N,N-二甲基甲酰胺中铀(V)吸收光谱的研究

以中压汞灯为光源，采用吸收光谱法，观察了UO2（NO3）2•6H2O在DMF（N，N－二甲基甲酰胺）溶剂中光化还原时的吸收光谱随照射时间、铀浓度及溶液酸度的变化．经短时间光照后，在UO2（NO3）2－DMF溶液中有铀（Ⅴ）形成，其吸收峰在755和635nm处．结果表明，它们分别是UO2+－DMF和UOOH2＋－DMF的特征吸收，溶液中铀（Ⅴ）的岐化反应与H＋浓度密切相关，UOOH2＋是岐化反应的中间体．     

低品位盐矿中K+、Na 的溶解动力学研究

为了更好地研究马海盐矿中K+、Na+溶解性能和溶解规律,根据本课题组之前正交试验结果分别选取质量分数为13.24%(即饱和度为50%)的Na Cl溶液和Na Cl+Mg Cl2混合溶液(Na Cl、Mg Cl2质量分数分别为13.24%、3%)为溶剂进行试验,并与水作比较,从而得出其在不同溶剂中的溶解动力学方程。根据测得数据绘制离子c-t图,进行非线性拟合后得到溶解动力学曲线;再用龙格-库塔微分方程组和单纯形优化法拟合求解Stumm模型中的K、n两个参数,程序由matlab编写,最终确定离子的溶解动力学方程并得出不同溶剂中K+、Na+的溶解规律:溶剂中加入Na Cl时,矿液中K+的溶解速率明显增大,且矿液中Na+的溶解速率大幅度减小;再引入Mg2+,K+的溶解速率明显增大,溶解速率常数K由0.1126增大到0.8749,且矿液中Na+的溶解速率常数K也保持在10-10级水平。     

粗硼砂的氯化铵溶液浸提动力学

研究了反应温度、溶液浓度、固液比、固体粒径大小和搅拌速度对氯化铵溶液浸提粗硼砂(十水四硼酸钠,Na₂B₄O₇·10H₂O)动力学的影响。结果表明反应速率随反应温度、溶液浓度的增加和固体粒径、固液比的减小而增加,但搅拌速度对溶解速率无显著影响。根据均相和多相动反应力学模型研究了粗硼砂的溶解过程。结果表明溶解速率遵从假一级均相反应模型。粗硼砂在氯化铵溶液中溶解的活化能为82.73 kJ·mol^-1。     

乙二胺硅胶复合材料对Zn2+的吸附特性

以γ-氯丙基三氯硅烷为偶联剂,将乙二胺偶合接枝在硅胶表面,合成对锌离子具有吸附作用的乙二胺硅胶复合材料（EDA/SiO2）,考察了Zn2+溶液pH值、初始浓度、吸附温度和吸附时间等因素对复合材料吸附性能的影响。 结果表明,在研究的溶液浓度及温度范围内,Zn2+溶液pH值对EDA/SiO2的吸附量影响显著,吸附的最佳pH值范围在3.0~5.5;Zn2+的吸附平衡数据符合Langmuir吸附模型,热力学数据显示,EDA/SiO2对Zn2+的吸附行为为一吸热且自发进行的过程,升高温度有利于吸附,并对此吸附行为作了解释;吸附动力学数据可用拟二级吸附动力学方程描述,得到的吸附速率常数与溶液初始浓度有关。     

N,N-二甲基甲酰胺中铀(Ⅴ)吸收光谱的研究

以中压汞灯为光源，采用吸收光谱法，观察了UO2（NO3）2·6H2O在DMF（N，N－二甲基甲酰胺）溶剂中光化还原时的吸收光谱随照射时间、铀浓度及溶液酸度的变化，经短时间光照后，在UO2（NO3）2－DMF溶液中有铀（Ⅴ）形成，其吸收峰在755和635nm处，结果表明，它们分别是UO－DMF和UOOH2＋－DMF的特征吸收，溶液中铀（Ⅴ）的岐化反应与H＋浓度密切相关，UOOH2＋是岐化反应的中间体。     

N-对位取代苯基马来酰亚胺与苯乙烯溶液共聚动力学的研究

以DMF为溶剂 ,采用膨胀计法对N 对位取代苯基马来酰亚胺与苯乙烯的溶液共聚动力学作了系统研究 .其中N 苯基马来酰亚胺与苯乙烯的均相溶液聚合 ,聚合速率方程为Rp=k[I]1/ 2 [M ].同时还测定了四种N 对位取代苯基马来酰亚胺与苯乙烯在DMF中的共聚表观活化能 ,并由此证明四种单体的共聚活性及CTC络合物的存在     

柠檬酸溶解废锂离子电池正极材料的研究

探求废锂离子电池正极材料LiMn2O4在柠檬酸溶液中的溶解条件,为废旧电池的进一步回收利用奠定基础。采用单因素与正交实验相结合的方法,对废锂离子电池正极材料LiMn2O4在柠檬酸溶液中的溶解条件进行研究,结果表明,废锂离子电池正极材料LiMn2O4在柠檬酸溶液中适宜的溶解条件为:柠檬酸浓度1.0mol.L-1、溶解温度45℃、H2O2加入量5.0%、料液比60g.L-1,在此条件下正极材料LiMn2O4在柠檬酸溶液中的溶解率达到99.56%。对柠檬酸溶解废锂离子电池正极材料LiMn2O4的机理进行了探讨,认为在加入H2O2之前,尖晶石LiMn2O4中的Mn3+发生歧化反应生成Mn2+以及MnO2,而Mn4+在溶液中水解生成MnO2。MnO2与柠檬酸发生氧化还原反应生成丙酮二羧酸及Mn2+。加入H2O2之后,H2O2作为还原剂能够将剩余的MnO2全部还原为Mn2+,使正极材料LiMn2O4在柠檬酸溶液中的溶解率得以提高。     

原生纤维素静电纺丝的调控

通过电纺非溶剂调控的纤维素溶液, 制备出纤维素电纺纤维. 在N,N-二甲基乙酰胺(DMAc)-氯化锂(LiCl)溶解纤维素体系中, 以DMAc和N,N-二甲基甲酰胺(DMF)作为非溶剂, 添加到高浓度的纤维素溶液中制备电纺溶液. 考察添加非溶剂对纤维素溶液性质和电纺纤维形貌的影响. 结果表明, 添加非溶剂有助于提升纤维素溶液的可纺浓度, 获得分散性较好的电纺纤维, 其中DMF效果最好. 添加非溶剂降低了纤维素溶液的黏度, 使纤维素溶液可纺浓度提高; 添加非溶剂改变了电纺溶液的稳定性, 获得了分散良好的纳米纤维, 从而有助于纤维素射流在电纺过程中快速固化成型.     

动态光散射对良溶剂中酚醛型聚醚砜的研究

用动态光散射方法研究了酚酞型聚醚砜(PES-C)在良溶剂DMF中的稀溶液性质。在稀溶液中,PES-C分子由于内旋转发生链折叠,整体上表现出柔性链的性质,较好的符合球形模型;而分子链的局部刚性结构又使分子尺寸稳定;它的扩散行为随温度的变化符合Arrehnius方程。表征了PES-C分子在稀溶液中的形态结构,且给出了PES-C分子在DMF中的扩散系数、扩散活化能、无限稀时的扩散系数和流体力学半径等重要特征参数。     

原生纤维素静电纺丝的调控（英文）

通过电纺非溶剂调控的纤维素溶液,制备出纤维素电纺纤维.在N,N-二甲基乙酰胺(DMAc)-氯化锂(Li Cl)溶解纤维素体系中,以DMAc和N,N-二甲基甲酰胺(DMF)作为非溶剂,添加到高浓度的纤维素溶液中制备电纺溶液.考察添加非溶剂对纤维素溶液性质和电纺纤维形貌的影响.结果表明,添加非溶剂有助于提升纤维素溶液的可纺浓度,获得分散性较好的电纺纤维,其中DMF效果最好.添加非溶剂降低了纤维素溶液的黏度,使纤维素溶液可纺浓度提高;添加非溶剂改变了电纺溶液的稳定性,获得了分散良好的纳米纤维,从而有助于纤维素射流在电纺过程中快速固化成型.     

Dynamic dissolution of persimmon leaves in DMSO and DMAc and the influence of acid-base interactions

Applying conductivity as a measure, dynamic behavior for dissolution of persimmon leaves in two organic solvents, e.g. DMSO and DMAc, respectively, were recorded and a mathematical model described as: dC/dt = k0 + k1C + k2C2 was deduced (of which, C is the concentration dissolved, k0, k1 and k2 are the different dissolution rate constants corresponding different dissolution stages and t is the time). Results showed that the DMAc seems to be better than that of DMSO due probably to the former having a higher activation energy and smaller acid/base ratio and polarity comparing to the latter. However, for a lower temperature, it seems to be contrary due to DMSO presented greater dissolution rate constant than that of DMAc.     

醇/水混合溶剂中碱性聚合物电解质独特的溶解行为

Self-aggregated quaternary ammonium polysulfone (aQAPS) is a high-performance alkaline polymer electrolyte that has been applied in alkaline polymer electrolyte fuel cells (APEFCs). For a long time, N, N-dimethyl formamide (DMF) has been considered the best solvent to dissolve aQAPS, but the high boiling point of DMF makes it hard to remove from the electrodes, which potentially poisons the electrocatalysts. Our recent experiments have shown that although aQAPS is unable to dissolve in ethanol, n-propanol, or water, it can dissolve in the mixture of these alcohols and water. This peculiar dissolution behavior significantly facilitates the fabrication of the membrane electrode assembly (MEA) for APEFCs, even though it has not been understood. In this work, atomistic molecular dynamics (MD) simulations were employed to study the dissolution behavior of aQAPS in different solvents, including water, methanol, ethanol, n-propanol, DMF, and the mixture of these non-aqueous solvents and water. The conformation of the aQAPS chain in pure solvents agreed well with the dissolution behavior observed in the experiments, even though in the water-containing mixed solvents, the aQAPS chain tended to be in a more contracted state. The simulations further revealed that the water component in the mixed solvents played dual roles. On one hand, the hydrocarbon chain of aQAPS was compressed to a contracted state upon the addition of water, because of the hydrophobic effect. On the other hand, water can drive the dissociation of the counterion (Cl^{–­ ­ ­} ), which led to an enhancement in the solute-solvent interaction energy and thus facilitated the dissolution of aQAPS. In most mixed solvents, the compensation of these two interactions resulted in a general increase in the total solute-solvent interaction energy; therefore, the addition of water was energetically favorable for the dissolution of aQAPS. This study not only furthers our fundamental understanding of the dissolution behavior of polyelectrolytes but also is technologically significant for the development of better APEFCs.     

Thermo-Reversible Cellulose Micro Phase-Separation in Mixtures of Methyltributylphosphonium Acetate and γ-Valerolactone or DMSO

We have identified cellulose solvents, comprised of binary mixtures of molecular solvents and ionic liquids that rapidly dissolve cellulose to high concentration and show upper-critical solution temperature (UCST)-like thermodynamic behaviour - upon cooling and micro phase-separation to roughly spherical microparticle particle-gel mixtures. This is a result of an entropy-dominant process, controllable by changing temperature, with an overall exothermic regeneration step. However, the initial dissolution of cellulose in this system, from the majority cellulose I allomorph upon increasing temperature, is also exothermic. The mixtures essentially act as ‘thermo-switchable’ gels. Upon initial dissolution and cooling, micro-scaled spherical particles are formed, the formation onset and size of which are dependent on the presence of traces of water. Wide-angle X-ray scattering (WAXS) and ¹³C cross-polarisation magic-angle spinning (CP-MAS) NMR spectroscopy have identified that the cellulose micro phase-separates with no remaining cellulose I allomorph and eventually forms a proportion of the cellulose II allomorph after water washing and drying. The rheological properties of these solutions demonstrate the possibility of a new type of cellulose processing, whereby morphology can be influenced by changing temperature.     

Immobilised tyrosinase-based biosensor for the detection of tea polyphenols

An amperometric principle-based biosensor containing immobilized enzyme tyrosinase has been used for detection of polyphenols in tea. The immobilized tyrosinase-based biosensor could detect tea polyphenols in the concentration range 10–80 mmol L⁻¹. Immobilization of the enzyme by the crosslinking method gave good stable response to tea polyphenols. The biosensor response reached the steady state within 5 min. The voltage response was found to have a direct linear relationship with the concentration of polyphenols in black tea samples. Enzyme membrane fouling was observed with number of analyses with a single immobilised enzyme membrane. The tyrosinase-based biosensor gave maximum response to tea polyphenols at 30°C. The optimum pH was 7.0. This biosensor system can be applied for analysis of tea polyphenols. Variation in the biosensor response to black tea infusions gave an indication of the different amounts of theaflavins in the samples, which is an important parameter in evaluating tea quality. A comparative study of the quality attributes of a variety of commercially available brands of tea were performed using the biosensor and conventional analytical techniques such as spectrophotometry.     

Recombination of the hydrated electron at high temperature and pressure in hydrogenated alkaline water

Pulse radiolysis experiments were performed on hydrogenated, alkaline water at high temperatures and pressures to obtain rate constants for the reaction of hydrated electrons with hydrogen atoms (H* + e-(aq) --> H(2) + OH-, reaction 1) and the bimolecular reaction of two hydrated electrons (e-(aq) + e-(aq) --> H(2) + 2 OH-, reaction 2). Values for the reaction 1 rate constant, k(1), were obtained from 100 - 325 degrees C, and those for the reaction 2 rate constant, k(2), were obtained from 100 - 250 degrees C, both in increments of 25 degrees C. Both k(1) and k(2) show non-Arrhenius behavior over the entire temperature range studied. k(1) shows a rapid increase with increasing temperature, where k(1) = 9.3 x 10(10) M(-1) s(-1) at 100 degrees C and 1.2 x 10(12) M(-1) s(-1) at 325 degrees C. This behavior is interpreted in terms of a long-range electron-transfer model, and we conclude that e-aq diffusion has a very high activation energy above 150 degrees C. The behavior of k(2) is similar to that previously reported, reaching a maximum value of 5.9 x 10(10) M(-1) s(-1) at 150 degrees C in the presence of 1.5 x 10(-3) m hydroxide. At higher temperatures, the value of k(2) decreases rapidly and above 250 degrees C is too small to measure reliably. We suggest that reaction 2 is a two-step reaction, where the first step is a proton transfer stimulated by the proximity of two hydrated electrons, followed immediately by reaction 1.     

A DFT-based study of the hydrogen-bonding interactions between epicatechin and methanol/water

Tea polyphenols are essential components that give tea its medicinal properties. Methanol and water are frequently used as solvents in the extraction of polyphenols. Hydrogen-bonding interactions are significant in the extraction reaction. Density functional theory (DFT) techniques were used to conduct a theoretical investigation on the hydrogen-bonding interactions between methanol or water and epicatechin, an abundant polyphenol found in tea. After first analyzing the epicatechin monomer's molecular geometry and charge characteristics, nine stable epicatechin (EC) H₂O/CH₂OH complex geometries were discovered. The presence of hydrogen bonding in these improved structures has been proven. The calculated hydrogen bond structures are very stable, among which the hydrogen bond bonded with a hydroxyl group has higher stability. The nine complex structures’ hydrogen bonds were thought to represent closed-shell-type interactions. The interaction energy with 30O-31H on the epicatechin benzene ring is the strongest in the hydrogen bond structure. While the other hydrogen bonds were weak in strength and mostly had an electrostatic nature, the hydrogen bonds between the oxygen atoms in H₂O or CH₂OH and the hydrogen atoms of the hydroxyl groups in epicatechin were of moderate strength and had a covalent character. Comparing the changes in the hydrogen bond structure vibration peak, the main change in concentration peak is the hydrogen bond vibration peak in the complex. Improved the study on the hydrogen bond properties of CH₂OH and H₂O of EC.     

Solution behavior of metal sulfonate ionomers. II. Effects of solvents

Previous studies on the dilute-solution behavior of sulfonated ionomers have shown these polymers to exhibit unusual viscosity behavior in mixed solvents of low polarity. These results have been interpreted as arising from specific solvation effects by the solvents with the metal sulfonate groups which persist as ion pairs. The consequences of ion pair interactions and their solvation are exceptional thickening behavior at low polymer levels as compared to unfunctionalized polymers, and anomolous solution viscosities with varying temperature. These studies have now been extended to single-component solvents which traverse a range of polarities. Using the sodium salt of lightly sulfonated polystyrene (S-PS) as a model system, the authors found the solution behavior in low-polarity solvents (tetrahydrofuran) to be consistent with that observed previously for mixed solvents; ion pair interactions predominated. However, in polar solvents such as dimethyl sulfoxide or dimethyl formamide, these polymers behave as classic polyelectrolytes even at sulfonate levels below 2 mol %. The behavior of the S-PS acids is similar to that observed for the metal salts. To a first approximation these two behaviors, ion pair association and polyelectrolyte behavior, are dependent on solvent polarity. In some cases it is possible to induce polyelectrolyte behavior in a S-PS/solvent combination exhibiting ion pair interactions by the addition of very low levels of a polar cosolvent, such as water. These results again demonstrate the selectivity of the solvent-sulfonate interactions.     

焙烧硼钠钙石在高固液比氯化铵溶液中的溶解动力学

Boron is available in the form of metal borates, especially of sodium and calcium, in nature[1]. The production of boron compounds has substantially increased recently due to increasing uses of these compounds in nuclear technology, in rocket engines as f…     

Dissolution kinetics of granular calcium carbonate in concentrated aqueous sodium dichromate solution at pH 6.0-7.0 and 110-130 degrees C

An understanding of the factors controlling calcite dissolution is important for modeling geochemical cycles and impacts of greenhouse gases on climate, diagenesis of sediments, and sedimentary rocks. It also has practical significance in the investigation of behavior of carbonates in petroleum and natural gas reservoirs and in the preservation of buildings and monuments constructed from limestone and marble. A large number of papers have been published on dissolution kinetics of calcium carbonate in aqueous solutions. But few involved the near-equilibrium region, especially at elevated temperatures and in concentrated solutions. In this paper, the dissolution kinetics of calcium carbonate in concentrated aqueous sodium dichromate solutions at pH 6.0-7.0 and 110-130 degrees C were studied in a 2-L autoclave. The results indicate that the dissolution reaction is mix-controlled, with surface reaction as the prevailing factor. The concentration of calcium ions in solution hardly affects the dissolution rate, but carbon dioxide in the vapor phase inhibits the dissolution reaction. The dissolution rate can be expressed by R = k(1)a(2)(H+) + k(2), and the apparent activation energy is 55-84 kJ mol(-1).     

Ultrasound-assisted extraction, HPLC analysis, and antioxidant activity of polyphenols from unripe apple

The polyphenols were extracted from the unripe apple assisted by a highly efficient and simple method of the ultrasound. Response surface methodology was used to investigate the effects of processing parameters, including ultrasound power, extraction time, temperature, and ethanol concentration on total polyphenols yield and polyphenols composition was analyzed by HPLC. Antioxidant activity of the polyphenols was evaluated as 2, 2-diphenyl-1-picrylhydracyl scavenging activity and inhibition activity of lipid peroxidation. The results showed that 10-100 times higher total polyphenols yield was obtained from the unripe apple than those from the reported apple pomace. The optimum extraction conditions were ultrasonic power of 519.39 W, extraction time of 30 min, extraction temperature 50°C, ethanol concentration of 50% gave the total polyphenols yield of 13.26 ± 0.56 mg GAE/g. HPLC analysis indicated that (-)-epicatechin, procyanidin B2, chlorogenic acid, and procyanidin B1 were the predominant polyphenols in unripe apple, which contributed to the higher antioxidant activity to 2, 2-diphenyl-1-picrylhydracyl of unripe apple polyphenols than other apple polyphenols. The extracted polyphenols had higher ability to inhibit lipid peroxidation than butylated hydroxy toluene, which demonstrated that the unripe apple polyphenols have the potential to be used as a substitute of some synthetic antioxidants.