超短激光蚀除金属机制的分子动力学研究

 采用耦合电子热传导方程的分子动力学方法,研究了飞秒激光辐照下金属Ni的熔化及蚀除动力学。分析了靶材内部温度分布特征及蚀除产物的构成,主要包含单个原子及大团簇。确定了断裂位置和蚀除开始的标志,即该处温度分布出现小的峰值,且粒子数密度急剧下降。模拟结果表明：强烈的蒸发及靶材内部所产生的拉应力分别是单个原子及大团簇喷射的机制。同时,深入探讨了激光诱导压力波的传播规律,预测了压力波的波速,约为4.97 km/s。将不同脉冲能量密度下的蚀除速率同实验数据加以对比,结果相差16%~20%。预测了熔深随时间的变化规律,基本随时间的延续而呈上升的趋势。发现过热现象的存在。     

升温速率对金属铅的熔化和过热行为的影响

采用分子动力学方法和QSC(quantum Sutton-Chen)力场研究了升温速率对金属铅的熔化和过热行为的影响.模拟中考虑了缺陷和表面对熔化和过热行为的作用.结果表明，升温速率对金属铅的熔化和过热行为影响很大，随着升温速率的升高，金属铅的熔点有所升高.快的升温速率会导致金属铅体系内部无序化程度增加，进而使体系能量增加，降低了熔化相变的能垒.升温速率导致的金属铅的过热极限大约为780 K.     

微波辐射下L-氨基酸的快速消旋方法

微波辐射作用下的L-氨基酸消旋反应是一种新的氨基酸消旋方法，具有对环境友好的优点。本文报道了在微波辐射下，以1．Omol／L氢氧化钠水溶液替代有机酸作为反应溶剂，水杨醛为催化剂，水杨醛与L-氨基酸的摩尔比为0．1，L-氨基酸可以快速消旋；消旋反应随微波辐射功率的提高而加快，在600W时已接近最大反应速率。同时也讨论了微波作用下L-氨基酸的消旋反应机理。     

Synthesis of industrial scale NaY zeolite membranes and ethanol permeating performance in pervaporation and vapor permeation up to 130 °C and 570 kPa

NaY zeolite tubular membranes in an industrial scale of 80 cm long were synthesized on monolayer and asymmetric porous supports. The quality of synthesized membranes were evaluated by pervaporation (PV) experiments in 80 cm long at 75 °C in a mixture of water (10 wt.%)/ethanol (90 wt.%), resulting in higher permeation fluxes of 5.1 kg m⁻² h⁻¹ in the monolayer type membrane and of 9.1–10.1 kg m⁻² h⁻¹ in the asymmetric-type membranes, respectively. The uniformity with small performance fluctuation in longitudinal direction of the membranes were observed by PV for 10–12 cm long samples at 50 °C in a mixture of methanol (10 wt.%)/MTBE (90 wt.%). The ethanol single component permeation experiments in PV and vapor permeation (VP) up to 130 °C and 570 kPa were performed to determine the relations between the ethanol flux and the ethanol pressure difference across the membrane which is represented by permeance (Π, mol m⁻² s⁻¹ Pa⁻¹) for estimate of potential of ethanol extraction through the present NaY zeolite membranes applying feasible studies. Results indicate that (1) the permeation fluxes are linearly proportional to the driving force of vapor pressure for each sample in VP and PV. The permeances through an asymmetric support type membrane were rather constant of 0.6–1.2 × 10⁻⁷ mol m⁻² s⁻¹ Pa⁻¹ in the wide temperature range of 90–130 °C in PV and VP, indicating that the ethanol permeances have weak temperature dependency with the feed at the saturated vapor pressure.

The results of superheating VP experiments showed that ethanol permeation fluxes are increased with increasing of the degree of superheating at a given constant feed vapor pressure. The ethanol permeances are increased with increasing of temperature at a given feed vapor pressure. The superheating VP could be a feasible process in industry.     

金属银在高升温速率下的熔化和过热行为

采用分子动力学方法和QSC(quantum Sutton-Chen)力场研究了升温速率对金属银的熔化和过热行为的影响.模拟中考虑了缺陷和表面对熔化和过热行为的影响.研究结果表明,升温速率对金属银的熔化和过热行为有很大影响,随着升温速率的升高,金属银的熔点有所升高.高的升温速率会导致金属银体系内部无序化程度增加,降低了熔化相变的能垒.升温速率导致的银完美晶体的过热极限大约为1450 K.     

Phase diagram of kaolinite from Molecular Dynamics calculations

Structural and thermal behaviors of uncharged 1:1 phyllosilicates kaolinite were investigated from molecular dynamics simulations based on the CLAYFF force field. The focus is on the variation of structural properties including bulk modulus with pressure from 0 to 20 GPa under various range of temperature. The largest bulk modulus between the pressures of 200 and 800 MPa varies from 80 GPa at 298 K to 50 GPa at 1473 K. The obtained value of C_p varies between 7.8 and 13.6 Kcal mol⁻¹ K⁻¹ in the pressure range of 0.1 MPa–20 GPa. Besides, a huge difference was noticed regarding the computed properties at the superheating point. Finally, we show the relationship between superheating point temperature and pressure leading to a phase diagram of kaolinite.