O3+与H2碰撞中非解离电荷转移过程的全量子计算

应用全量子的分子轨道强耦合方法，研究了基态的O³⁺(2s²2p ²P)与氢分子碰撞的非解离电荷转移过程，计算了不同方位角(25°，45°，89°)，能量分别为100，500，1000和5000eV/u时的单电子俘获的振动分辨的态选择截面及相应的微分截面.分子轨道强耦合计算中采用了自旋耦合价带理论计算的三原子分子势能面和径向耦合矩阵元.对氢分子的自身转动，采用无限阶的冲量近似方法；对体系的电子运动同H₂或H^+<     

O3+与H2碰撞中解离电子俘获过程的全量子计算

利用全量子的分子轨道强耦合方法,我们研究了基态的O3+(2s22p2P)与氢分子碰撞的解离电荷转移过程.分子轨道强耦合计算中采用了自旋耦合价带理论计算的三原子分子势能面和径向耦合矩阵元.对氢分子的自身转动,我们采用无限阶的冲量近似方法.在入射离子能量为0.1 eV/u到500 eV/u的能量区间,我们得到了非解离碰撞过程的振动态选择单电子俘获截面和解离碰撞过程的单电子俘获微分截面,发现解离碰撞截面大约占非解离过程的10%.这表明在实际的应用中,必须包含解离俘获过程的贡献.     

0^3＋与H2碰撞中解离电子俘获过程的全量子计算

利用全量子的分子轨道强耦舍方法。我们研究了基态的O^3（2s^22p^2P）与氢分子碰撞的解南电荷转移过程．分子轨道强耦合计算中采用了自旋耦合价带理论计算的三原子分子势能面和径向耦合矩阵元．对氢分子的自身转动，我们采用无限阶的冲量近似方法，在入射离子能量为0．1 eV／u到500 eV／u的能量区间。我们得到了非解离碰撞过程的振动态选择单电子俘获截面和解离碰撞过程的单电子俘获微分截面，发现解离碰撞截面大约占非解离过程的10％．这表明在实际的应用中。必须包含解离俘获过程的贡献．     

O3+与H2碰撞中非解离电荷转移过程的全量子计算

应用全量子的分子轨道强耦合方法,研究了基态的O3 (2s22p 2P)与氢分子碰撞的非解离电荷转移过程,计算了不同方位角(25°,45°,89°),能量分别为100,500,1000和5000eV/u时的单电子俘获的振动分辨的态选择截面及相应的微分截面.分子轨道强耦合计算中采用了自旋耦合价带理论计算的三原子分子势能面和径向耦合矩阵元.对氢分子的自身转动,采用无限阶的冲量近似方法;对体系的电子运动同H2或H 2的振动之间的耦合,采用了振动冲量近似.结果发现,对不同的入射能量,振动态选择截面随振动量子数的分布发生了一定的改变;不同入射能量和不同方位角的振动态分辨的微分截面具有类似的结构,在极小的散射角附近出现一个最大值平台,然后散射截面随着散射角的增大而减小,并出现大量的震荡结构,其中第一个震荡结构对应的散射角位置随入射能量Ep以E-1/2p的标度规律变化;微分截面的结构和大小对H2方位角α的变化敏感,这种性质为H2取向的诊断提供了一种可能的途径.     

低能O^3＋与H2碰撞电子俘获过程中靶的同位素效应研究

利用全量子的分子轨道强耦合方法，我们研究了基态的O^3＋（2s^22p^2P）与氚分子和氢分子碰撞的电荷转移过程，计算了方位角为45°，能量分别为0．1eV／u，1．0eV／u，100eV／u，500eV／u的单电子俘获的振动分辨的态选择截面及总截面．分子轨道强耦合计算中采用了自旋耦合价带理论计算的三原子分子势能面和径向耦合矩阵元，对体系的电子运动同H2（T2）或H2^＋（T2^＋）的转动和振动之间的耦合，根据能量的不同，分别采用了无限阶的冲量近似或振动冲量近似．结果发现，低能O^3＋与H2碰撞电子俘获过程中靶的同位素效应显著：对不同的同位素靶，单电子俘获的总截面以及振动分辨态选择截面的分布明显不同；入射离子能量越低，同位素效应越显著．     

低能O3+与H2碰撞电子俘获过程中靶的同位素效应研究

利用全量子的分子轨道强耦合方法,我们研究了基态的O3 (2s22p2P)与氚分子和氢分子碰撞的电荷转移过程,计算了方位角为45°,能量分别为0.1eV/u,1.0eV/u,100eV/u,500eV/u的单电子俘获的振动分辨的态选择截面及总截面.分子轨道强耦合计算中采用了自旋耦合价带理论计算的三原子分子势能面和径向耦合矩阵元.对体系的电子运动同H2(T2)或H2 (T2 )的转动和振动之间的耦合,根据能量的不同,分别采用了无限阶的冲量近似或振动冲量近似.结果发现,低能O3 与H2碰撞电子俘获过程中靶的同位素效应显著:对不同的同位素靶,单电子俘获的总截面以及振动分辨态选择截面的分布明显不同;入射离子能量越低,同位素效应越显著.     

Calculations of state-selective differential cross sections for charge transfer in collisions between O3+ and H2

The non-dissociative charge-transfer processes in collisions between O^3＋ and H2 are investigated by using the quantum-mechanical molecular-orbital coupled-channel （QMOCC） method. The adiabatic potentials and radial coupling matrix elements utilized in the QMOCC calculations are obtained with the spin-coupled valence-bond approach. Electronic and vibrational state-selective differential cross sections are presented for projectile energies of 0.1, 1.0 and 10.0eV/u in the H2 orientation angles of 45° and 89°. The electronic and the vibrational state-selective differential cross sections show similar behaviours： they decrease as the scattering angle increases, and beyond a specific angle the oscillating structures appear. Moreover, it is also found that the vibrational state-selective differential cross sections are strongly orientation-dependent, which provides a possibility to determine the orientations of molecule H2 by identifying the vibrational state-selective differential scattering processes.     

电子与类铍N3+和O4+离子碰撞激发截面的相对论扭曲波计算

采用全相对论扭曲波方法,系统地计算了类铍N³⁺和 O⁴⁺离子从基态到2s2p和2p² 的各激发态以及从亚稳态到2p²各激发态的电子碰撞激发截面,详细地讨论了靶态的关联效应对激发截面的影响.结果表明：对于2s-2p的单电子激发,在低能碰撞时,靶态的电子关联效应起非常重要的作用,且使得激发截面降低;而高能碰撞时,靶态波函数的描述对连续态波函数的影响比较小,对激发截面影响也比较小.对于2s²-2p²的双电子激发,其中基态2s²¹S₀到J=0的2p²³P₀,¹S₀的激发截面较大,其主要原因是末离子态波函数与基组态波函数的混合,但是其他几个激发的激发截面较小. 关键词： 全相对论扭曲波方法 电子碰撞激发 电子关联效应     

Ionization and single electron capture in collision of highly charged Ar16+ ions with helium

This paper uses the two-centre atomic orbital close-coupling method to study the ionization and the single electron capture in collision of highly charged Ar^16＋ ions with He atoms in the velocity range of 1.2-1.9 a.u.. The relative importance of single ionization （SI） to single capture （SC） is explored. The comparison between the calculation and experimental data shows that the SI/SC cross section ratios from this work are in good agreement with experimental data. The total single electron ionization cross sections and the total single electron capture cross sections are also given for this collision. The investigation of the partial electron capture cross section shows a general tendency of capture to larger n and l with increasing velocity from 1.2 to 1.9 a.u..     

Single electron capture in collisions of N^q＋ （q = 5, 6, 7） ions with helium

Close-coupling calculations are carried out for cross sections of the single electron capture in collisions of N^q+ (q = 5, 6, 7) ions with helium atoms in the collision velocity range from 0.3 a.u. to 1.8 a.u. The relative importances of the single ionization (SI) to the single capture (SC) are investigated for the N^q+ (q = 5, 6, 7) projectiles, respectively. The SI/SC cross section ratio for the N⁷⁺ projectile obtained from our calculations is in excellent agreement with the experimental data. The ratio curves also show us distinct behaviours when the charge of the projectile is different. The partial electron capture cross sections for different projectiles indicate that the electron on the target He atom tends to be captured by the projectile into its lower orbital of the outer shell with the decreasing projectile charge.     

He同位素与H2分子碰撞第二振动激发分波截面的理论研究

用公认精确度较高的密耦近似方法计算了不同能量下惰性气体原子³He（⁴He,⁵He）与H₂分子替代碰撞体系的00-20,00-22,00-24,00-26第二振动激发分波截面.通过分析³He（⁴He,⁵He）-H₂碰撞体系第二振动激发分波截面的差异,总结出³He（⁴He,^{5关键词： 振动激发 分波截面 密耦方法 同位素}     

Theoretical calculation of of B-like ions： photoionization cross sections N^2＋, O^3＋ and F^4＋

There can be found some notable discrepancies with regard to the resonance structures when R-matrix calculations from the Opacity Project and other sources are compared with recent absolute experimental measurements of Bizau et al [Astron.Astrophts.439 387(2005)] for B-like ions N2+,O3+ and F4+.We performed close-coupling calculations based on the R-matrix formalism for the photoionizations of ions mentioned above both for the ground states and first excited states in the near threshold regions.The present results are compared with experimental ones given by Bizau et al and earlier theoretical ones.Excellent agreement is obtained between our theoretical results and the experimental photoionization cross sections.The present calculations show a significant improvement over the previous theoretical results.     

Theoretical calculation of the partial cross section for first vibrational excitation in He-H2（D2,T2） collisions

In this paper, close-coupling method was applied to the He-H2 （D2,T2） system, and the first vibrational excitation cross sections of ＇00-10, 00-12, 00-14, 00-16＇ at different incident energy have been calculated. By analyzing the ditferences of these partial wave cross sections, this paper have obtained the change rules of the partial wave cross sections with increases of quantum number, and with change of reduced mass of system. Based on the calculation, influence on the partial wave cross sections brought by the variations in the reduced mass of systems and in the relative kinetic energy of incident atoms is discussed.[第一段]     

不同能量的氦原子与同位素分子H2(D2，T2)碰撞分波截面的理论计算

用Tang-Toennies势模型和密耦近似方法计算了不同能量下惰性气体原子He与H₂及其同位素D₂,T₂替代碰撞体系的振转激发碰撞截面. 通过分析He-H₂(D₂,T₂)各碰撞体系分波截面的差异,总结出在H₂分子的对称同位素替代情形下He-H₂(D₂,T₂)碰撞体系分波截面随量子数和体系 关键词： 散射截面 密耦方法 同位素