水氯镁石合成3MgCO_3·Mg(OH)_2·3H_2O的研究

本文探讨了以盐湖提钾后的老卤蒸干所得的水氯镁石为原料,以纯碱法合成3MgCO3.Mg(OH)2.3H2O,并对反应中初始反应温度的确定机理进行了探讨,对Mg2+的浓度、原料配比、热解时间、静置时间、烘干时间等进行了实验设计,获得了合成3MgCO3.Mg(OH)2.3H2O的最佳条件,对碱式碳酸镁的制备机理进行了探讨。为盐湖镁资源的开发及综合利用提供一条有效途径。

Mg_2(OH)_2CO_3·3H_2O Whiskers Growth Mechanism

From the perspective of growth units, the growth mechanism of Mg2（OH）2CO3.3H2O whisker is investigated in this paper. Results show that the growth morphology of Mg2（OH）2CO33H2O whisker is consistent with the model of anion coordination polyhedron growth units. The growth solution Raman shift of Mg2（OH）2CO;3H2O was monitored using Raman spectroscopy. The growth units are [Mg-（OH）4]2- and H2COv The growth process of Mg2（OH）2COf3H2O whisker is as follows： growth unit [Mg-（OH）4]2- first incorporates into the larger dimension [Mg-（OH）4]2-, then the [Mg-（OH）4]2-n combines with H2CO3 into a linear skeleton Mg2（OH）2CO3 in the same line. Mg2（OH）2CO3 combines with H2O by hydrogen bonds and ultimately transforms into Mg2（OH）2COf3H2O whisker. Magnesium carbonate whiskers have a layered structure, each of which is made of magnesium, carbon, oxygen, with H2O in between each layer. When skeletons are superimposed within the same plane as a parallelepiped one, they grow into solid cuboid-shaped whiskers. When the parallelepiped skeletons planes combine with each other through the cascading links, they grow into hollow cylindrical whiskers.

MgSO_4·5Mg(OH)_2·3H_2O的水热合成及反应时间对其形貌的影响(英文)

Both whisker and nanometer MgSO4·5Mg(OH)2·3H2O(MOS) were prepared by hydrothermal method at 140℃for different times, using NaOH and MgSO4·7H2O as raw materials. The MgSO4·5Mg(OH)2·3H2O part icles were characterized by powder X ray diffraction(XRD),thermal analysis(TGA DSC), infrared spectroscopy(FT IR),transmission electron microscopy(SEM) and scanning electron microscopy(TEM). The size distribution in whisker like and nanocrystalline materials arein the range of 10～50μm and 10～20nm respectively. The whisker MOS is metastable phase in MgSO4 NaOH H2O system at 140℃,whereas nanometer MOS is stable phase.

纳米晶MgSO_4·5Mg(OH)_2·3H_2O合成与表征

Nanocrystalline MgSO\-4·5Mg（OH）\-2·3H\-2O were prepared by the hydrothermal reaction at 140 ℃ for 24 h. Nanoparticle samples were characterized by FTIR, TG, DSC, XRD and TEM. The size distribution of nanocrystalline is in the range of 10\20 nm, the mean size is 16 nm.

pH值对Mg_2(OH)_2CO_3·3H_2O晶须生长机制的影响

研究了pH值对Mg_2(OH)_2CO_3·3H_2O晶须生长过程的影响。发现在较低的p H值下Mg_2(OH)_2CO_3·3H_2O易于形成空心管状的晶须,而在较高的p H值下则易形成层板状的晶须。结合拉曼光谱,利用负离子配位多面体生长基元模型分析了管状Mg_2(OH)_2CO_3·3H_2O晶须生长过程。

Synthesis of Mg_5(CO_3)_4(OH)_2·4H_2O with Flower-like Micro-structure and Its Catalytic Activity for Transesterification of Dimethyl Carbonate with Phenol

A novel flower-like hydrated magnesium carbonate hydroxide, Mg5 （CO3 ）4 （OH）2·4H2O, with micro-structure composed of individual thin nano-sheets was synthesized using a facile solution route without the use of template or organic surfactant. Reaction time has an important effect on the final morphology of the product. The micro-structure and morphology of Mg5 （CO3）4 （OH）2·4H2O were characterized by means of X-ray diffractometry （XRD）, fieldemission scanning electron microscopy（FE-SEM）. Brunauer-Emmett-Teller（BET） surface areas of the samples were also measured. The probable formation mechanism of flower-like micro-structure was discussed. It was found that Mg5 （CO3）4（ OH）2·4H2O with flower-like micro-structure was a novel and efficient catalyst for the synthesis of diphenyl carbonate （DPC） by transesterification of dimethyl carbonate （DMC） with phenol.

Liquid precipitation and microstructure of Mg6Al2(OH)15NO3CO3·4H2O whiskers

High-quality LDH-NO_3-CO_3 whiskers were synthesized via a liquid precipitation method using Mg(NO_3)_2·6H_2O and Al(NO_3)_3·9H_2O as raw materials and Na_2CO_3-NaHCO_3 buffer solutions as precipitant. The whiskers were characterized by X-ray diffraction, transmission electron microscope, and Brunauer-Emmett-Teller N_2 surface area measurement. The influence of buffer solution concentration on the characteristics of the sample was investigated. The results show that the buffer solution concentration has significant impact on whiskers with intercalated structure. Overall, LDH-NO_3-CO_3 whiskers with well-defined geometry, distinct intercalated structure, high quality, and good dispersion capability can be obtained under the following conditions: buffer solution volumetric ratio of 60%, reaction temperature of 55°C, and reaction time of 269 h.

在缓冲液中制备Mg_6Al_2(OH)_(13)-SO_4-CO_3-Br·5.5H_2O及其结构分析

以MgBr_2·6H_2O、Al_2(SO_4)_3·18H_2O为原料,Na_2CO_3-NaHCO_3缓冲对为沉淀剂,合成了优质的Mg_6Al_2(OH)_(13)-SO_4-CO_3-Br·5.5H_2O晶须.样品用XRD、SEM、N2吸附-解吸进行了物相、粒度、晶体形貌结构分析.分析了缓冲对体积分数对LDH-SO_4-CO_3-Br晶须晶形及晶胞参数的影响.结果发现,缓冲对用量在体系中含量的大小对其规整性、板层结构有较大的影响.当缓冲液用量为40%,反应温度T=75?C,反应时间t=212h时可获得晶形好、板层结构显著、规整性好、分散性好的优质LDH-SO_4-CO_3-Br晶须.

Li_2Mg_2Si_4O_(10)F_2、H_2Mn_8O_(16)·1.4H_2O和Li_(1.3)Ti_(1.7)Al_(0.3)(PO_4)_3在高浓度LiCl水溶液中的离子交换行为

研究了用功能材料Li_2Mg_2Si_4O_(10)F_2(LHT)、H_2Mn_8O_(16)·1.4H_2O(CRYMO)和Li_(1.3)Ti_(1.7)Al_(0.3)(PO_4)_3(LTAP)分别去除高浓度氯化锂水溶液中的杂质Fe^(3+)、K^+和Na^+.实验结果表明,这几种功能材料分别对溶液中的杂质Fe^(3+)、K^+和Na^+有很高的选择性,除杂效果明显.分析和研究了这几种功能材料在高浓度氯化锂水溶液中分别与Fe^(3+)、K^+和Na^+的交换行为.结果表明,在高浓度氯化锂溶液中这几种功能材料与杂质交换的动力学行为可近似用JMAK方程描述.

Cu/TiO_2-NiO上光促表面催化CO_2和H_2O合成CH_3OH反应规律

采用溶胶-凝胶法制备了n(电子型)-p(空穴型)复合半导体材料0.5%Cu/TiO2-2.0%NiO(w),利用X射线衍射(XRD)、透射电镜(TEM)、红外光谱(IR)、紫外-可见光漫反射(UV-Vis)、程序升温脱附(TPD)技术对材料结构、吸光性能、化学吸附性能进行了表征,研究了该材料对CO2和H2O合成CH3OH的光促表面催化反应(PSSR)规律.结果表明,所制备材料能够明显促进目的反应,室温条件下即有CH3OH生成.在200℃下,由于光-表面-热的协同效应,CO2转化率得以提高,且CH3OH的选择性达到87.5%.根据实验结果,得出CO2在材料表面的卧式吸附态为CH3OH的前驱物,并对PSSR机理进行了讨论.

Cu_3V_2O_7(OH)_2·2H_2O纳米线的制备及其电化学性能

以CuSO4.5H2O和NH4VO3为原料,采用水热法制备了Cu3V2O7(OH)2.2H2O纳米线。利用XRD、FE-SEM、TEM和HRTEM对样品的结构和表面形貌进行了表征,并对其作为锂电池正极材料的电化学行为进行了研究。电化学性能测试表明,Cu3V2O7(OH)2.2H2O纳米线电极具有较高的开路电压和较大的放电容量。

[Ho_2(phen)_4(H_2O)_4(OH)_2](phen)_2(NO_3)_4的合成、晶体结构及磁性

在甲醇与水的混合溶剂中 ,经浓硝酸硝化的Ho2 O3 与 1,10 邻菲啉反应形成氢氧根桥联的双核钬配合物[Ho2 (phen) 4(H2 O) 4(OH) 2 ](phen) 2 (NO3 ) 4(phen =1,10 邻菲啉 ) .单晶X射线衍射晶体结构测定表明晶体属三斜晶系 ,P 1(no .2 )空间群 ,晶胞参数a =1.12 41(1)nm ,b =1.1439(1)nm ,c =1.40 5 8(1)nm ,α =93.989(7)°,β =98.173(7)° ,γ =10 8.19(1)°,V =1.6 874(4 )nm3 ,Z =1,Dc=1.737g/cm3 ,F(0 0 0 ) =880 ,775 2个独立衍射点中 ,5 70 2个可观测点满足Fo2 ≥ 2σ(Fo2 ) ,R1=0 .0 499,wR2 =0 .0 85 8.标题配合物由中心对称的双核 [Ho2 (phen) 4(H2 O) 4 (OH) 2 ]4 + 配阳离子 ,邻菲啉phen分子及硝酸根NO-3 阴离子组成 .每个稀土原子与 2个邻菲啉配体 ,2个水分子和 2个氢氧根配位形成配位数为 8的 [HoN4 O4 ]四方反棱柱 .配位多面体通过两氢氧根基团形成共棱的 [Ho2 N8O6]双四方反棱柱 [d(Ho—N) =0 .2 5 49～ 0 .2 5 6 5nm ,d(Ho—OH2 O) =0 .2 35 6 ,0 .2 36 6nm ,d(Ho—OOH) =0 .2 2 2 3,0 .2 2 40nm].通过氢键和芳环堆积作用 ,配阳离子和邻菲啉分子排列形成平行于 (10 1)的两维层结构 ,NO-3 阴离子位于层之间 .标题配合物为顺磁物质 ,在 5～ 30 0K区间内遵循Curie Weiss定律 ?

一维链状高价锰配合物[Mn_2(C_7H_4O_3)_4(CH_3OH)_2]·4H_2O_2CH_3OH的合成与结构

合成了一维链状高价锰配合物[Mn2(C7H4O3)4(CH3OH)2]4H2O2CH3OH,并对其进行了IR、X-射线衍射、UV-Vis和TG-DSC等表征。单晶衍射结果表明,该配合物晶体属三斜晶型,空间群P?晶胞参数a=7.653(5),b=10.486(7),c=12.943(8),=103.24(1),?=104.55(1),?=110.11(1),V=885.4(9)3,Z=1。UV-Vis光谱在547nm有一个吸收峰,相应于Mn(Ⅳ)的d-d电子跃迁光谱。

二维聚合物[MnNa(Salicylate)_2(CH_3OH)(H_2O)]_n·0.5nH_2O的合成、晶体结构与活性研究

In this paper, a novel polymeric complex [MnNa（Salicylate）2（CH3OH）（H2O）]n·0.5nH2O was obtained and characterized by IR spectra, elemental analysis and single crystal X-ray diffraction. The titled complex is crystallized in triclinic system, space group P1 with a=0.763 82（15） nm, b= 1.037 1（2） nm, c=1.290 9（3） nm, α= 103.59（3）°, β=104.65（3）°, γ=109.50（3）°, V=0.873 6（3） nm 3, Z=2, Dc=1.556 Mg/m 3, Mr=409.20, μ=0.823 mm -1, F（000）=418, R=0.0614, wR= 0.147 6. The activity in catalyzing the superoxygen anionic free radical dismutation was determinated.

Cu_3V_2O_7(OH)_2·2H_2O纳米线的制备及光吸收性能

以CuSO4.5H2O和NH4VO3为原料,采用水热法制备了Cu3V2O7(OH)2.2H2O纳米线。采用X射线衍射(XRD)和场发射扫描电子显微镜(FE-SEM)对样品的组成和表面形貌进行了表征,结果显示:Cu3V2O7(OH)2.2H2O纳米线直径约80 nm,长度达到几个微米。对纳米线形成机理研究表明:该纳米线的形成主要取决于反应温度和反应体系pH值等因素。紫外-可见光吸收测试显示Cu3V2O7(OH)2.2H2O纳米线具有较宽的紫外-可见光吸收范围,计算其带隙宽度为1.94 eV。

三维孔道结构(H_3NCH_2CH_2NH_3)_2(H_3NCH_2CH_2NH_2)[V~Ⅲ(H_2O)_2(V~ⅣO)_8(OH)_4(H(P,B)O_4)_4(P,B)O_4)_4(H_2O)_2]·3H_2O的水热合成及晶体化学研究——(1)水热合成与产物表征

为了探讨化学成份对VPO体系孔道结构化合物结构稳定性的影响,根据酸碱平衡原理进行了合成实验设计;利用V2O5、H3PO4、H3BO3等简单的无机前驱物、乙二胺作结构导向剂,水热法合成了孔道结构钒硼磷酸盐化合物(H3NCH2CH2NH3)2(H3NCH2CH2NH2)[VⅢ(H2O)2(VⅣO)8(OH)4(H(P,B)O4)4((P,B)O4)4(H2O)2]·3H2O(简称V9(P,B)8-en).典型的反应起始物摩尔比为n(V2O5):n(H3BO3):n(H3PO4):n(en):n(H2O)=0.89:3.50:3.50:3.60:265(pH值为6.5),在175℃、自生压力条件下恒温晶化6.5d(最终pH值为5.9).通过电子探针、粉末X射线衍射、红外吸收光谱、原子占位度修正等方法,对产物的化学成份、物相及其结构等进行了实验研究.证实V9(P,B)8-en为V9P8-en的类质同象化合物,不同晶粒中B与P的含量有差别,B与P之比为O.1:7.9～2.54:5.46(原子比),但恒有V:(P+B)≈9:8.表明通过合理设计和控制合成条件,可在保持V9P8-en基本结构不变的前提下通过同晶取代引入新的化学成份,并由此探讨成份与结构稳定性的关系.

新型磷-钒-氧层状化合物[H_2en]_2[H_3O]_6[Co(H_2O)_2(VO)_8(OH)_4(PO_4)_8]的水热合成与晶体结构

A new compound 2 6[Co(H 2O) 2(VO) 8(OH) 4(PO 4) 8] has been hydrothermally synthesized. Single crystal X-ray analysis indicates that this compound crystallizes in a monoclinic system, space group P2 1/n with a=1.438 5(3) nm, b=1.012 2(2) nm, c=1.832 5(4) nm, β=90.21°, V=2\^668 2(9) nm 3, Z=2, D c=2.112 g/cm 3, R=0.055, wR=0.149 7, S=1.037. The structure of 2 6[Co(H 2O) 2(VO) 8(OH) 4(PO 4) 8] is characterized by P-V-O layers constructed by [(VO) 4(OH) 2(PO 4) 4] 6- non-symmetric units. The P-V-O layers are pillared by [Co(H 2O) 2] 2+ group, resulting in the channels within which the protonated diaminoethane and H 3O + are located.

Mg(CH_3COO)_2·4H_2O的热分解机理和动力学研究

用热分析(TG/DTG/DTA,DSC)、X射线衍射(XRD)技术研究了固态物质Mg(CH3COO)2.4H2O在氩气中热分解过程.热分析结果表明,Mg(CH3COO)2.4H2O在氩气中分两步分解.其质量变化率与理论计算相吻合.XRD结果表明,Mg(CH3COO)2.4H2O分解最终产物为MgO.用Friedman和FWO法对分解过程的活化能E进行了初步计算,依此为初始值,用多元非线性回归得到了分解步骤可能的机理函数和动力学参数.

配合物[Ni(EDTB)](NO_3)_2·2C_2H_5OH·H_2O的合成表征及对尿素水解的影响

报道了对称六齿配体N ,N ,N’ ,N’ ,-四 (2’ -苯并咪唑甲基 )乙二胺 (EDTB)的含镍(II)配合物 [Ni(EDTB) ](NO3 ) 2 ·2C2 H5OH·H2 O的合成、表征及其对尿素水解的影响。根据配合物元素分析、摩尔电导、紫外—可见红外、ESR谱和循环伏安等性质与已测X—射线单晶结构的同种配体含铜 (Ⅱ )单核配合物比较 ,推测此配合物中的Ni(II)离子被配体EDTB的 4个苯并咪唑 (Bzim)氮和 2个烷胺氮配位 ,形成一种畸变八面体几何构型。并用气相色谱法观测了此配合物对尿素水解反应的影响 ,结果表明它几乎无催化尿素水解的活性 。

Cu_3V_2O_7(OH)_2·2H_2O纳米片的制备及其在锂电池中的应用

以CuSO4.5H2O和NH4VO3为原料,采用沉淀法制备了Cu3V2O7(OH)2.2H2O纳米片。利用XRD、FE-SEM、TG对样品的结构和形貌进行了表征,并对其作为锂电池正极材料的电化学行为进行了研究。电化学性能测试表明:Cu3V2O7(OH)2.2H2O纳米片具有较高的放电容量和良好的高温放电性能,是一类性能优良的锂电池正极材料。