碱式氯化镁5Mg(OH)2·MgCl2·3H2O的制备与表征

以氨水和盐湖盛产的水氯镁石为原料经过两步反应制备碱式氯化镁。第一步,水氯镁石和氨水反应制备氢氧化镁;第二步,利用氢氧化镁和水氯镁石,通过水热反应得到了具有纤维形貌、结晶较好的碱式氯化镁。应用化学分析、XRD、SEM和FIIR等手段对产物进行测试与表征。化学分析结果表明产物组成为5Mg(OH)₂·MgCl₂·3H₂O。将得到的5Mg(OH)₂·MgCl₂·3H₂O和碱式氯化镁系列标准XRD图对照,未有较好的匹配,且结合化学分析和已报道碱式硫酸镁具有5Mg(OH)₂·MgSO₄·3H₂O物相,因而推测其为新物相;SEM图中5Mg(OH)₂·MgCl₂·3H₂O纤维直径约为0.4 μm,平均长度大于24 μm,长径比大于60;FTIR图谱中3 419 cm^-1附近出现了氢键的O-H伸缩振动吸收峰,1 635 cm^-1附近出现了游离水中H-O-H的弯曲振动吸收峰。水热合成的5Mg(OH)₂·MgCl₂·3H₂O和常压下的产物相比直径较小,晶形更完整,强度更高。     

纳米晶MgSO4·5Mg(OH)2·3H2O合成与表征

纳米材料由于具有表面、体积和量子尺寸效应的特殊性而受到广泛重视[1～3]. 微米级硫氧镁晶须作为塑料添加增强和阻燃剂已有报道[4～7]. 纳米晶MgSO4*5Mg(OH)2*3H2O不仅对塑料起补强作用, 而且其粒度小, 使塑料变得更致密, 强度、韧性与防水性能大大提高. 目前纳米材料的合成方法多种多样[8～10], 本文采用水热法制得纳米硫氧镁晶粒, 产物纯度高、分散性好且粒度易控制.     

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)

０IntroductionWhiskerswithhighaspectratiohavebeenexten－sivelyusedascompositematerialsinalloys，ceramics，cementandplastic犤１～５犦，sincetheyhavespecificdesirepropertiessuchashighmeltingpoint，lowdensityandhighmodulus犤６犦．Magnesiumoxysulfate（MOS）com－poundshowsthehighcrystallinityandaspectratiotomakeitapotentialreinforcingmaterialforplastics，resinandrubber犤７，８犦．Inpastyears，MgSO４·５Mg（OH）２·３H２Ohasbeensynthesizedbyhydrothermalreactionusingmagnesiumhydroxideandmagnesium…     

Mg(OH)2· 2MgSO4· 2H2O晶体的水热生长过程

对 MgSO4- NaOH- H2O四元交互体系在 160 ℃水热条件下 ,相同物料配比 ,不同反应时间的晶体生长过程进行了研究 ,得到 5Mg(OH)2@ MgSO4@ 2H2O(简称 MOS)晶须和 Mg(OH)2@ 2MgSO4@ 2H2O棒状晶体两种硫氧镁化合物 .通过化学分析、 X- ray粉末衍射、 FT- IR光谱和 SEM对反应产物进行了表征 .前者是该体系水热条件下介稳产物 ,而新的硫氧镁化合物 Mg(OH)2@ 2MgSO4@ 2H2O是该体系的稳定相.     

2MgO·2B2O3·MgCl2·14H2O-MgCl2-H2O体系30℃相平衡

用相平衡方法研究2MgO@2B2O3@MgCl2@14H2O在30℃不同质量分数MgCl2水溶液中的溶解转化产物及其溶解度.结果表明,该复盐在MgCl2的质量分数0～2%浓度范围,发生不同步溶解并转化为多水硼镁石(2MgO@3B2O3@15H2O);在MgCl2的质量分数2%～13.8%浓度范围,转化为柱硼镁石(MgO@B2O3@3H2O),这一结果比文献报导的该硼酸盐的形成温度低了13℃,为盐湖硼酸镁矿物柱硼镁石形成的解释提供了物理化学依据;而在MgCl2质量分数大于13.8%时,同步溶解,不发生转化.提出了溶解相转化反应机理.     

水氯镁石气固反应制备无水氯化镁

用盐湖水氯镁石在氮气保护下135℃脱水2h成低水合水氯镁石。低水合水氯镁石与固体氯化铵按质量比1:6.5混合,高温下使反应体系中NH3的分压达49.6KPa以上,在440℃脱水18分钟和710℃煅烧12分钟成无水氯化镁。分析结果表明:制得的无水氯化镁中氧化镁的质量分数为小于0.15%。X射线衍射和电镜扫描图证明,制得的无水氯化镁无杂相,颗粒大而均匀,分散性好,适合于电解制备金属镁。方法简单,生产成本低,固体氯化铵可以回收循环使用。     

MgSO4·5Mg(OH)2·3H2O的水热合成及反应时间对其形貌的影响

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 are in 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.     

Co(en)3[B4O5(OH)4]Cl·3H2O和[Ni(en)3][B5O6(OH)4]2·2H2O的合成、结构以及热力学性质

利用水热法合成了两种过渡金属配合物为模板剂的含水硼酸盐晶体Co(en)3[B4O5(OH)4]Cl·3H2O(1) 和 [Ni(en)3][B5O6(OH)4]2·2H2O (2),并通过元素分析、X射线单晶衍射、红外光谱及热重分析对其进行了表征。化合物1晶体结构的主要特点是在所有组成Co(en)33+, [B4O5(OH)4]2–, Cl– 和 H2O之间通过O–H…O、O–H…Cl、N–H…Cl和N–H…O四种氢键连接形成网状超分子结构。化合物2晶体结构的特点是[B5O6(OH)4]–阴离子通过O–H…O氢键连接形成沿a方向有较大通道的三维超分子骨架,模板剂[Ni(en)3]2+阳离子和结晶水分子填充在通道中。     

(enH2)5[(VO)12O6B18O36(OH)6]·2(H3O)·6H2O的水热合成和晶体结构

以NH4VO3,H3BO3,乙二胺,MoO3,H2O为原料,按物质的量比2∶20∶9∶3∶222,在180℃条件下晶化,得到黑色棱形晶体(enH2)5[(VO)12O6B18O36(OH)6].2(H3O).6H2O.单晶结构分析结果表明该化合物属三斜晶系,Pī空间群,晶胞参数a=1.336 8(3)nm,b=1.599 8(3)nm,c=1.663 4(3)nm,α=94.040(1)°,β=91.530(1)°,γ=95.830(1)°,V=3.528 1(12)nm3,Z=2,Dc=2.099 g/cm3,μ=1.649 mm-1,F(000)=2 228,15 641个可观察独立衍射点射点(I>2σ(I)),最后结构精修到偏离因子R1=0.047 5,wR2=0.150 4,S=1.039.该化合物的结构主要由阴离子簇[(VO)12O6B18O36(OH)6]12-构成.该阴离子簇由B18O36(OH)6十八元环夹在两个以共边交替相连形成的V6O18簇中间,通过共用氧原子形成三明治式结构新颖的硼-钒-氧离子簇,簇间填充了一些(enH2)2+离子和水分子.     

复盐法制备无水氯化镁的热解机理及动力学研究

The complex compound (MgCl₂·C₆H₅NH₂·HCl·6H2O) was prepared by reaction of C₆H₅NH₂·HCl with MgCl₂·6H₂O. Reaction mechanism and kinetics of the compounds decomposition were studied by means of the TG-DTA-MS coupling technique and the TG-DTA technique. The results show that there are four steps in the complex′s thermal decomposition, the first two steps correspond to the loss of six crystal waters and the last two steps loss one Aniline hydrochloride. The first three steps belong to the R2 mechanism with 2-dimentional phase boundary reaction as the control step, and the last step belongs to the D3 with 3-dimensional diffusion (sphere Jander equ.) as the control step. The apparent active energy of four steps are, 127.4 kJ·mol^-1, 124.8 kJ·mol^-1, 142.3 kJ·mol^-1 and 329.0 kJ·mol^-1, respectively and the frequency factor are 1.28 × 10¹⁸ s^-1, 7.94 × 10¹⁵ s^-1, 5.98 × 10¹⁶ s^-1 and 4.39 × 10³⁴ s^-1, respectively.     

5Mg(OH)2·MgSO4·2H2O晶须生长过程中的形貌研究

Using MgSO₄ and NaOH solutions as starting materials, the whisker of 5Mg(OH)₂·MgSO₄·2H₂O has been prepared by hydrothermal method at 160℃ for different time. The whisker was separated, washed by water, ethanol and ether,and characterized by chemical analysis, XRD, IR and microphotography. The growth time of whisker would affect its morphology.     

有机溶剂法无水氯化镁的制备与表征

Ammonium carnallite was synthesized by hydrated magnesium chloride in salt lake and ammonium chloride solution. Dehydrated ammonium carnallite was dissolved in methanol under low temperature by feeding ammonia, to prepare anhydrous magnesium chloride. The results show that anhydrous magnesium chloride contains magnesium oxide in an amount less than 0.1% by weight, the yield of magnesium chloride was above 99.5%. Ammonium carnallite, ammoniation magnesium chloride and anhydrous magnesium chloride were characterized by thermoanalysis, X-ray powder diffraction and scanning electron microscopy.     

Study of In Situ Formation of Magnesium Hydroxide Whisker via Basic Magnesium Chloride Whisker Regulated by Organic Parcels at Low Temperature

In this work, we demonstrate an in situ phase conversion from basic magnesium chloride（BMC） into magnesium hydroxide whisker by using polar organic solvent at low temperature. The morphology and phase composition of magnesium hydroxide whiskers prepared at different reaction temperature, alkali concentration and organic solvent were analyzed by X-ray diffraction（XRD） and scanning electronic microscope（SEM）. It was found that when one of the organic solvents such as absolute ethyl alcohol, butanol, polyethylene glycol（PEG-400）, acetone, et al. was selected as the template, the precursor BMC can transform into whisker-like magnesium hydroxide through precipitate transformation in low temperature and non-hydrothermal system. It can be reasonably explained that the regulation of Mg^2＋ solubility by those organic solvents and the sustained release of Mg^2＋ dissolution by organic adsorption played a significant role in the formation of magnesium hydroxide whisker via BMC whisker as the precursor.     

一元氯化镁化合物热分解的热力学研究

本文利用Gaussian 03程序,采用量子化学理论,在RHF/6-31G(d)水平上,对一元氯化镁化合物热分解反应机理进行了研究。在对现有4种水氯镁石脱水技术的反应物和产物几何构型进行能量梯度法全优化的同时,计算了不同温度下4种方法的主副反应路径的标准热力学参数(298.15~1000 K)。热力学计算结果表明:所有反应均为吸热反应,当压力为1.01×105 Pa、温度低于1000 K时,所有反应都不能自发进行;从热力学的角度分析,热分解更有利于以苯胺为助剂的复盐法的发生。     

Syntheses and Structures of Na2Mg3(OH)2(SO4)3·4H2O and K2Mg3(OH)2(SO4)3·2H2O

The crystal structures of Na₂Mg₃(OH)₂(SO₄)₃ · 4H₂O and K₂Mg₃(OH)₂(SO₄)₃ · 2H₂O, were determined from conventional laboratory X‐ray powder diffraction data. Synthesis and crystal growth were made by mixing alkali metal sulfate, magnesium sulfate hydrate, and magnesium oxide with small amounts of water followed by heating at 150 °C. The compounds crystallize in space group Cmc2₁ (No. 36) with lattice parameters of a = 19.7351(3), b = 7.2228(2), c = 10.0285(2) Å for the sodium and a = 17.9427(2), b = 7.5184(1), c = 9.7945(1) Å for the potassium sample. The crystal structure consists of a linked MgO₆–SO₄ layered network, where the space between the layers is filled with either potassium (K⁺) or Na⁺‐2H₂O units. The potassium‐bearing structure is isostructural to K₂Co₃(OH)₂(SO₄)₃ · 2(H₂O). The sodium compound has a similar crystal structure, where the bigger potassium ion is replaced by sodium ions and twice as many water molecules. Geometry optimization of the hydrogen positions were made with an empirical energy code.     

探究镁与氯化钠溶液反应的微观过程*

镁在常温下和水发生反应的速率较慢,这是因为镁表面存在氢氧化镁附着层的保护作用,但是镁可以和NaCl溶液发生较快的反应,在产生大量气泡的同时生成白色固体。通过对白色固体进行分析发现,在有Cl^-的环境下氢氧化镁会逐渐转化为碱式氯化镁,同时也会导致溶液pH的升高。经过实验探究发现,镁在不同浓度NaCl溶液中的反应现象存在差异,在反应过程中溶解氧含量也会下降。