水分子在水化蒙脱石表面脱附行为的第一性原理研究

使用密度泛函理论计算研究了水分子在蒙脱石(MMT)表面的脱附作用．水分子在MMT 表面的脱附受到配衡离子(Li+,Na+,或K+),MMT表面和吸附水分子的共同作用．通过势能面扫描得到了脱附水分子在MMT表面脱附的能量路径．通过对脱附水分子能量路径的分析发现：水分子在MMT 表面的脱附能垒受到配衡离子种类的影响,半径较小的配衡离子具有较大的脱附能垒．此外,吸附水的存在能降低脱附水分子的脱附能垒,使脱附过程容易触发．     

基于第一性原理的CVD金刚石涂层表面氧原子作用分析

采用第一性原理方法研究了氧原子在CVD金刚石涂层表面吸附形成的两种氧掺杂结构的差异及脱附CO的难易程度.仿真计算结果表明：氧原子在金刚石表面顶位和桥位吸附形成C=O羰结构和C-O-C醚结构,改变与其直接成键的局部金刚石结构;C-O-C结构吸附能比C=O结构大,其结构更加稳定;C=O结构断键脱附形成CO的能垒比C-O-C结构更低,CVD金刚石涂层表面脱附CO主要是以C=O断键形成;氢终止表面能够增强碳原子之间成键,提高C=O脱附的能垒,而氧终止表面作用相反,降低脱附能垒.     

脂肪醇聚氧乙烯醚在空气-水界面上铺展单分子膜的脱附性质

采用Wilhelmy法测定脂肪醇聚氧乙烯醚在空气-水界面上铺展单分子膜的动态表面压,并由此计算动态脱附动力学参数.实验结果表明,样品铺展膜的脱附初期扩散系数约10-3～10- 4cm2/sec,远远大于溶液表面吸附的扩散系数,铺展膜的初始表面浓度越大,其初期脱附扩散系数也越大.但是从脱附整个过程看,铺展膜的初始表面浓度越大,其平均脱附速率常数越小,脱附过程是属于扩散控制和表面能垒控制共同作用的混合模式.     

MgH_2(110)表面Pd单原子催化氢脱附反应的第一性原理研究（英文）

本文采用第一性原理密度泛函理论计算研究了MgH_2(110)表面吸附单原子Pd后的氢脱附反应.计算发现,在吸附一个Pd单原子后,MgH_2(110)表面氢脱附反应的能垒可以从1.802 eV显著地降低到1.154 eV,表明Pd单原子对于氢脱附具有很强的催化效应.并且,Pd单原子催化还可以将氢脱附的温度从573 K显著地降低到了367 K,从而使MgH_2(110)表面的氢脱附反应更加容易和快速地发生.此外,通过MgH_2(110)表面氢溢出机制的反向过程来讨论了氢脱附反应的微观过程.该研究表明Pd/MgH_2薄膜在未来的实验中可作为良好的储氢材料.     

离子配对动力学不一定遵循Eigen-Tamm机理

Eigen-Tamm模型认为水溶液中的离子对从单水分子桥链离子对到紧密离子对是离子对溶剂化平衡的动力学控制性步骤,两态之间自由能垒最高,相互转化速率最慢. 设计了两类带有单位电荷的离子对模型(2.0:x和x:2.0,固定离子对中的阳离子或阴离子的半径为2 ?,另一个为不同半径的阴阳离子),通过计算离子对不同距离的平均力势来获取自由能曲线,发现2.0:x系列离子对由于溶剂水的作用,从单水分子桥链离子对到紧密离子对转化的自由能垒有明显减低,并不是离子成对动力学平衡中的最慢步骤,与Eigen-Tamm 模型描述存在偏差.     

球状胶束中表面活性剂脱附的离子调控机制

建立耦合伞状采样的粗粒度分子动力学方法,研究球状胶束中表面活性剂分子的脱附过程,揭示表面活性剂聚集数、盐种类及浓度对表面活性剂脱附过程的影响机制。发现球状胶束半径及偏心率均随聚集数增加而增大,盐浓度的影响主要取决于抗衡离子的半径和吸附特性,半径更大、吸附更强的水杨酸根离子对胶束结构的影响更为显著;基于伞状采样方法获得了表面活性剂脱附自由能、脱附时间等关键参数,发现球状胶束中表面活性剂脱附自由能和脱附时间均随聚集数和盐浓度呈非单调变化,揭示其主要机制为离子吸附引起的静电屏蔽作用;发现自由能在表面活性剂脱附过程中起主导作用,结合胶束热力学理论发展了临界胶束浓度预测方法,获得了临界胶束浓度下胶束尺寸的分布范围。     

MgH2(110)表面Pd单原子催化氢脱附反应的第一性原理研究

本文采用第一性原理密度泛函理论计算研究了MgH₂(110)表面吸附单原子Pd后的氢脱附反应. 计算发现,在吸附一个Pd单原子后,MgH₂(110)表面氢脱附反应的能垒可以从1.802 eV显著地降低到1.154 eV,表明Pd单原子对于氢脱附具有很强的催化效应. 并且,Pd单原子催化还可以将氢脱附的温度从573 K显著地降低到了367 K,从而使MgH₂(110)表面的氢脱附反应更加容易和快速地发生. 此外,通过MgH₂(110)表面氢溢出机制的反向过程来讨论了氢脱附反应的微观过程. 该研究表明Pd/MgH₂薄膜在未来的实验中可作为良好的储氢材料.     

用双群模型研究表面位垒对离子反射的影响

低能离子在固体表面上反射,对于理解等离子体与聚变堆第一壁相互作用是十分重要的,当离子能量低于千电子伏以下时,表面位垒对离子反射的影响逐渐变得重要起来,本文应用轻离子输运双群模型,考虑了直方表面位垒对输运方程边界条件的影响,得到考虑了位垒影响的离子反射系数,结果表明,当离子能量下降到10倍固体表面位能以下,由于表面位能将引起轻离子反射系数明显减少。 关键词：     

环戊酮光电离解离的实验和理论研究（英文）

本文介绍了真空紫外光电离质谱结合理论计算研究环戊酮单分子的光电离解离过程,在9.0～15.5 eV能量范围内,测量了环戊酮离子及其碎片离子的光电离效率曲线.通过光电离效率曲线,将环戊酮分子的电离能确定为9.23±0.03eV,并确认碎片离子为:C_5H_7O~+,C_4H_5O~+,C_4H_8~+,C_3H_3O~+,C_4H_6~+,C_2H_4O~+,C_3H_6~+, C_3H_5~+,C_3H_4~+, C_3H_3~+, C_2H_5~+,C_2H-4~+.利用量子化学计算方法,在ωB97X-D/6-31+G(d,p)理论水平基础上,提出了C_5H_8O~+的解离机制.通过对环戊酮解离路径的分析,发现开环和氢迁移过程为环戊酮离子解离的主要路径.     

f~4—f~7的波函数

本文用算子L~+,S~+,Q,R求得了f~(4—7)的波函数。并讨论了通过表象变换计算库仑能、自旋轨道作用和晶场,以及使希土离子能量矩阵对角化的方案。     

Adsorption, reaction and desorption of hydrogen on modified Pd(1 1 1) surfaces

The interaction of hydrogen (deuterium) with different modified Pd(1 1 1) surfaces has been investigated. The focus was put on the energy and angel dependence of the desorbing molecules from oxygen covered, potassium covered and vanadium oxide covered surfaces. Conventional adsorption/desorption as well as permeation/desorption experiments were performed. For the oxygen covered surface optimum reaction rates for water production and the energy distribution of the reaction products were determined, both for the reaction of oxygen with molecular hydrogen as well as with atomic hydrogen. Potassium on the surface enhances the activation barrier for hydrogen adsorption resulting in a hyper-thermal desorption flux and a forward focused angular distribution of desorption. Permeation/desorption of deuterium from ultra-thin vanadium oxide films yield mainly thermalized desorbing molecules or slightly hyper-thermal, depending on the oxidation state of the surface oxide.     

Mechanism of H2 desorption from monohydride Si(100)2 × 1H

Most recent experimental work on H₂ desorption from the monohydride Si(100) surface seems to point to a pairwise desorption mechanism involving the concerted desorption of two hydrogen atoms on different Si atoms of a single dimer. Using ab initio SCF and CI theory and a cluster model of the surface, the present work finds that the lowest energy pathway is symmetric rather than asymmetric. The desorption energy barrier is calculated to be 3.7 eV. Compared with an experimental value of 2.6 eV, the large barrier suggests that this direct desorption mechanism is not applicable. A multi-step desorption mechanism which involves a delocalized process in the formation of dihydride SiH₂ and a localized desorption of H₂ is proposed and is shown to explain the experimental observations.     

Real-time monitoring of the desorption process of chlorine-covered Si(111)-‘1×1’ surface with second-harmonic generation

To elucidate the fundamental process underlying the semiconductor surface fabrication, isothermal desorption from a Cl/Si(111)-‘1×1’ surface was monitored by means of second-harmonic generation with 1064 nm light. During the desorption, surface Cl-coverages were obtained in real time. The temperature dependence of the desorption rates revealed that the energy barrier against chloride desorption is 2.1 eV. A very slow second phase in the recovery of the second-harmonic intensity is associated with reconstruction of 7×7 DAS structure following the desorption. The activation energy for the reconstruction was 2.4 eV.     

Quantitative analysis of thermally induced desorption during halogen-etching of a silicon (1 1 1) surface

Thermal desorption at a chlorine-adsorbed Si(1 1 1) surface was measured with high precision. High-sensitivity measurements of the temperature dependence of the isothermal process, and thermal desorption spectra (TDS) with various parameters, heating rates and levels of surface coverage, indicated that the desorption is a second-order reaction with an activation energy of 2.2 eV. The wide dynamic-range data throw light on the ability of various methods of thermal desorption measurement to describe quantitatively the surface reaction. It is important to obtain a precise energy value, which can be done by considering the whole TDS shape, as well as isothermal data, in order to distinguish various reaction processes. Our results are consistent with model calculations.     

Dynamics of high-barrier surface reactions: laser-assisted associative desorption of N2 from Ru(0001)

We have determined the dynamics and energetics of associative desorption of N2 from Ru(0001) using both an experimental technique, laser-assisted associative desorption, and density functional calculations. These show that N2 is preferentially desorbed into very high vibrational states and that the barriers between gas phase N2 and adsorbed N atoms increase from 2 to >3 eV with increasing N coverage on the surface. This experimental technique is found to be quite insensitive to low barrier steps and defects which complicate interpretations from other methods of studying high-barrier surface reactions.     

Mechanistic study of the CO oxidation reaction on the CuO (111) surface during chemical looping combustion

Cu-based oxides oxygen carriers and catalysts are found to exhibit attractive activity for CO oxidation, but the dispute with respect to the reaction mechanism of CO and O₂ on the CuO surface still remains. This work reports the kinetic study of CO oxidation on the CuO (111) surface by considering the adsorption, reaction and desorption processes based on density functional theory calculations with dispersion correction (DFT-D). The Eley–Rideal (ER) CO oxidation mechanism was found to be more feasible than the Mars-van-Krevelen (MvK) and Langmuir–Hinshelwood (LH) mechanisms, which is quite different from previous knowledge. The energy barrier of ER, LH, and MvK mechanisms are 0.557, 0.965, and 0.999 eV respectively at 0 K. The energy barrier of CO reaction with the adsorbed O species on the surface is as low as 0.106 eV, which is much more active in reacting with CO molecules than the lattice O of CuO (111) surface (0.999 eV). A comparison with the catalytic activity of the perfect Cu₂O (111) surface shows that the ER mechanism dictates both the perfect Cu₂O (111) and the CuO (111) surface activity for CO oxidation. The activity of the perfect Cu₂O (111) surface is higher than that of the perfect CuO (111) surface at elevated temperatures. A micro-kinetic model of CO oxidation on the perfect CuO (111) surface is established by providing the rate constants of elementary reaction steps in the Arrhenius form, which could be helpful for the modeling work of CO catalytic oxidation.     

Multi-dimensional mixed quantum–classical description of the laser-induced desorption of molecules

A mixed quantum–classical method for the simulation of laser-induced desorption processes at surfaces is implemented. In this method, the nuclear motion is described classically, while the electrons are treated quantum mechanically. The feedback between nuclei and electrons is taken into account self-consistently. The computational efficiency of this method allows a more realistic multi-dimensional treatment of desorption processes. We apply this method to the laser-induced desorption of NO from NiO(100) using a two-state two-dimensional potential energy surface derived from ab initio quantum chemical calculations; we extend this potential energy surface to seven dimensions employing a physically reasonable model potential. By comparing our method to jumping wave-packet calculations on exactly the same potential energy surface we verify the validity of our method. We focus on the velocity, rotational, and vibrational distributions of the desorbing NO molecules. Furthermore, we model the energy transfer to the substrate by a surface oscillator. Including recoil processes in the simulation has a decisive influence on the desorption dynamics, as far as the velocity and rotational distribution is concerned. In particular, the bimodality in the velocity distribution observed in low dimensions and in the experiment disappears in a high-dimensional treatment. PACS  68.43.Tj; 68.43.Rs; 82.20.Gk; 82.20.Wt