癸二醇和十二烷二醇及其混合物的液固相变研究

使用差示扫描量热法（DSC）和红外光谱法（IR）对1,10-癸二醇（1,10-C10H22O2,A）与1,12-十二烷二醇（1,12-C12H26O2,B）及其二元混合物系统液固相变进行研究。测定了该二元混合系统的相变温度、相变焓和液固平衡相图。该二元系统存在低共熔混合物,其组成为xB=0．333,低共熔温度为328K。该二元混合系统的IR图谱显示存在氢键缔合现象,长链烷烃中的亚甲基在晶格中是有序规则排列的。该系统具有较低的相变温度和较高的相变焓,是一种潜在的低温储能材料。     

四元体系LiNO3-Mg(NO3)2-NH4NO3-H2O相图预测及相关相变储能材料的研究

应用修正的BET热力学模型对Mg(NO3)2-NH4NO3-H2O三元体系和LiNO3-Mg(NO3)2-NH4NO3-H2O四元体系在273～320 K的相图进行预测,并找到一个相变温度较低的四元共晶点Mg(NO3)2.6H2O-LiNO3.3H2O-NH4NO3,其质量百分数组成为:25.5%的硝酸铵,28.4%的硝酸锂,13.8%的硝酸镁和32.3%的水,通过实验对共晶点组成材料的吸放热行为进行测定,发现其熔化温度为286.3 K,且DSC测试其相变热焓为192.7 J.g-1,表明该材料可用作潜在的低温相变储能材料。     

“二组分简单共熔体系相图测量”实验的绿色化探索

基于绿色化学理念,探索选用无毒、低熔点的“正十八醇-月桂酸”近室温有机共熔体系,通过测量步冷曲线,获取不同配比条件下体系的固液相变温度,从而绘制相图;再用差示扫描量热法对固液相变温度加以验证,显示2种方法测得的固液相变温度相互吻合,表明该二元共熔体系用于固液相图绘制实验的可行性。由于高级脂肪酸-脂肪醇体系固液相变的潜热较大,该类体系展现出有望作为潜热储能材料的应用前景。因此,该二元有机共熔体系相图测量实验,可在对实验体系进行绿色化探索的基础上,帮助学生认识相变材料和潜热储能技术。     

EuI2—LiI和EuI2—NaI二元体系相图

用ＤＴＡ和Ｘ射线粉末衍射法研究了ＥｕＩ２－ＮａＩ和ＥｕＩ２－ＬｉＩ两个二元体系低压相图。ＥｕＩ２－ＮａＩ二元体系相图为一简单低共熔相图，低共熔点为４０９℃，其低共熔摩尔组成为３２％ＮａＩ；ＥｕＩ２－ＬｉＩ体系相图也为一简单低共熔相图。低共熔点为３８５℃，低共熔摩尔组成为６８．５％ＬｉＩ。     

相变储热材料C10CoCl/C18CoCl二元体系相图

合成了具有层状钙钛矿结构的固-固相变材料四氯合钴酸癸铵(n-C10H21NH3)2CoCl4和四氯合钴酸十八铵(n-C188H37NH3)2CoCl4,并制得一系列C10CoCl/C18CoCl二元体系.利用差示扫描量热(DSC)技术测定其相变温度,并在此基础上绘制了C10CoCl/C18CoCl二元体系相图.在实验相图中确定了新的稳定化合物(n-C10H21NH3)(n-C18H37NH3)CoCl4的存在和2个不变的共晶点,共晶点温度分别为70和73℃.     

乙腈-水的液液、固液相平衡和过量Gibbs自由能

测制了xCH~3CN+(1-x)H~2O的液液、固液平衡相图, 此系液液分层的简单低共熔混合物类相图。低共熔点温度为227.44K, 组成x=0.955。最高临界溶解温度为271.0K, 临界组成x=0.35, 临界指数n=2.64。两液相与冰的平衡温度为263.07K。计算出体系在263.07K的过量Gibbs自由能G~m^E, 液液分层时G~m^E的最大值为1174J·mol^-^1。     

CeCl3—SrCl2—CaCl2三元体系液相限的研究

作为系列研究含稀土氯化物的三元相图工作之一,本文测定了CeCl_2-SrCl_2-CaCl_2三元体系的液相限。该相图未见文献报道。相关的三个二元体系相图,文献已有报道。CeCl_2-SrCl_2与CeCl_3-CaCl_2属二元简单低共熔体系。前者低共熔点为67.3wt-％CeCl_3(640℃);后者低共熔点的组成为57.0wt-％ CeCl_3(622℃)。SrCl_2-CaCl_2二元体系相图属带有最低点的连续固溶     

四氯合锌酸十四烷铵-四氯合锌酸十六烷铵二元体系相图

合成了四氯合锌酸十四烷铵(C4H29NH3)2ZnCl4(简记为C14ZnCl)和四氯合锌酸十六烷铵(C16H33NH3)2ZnCl4(简记为C16ZnC1),并配制了一系列不同组成的C14ZnCl-C16ZnCl二元体系,通过DSC测试,变温红外光谱法及X-ray粉末衍射法来绘制该二元体系相图。该相图是生成稳定中问化合物的固相部分互溶体系相图。     

相变贮热材料四氯合钴酸铵共析物的制备和热性能

在温度353 K的乙醇溶液中, 采用热回流法合成了热致相变化合物四氯合钴酸铵(1-C_nH_2n+1NH₃)₂CoCl₄(n=10, 18)(分别简写为C₁₀Co、C₁₈Co)及其二元混合物. 利用差示扫描量热和X射线法对二元体系进行了表征.根据测定实验数据构筑二元相图, 所得相图结果表明, 在w_C10Co=52.51% (质量分数)处存在中间化合物(1-C₁₀H₂₁NH₃)(1-C₁₈H₃₇NH₃)CoCl₄. 相图还包括两个三相线, 相对应的两个共析温度分别为(347±1)和(343±1) K, 共析点分别在w_C10Co=38.50%和w_C10Co=69.86%处. 并且, 在相图的左右边界存在端际固溶体(α、β)及中间区域存在非化学计量相(γ). 四氯合钴酸铵及其二元混合体系作为相变材料贮热时, 相变温度范围为340-370 K, 相变焓大小范围在2.13到141.12 J·g^-1之间.     

NdCl3-LiCl及NdCl3-LiCl-NaCl体系相图的研究

利用DTA和X射线结构分析研究了NdCl3-LiCl二元体系相图和NdCl3-LiCl-NaCl三元体系液相限. 发现NdCl3-LiCl体系相图属于简单低共熔型, 低共熔点e3为28.5(wt%)LiCl, 452℃. 在低共熔温度以下有一固相下生成的介稳化合物, 在443℃分解, 组成为2NdCl3.LiCl. 经长时间退火, 该化合物消失. NdCl3-LiCl-NaCl体系有对应NdCl3、LiCl、NaCl、2NaCl.LiCl、NaCl.LiCl的五个液相面, 七条两次结晶线, 一个三元低共熔点E[69.0(wt%)NdCl3, 13.5(wt%)NaCl, 374℃], 两个三元转熔点P1[69.5(wt%)NdCl3, 14.5(wt%)NaCl, 380℃], P2[70.0(wt%)NdCl3,15.5(wt%)NaCl, 385℃].     

Conductivity, calorimetry and phase diagram of the NaHSO4–KHSO4 system

Physico-chemical properties of the binary system NaHSO₄–KHSO₄ were studied by calorimetry and conductivity. The enthalpy of mixing has been measured at 505 K in the full composition range and the phase diagram calculated. The phase diagram has also been constructed from phase transition temperatures obtained by conductivity for 10 different compositions and by differential thermal analysis. The phase diagram is of the simple eutectic type, where the eutectic is found to have the composition X(KHSO₄) = 0.44 (melting point ≈ 406 K). The conductivities in the liquid region have been fitted to polynomials of the form κ(X) = A(X) + B(X)(T − T_m) + C(X)(T − T_m)², where T_m is the intermediate temperature of the measured temperature range and X, the mole fraction of KHSO₄. The possible role of this binary system as a catalyst solvent is also discussed.     

Relationship between properties of fluorinated graphite intercalates and matrix composition Part III. Intercalates with 1,2-dichloroethane

A series of PA-TD mixtures were prepared and their thermal properties were studied by DSC and thermal conductivity measurement. The phase diagram of the binary system was constructed, which showed an eutectic behavior for the solid-liquid equilibrium line. The eutectic composition of the binary system was at the mass fraction of TD near 0.7 with an eutectic temperature of about 29°C. At TD side, PA was partially miscible in the TD solid matrix and the solid phase transition of TD had an effect on the solidus line. The eutectic composition mixture could be viewed as a new phase change material with large thermal energy storage capacity.     

Study of the NaBr–DyBr3 phase diagram by differential thermal analysis

The phase diagram of the quasi binary NaBr–DyBr₃ system was determined by differential thermal analysis (DTA) applied to 27 samples covering the complete composition range of the system. The 3NaBr*DyBr₃(s) compound is present in the solid-phase in addition to the pure component halides NaBr(s) and DyBr₃(s). The DyBr₃(s) and 3NaBr*DyBr₃(s) phases showed a polymorphic transition at 1112 and at 733 K, respectively. The {DyBr₃(s) + 3NaBr*DyBr₃(s)} eutectic mixture melts at 709 K giving a liquid of the molar composition x(NaBr) = 0.62. The 3NaBr*DyBr₃(s) phase melts peritectically at 765 K. The phase diagram obtained in the present study virtually agrees with the calculated one available in literature.     

Characterization of the crystallization behavior of the eutectic-forming binary system polyoxyethylene and glutaric acid. I. melting and crystallization behavior

The crystallization characteristics of the binary system polyoxyethylene (PEO)-glutaric acid were determined. From the extrapolated melting point depression data the heat of fusion for PEO is 2506 ± 200 cal/mole of repeat unit while the heat of solution for the glutaric acid amounts to 6.7 ± 1.2 cal/cm³. A melting point of 348 K is found for the high-molecular-weight PEO. A calorimetric glass-transition temperature for mixtures of the two components is relatively independent of the melt composition and appears at 217 K. A eutectic is observed whose composition and melting temperature depend on the nature of the PEO crystal phase.     

Determination of High Pressure Phase Diagrams of the Ternary Alloy System

ＤｅｔｅｒｍｉｎａｔｉｏｎｏｆＨｉｇｈＰｒｅｓｓｕｒｅＰｈａｓｅＤｉａｇｒａｍｓｏｆｔｈｅＴｅｒｎａｒｙＡｌｌｏｙＳｙｓｔｅｍＳＯＮＧＬｉ－ｚｈｕ；ＹＡＮＧＨｕａａｎｄＺＨＡＯＭｕ－ｙｕ（ＤｅｐａｒｔｍｅｎｔｏｆＣｈｅｍｉｓｔｒｙ，ＪｉｌｉｎＵｎｉｖ...     

Phase diagram study of CaBr2–CaHBr system

A study of binary, CaBr₂–CaHBr system was carried out by differential thermal analysis (DTA), covering the composition range from 100 % CaBr₂ to 100 % CaHBr between room temperature and 800 °C. From DTA results, the contour of solidus and liquidus temperatures with composition is plotted and the phase diagram of CaBr₂–CaHBr system is constructed. The system shows an eutectic reaction at 576 °C and the eutectic composition is 79.6 mol% CaBr₂. Co-existing phases in different phase fields are characterized by X-ray diffraction analysis.     

Crystallization Behavior of the System Poly(L-lactic Acid) and Pentaerythrityl Tetrabromide

Differential scanning calorimetry has been used to study the thermal crystallization of poly(L-lactic acid) (PLLA) and pentaerythrityl tetrabromide mixtures at different compositions. The melting temperature-composition phase diagram of the system reveals that PLLA forms a simple eutectic with pentaerythrityl tetrabromide, with a eutectic composition of 46% (w/w) of PLLA and a eutectic temperature of 422 K. Investigation of the microstructures obtained after removal of the diluent from the eutectic using scanning electron microscopy shows that the simultaneous crystallization of PLLA and the diluent proceeded in such a way that the diluent rods are the leading phases.     

Thermal investigation of PEG 4000 — oxazepam binary system

A thermal study using DSC and Hot Stage Microscopy (HSM) was carried out to investigate the interaction in solid state of the binary system PEG 4000 — oxazepam, and to establish their phase diagram. The eutectic composition, which melting occurs at lower temperature as compared with the pure components, has been determined. The results obtained by DSC and HSM have indicated that PEG 4000 — oxazepam mixtures displays no obvious incompatibilities, and that the system shows a typical eutectic behaviour. However because of the closeness of the melting of PEG 4000 to the eutectic temperature, it was difficult to determine precisely the eutectic composition and temperature on the basis of DSC measurements alone. The use of heats of fusion corresponding to physical mixtures allowed an estimation of the eutectic composition at 6% w/w oxazepam. Additional information of temperature (57.6C) and composition (5–10% w/w oxazepam) of the eutectic was obtained by HSM using the contact method. This low melting temperature in this range of compositions offers advantages in terms of drug stability and easy manufacture.     

Thermal and conductometric studies of NdBr3 and NdBr3-LiBr binary system

The heat capacity of solid NdBr₃ was measured by Differential Scanning Calorimetry in the temperature range from 300 K up to the melting temperature. The heat capacity of liquid NdBr₃ was also determined. These results were least-squares fitted to a temperature polynome. The melting enthalpy of NdBr₃ was measured separately. DSC was used also to study phase equilibrium in the NdBr₃-LiBr system. The results obtained provided a basis for constructing the phase diagram of the system under investigation. It represents a typical example of simple eutectic system. The eutectic composition, x(NdBr₃)=0.278, was obtained from the Tamman construction. This eutectic mixture melts at 678 K. The electrical conductivity of NdBr₃-LiBr liquid mixtures and of pure components was measured down to temperatures below solidification. Reflectance spectra of the pure components and their solid mixtures (after homogenisation in the liquid state) with different composition were recorded in order to confirm the reliability of the constructed phase diagram. This revised version was published online in July 2006 with corrections to the Cover Date.