧或氧化镧的三元水盐体系。     

Third-order Optical Nonlinearities of a Series of Compounds Derived from a Keplerate Type Molybdenum-oxide-based Polyoxometalate

Abstract By reacting the unique Keplerate type molybdenum-oxide based polyoxometalate （NH4）42·[MoI320372·（CH3COO）30（H2O）y2]·ca.300H2·ca. 10CH3COONH4（1） with tetramethylammonium bromide, a new derivative （NH4）26[TMA]16{MoI32O372（H2O）72（CH3COO）30}·ca.7NH4CH3COO·ca.189H2O（2, TMA=tetramethylammonium） was prepared. Compound 2 was characterized by Fourier transform infrared spectroscopy（FTIR）, UV-Vis, elemental and thermogravimetric analyses. By the well-established Z-scan technique, investigations on the nonlinear opti- cal（NLO） properties of the series of compounds derived from the Keplerate type molybdenum-oxide-based poly- oxometalate, namely, the newly prepared compound 2, the three previously reported compounds, included compound 1, （NH4hs（TBA）24{Mo132O372（H2O）72（CH3COO）30}·ca.7NH4CH3COO·ca. 173H2O（3, TBA=tetrabutylammonium） and （DODA）40（NH4）2[（H2O）nMo132O372（CH3COO）3o（H20）72]（4, DODA=dimethyldioctadecylammonium）, reveal that the third-order nonlinearity[x（3）] values of compounds 1, 2 and 3 in the DMF/H2O solution and compound 4 in chloro- form are almost the same, which indicates that the counter cations with different length of alkyl chains show ignora- ble impacts on the NLO susceptibility. In other words, the remarkable third-order nonlinearities[x（3）≈10 19 m2/V2] mainly come from the [MoI32O372（CH3COO）30（H2O）72]42 anions. This fact reveals that the applications of the NLO active polyoxometalates in various environments（such as hydrophilic, hydrophobic, polar, apolar, etc.） can be achieved by simply varying cations to meet the demands in the design of diverse devices. Keywords Keplerate type polyoxometalate; Nonlinear optical property; Z-Scan technique; Self-defocusing; Reverse saturable absorption     

Isothermal Evaporation of Quaternary System Li^＋, K^＋, Mg^2＋//Cl^--H2O at 348K

The solubilities of the quaternary system Li^＋,K^＋,Mg2^＋//Cl^--H2O were investigated at 348 K via isothermal evaporation.The densities and refractive indices of its equilibrated solution were also determined experimentally.On the basis of the obtained data,the metastable phase diagram,the water content diagram,the diagrams of the density and refractive index against the composition of this quaternary system were constructed.The quaternary system Li^＋,K^＋,Mg^2＋//Cl^--H2O at 348 K belongs to a complex type with the formation of two carnallite double salts,which are potassium carnallite（K-carnallite） and lithium carnallite（Li-carnallite）.There are five salts like potassium chloride （KCl）,lithium chloride monohydrate（LiCl.H2O）,bischofite（MgCl2·6H2O）,K-carnallite（KCl·MgCl2·6H2O） and Li-carnallite（LiCl·MgCl2·7H2O）,seven unvariant curves named AH3,BH2,CH3,DH1,EH1,H1H2 and H2H3,and three invariant points,namely H1,H2 and H3,included in this metastable phase diagram.Comparisons between the stable phase diagram at 298 K and metastable phase diagram at 348 K of this quaternary system show that all the crystalline forms of the salts are not changed,whereas the crystallization areas of salts are changed significantly with temperature.The scope of KCl crystallization increases from 82% to 95% and that of K-carnallite decreases from 15.80% to 0.32% along with the temperature increasing from 298 K to 348 K,respectively.