Li+低能(e,2e)反应角分布

利用修正的BBK理论，考虑入射道的库仑相互作用及出射电子的交换对称性，在共面-等能分享-垂直角度碰撞几何中，分别计算了能量为79.6，105.6，227.6和375.6eV的入射电子碰撞Li⁺(1s²)(e，2ｅ)反应三重微分截面(TDCS).结果表明：在接近阈能的碰撞中，两出射电子连线平行于入射电子方向时，TDCS最大；两出射电子连线垂直于入射电子方向时，TDCS最小；入射电子能量达5倍的电离阈能时，主要为单次双体碰撞，而且入射道库仑场对决定低能碰撞的TDCS起着重要作用. 关键词：     

共面双对称几何条件下Ne原子(e,2e)反应的三重微分截面

利用标准一阶扭曲波玻恩近似方法(DWBA)计算了共面双对称几何条件下不同能量电子碰撞电离Ne原子的三重微分截面(TDCS),与Nixon和Murray[1]最新的实验测量数据进行比较.当入射电子能量较低时,理论计算结果和实验数据符合较差;而随着入射电子能量的增加,符合程度逐渐改善.     

电子碰撞锂原子(e,2e)反应三重微分截面的计算

采用畸变波玻恩近似(DWBA)方法,计算了入射能量为400 eV和200 eV的 电子碰撞锂原子(e,2e)反应在非共面对称几何条件下的三重微分截面(TDCS),并研究了 极化势对TDCS的影响。     

共面双对称几何条件下Ne原子(e,2e)反应的三重微分截面

利用标准一阶扭曲波玻恩近似方法（DWBA）计算了共面双对称几何条件下不同能量电子碰撞电离Ne原子的三重微分截面(TDCS),与Nixon和Murray 最新的实验测量数据进行比较.当入射电子能量较低时,理论计算结果和实验数据符合较差;随着入射电子能量的增加,而符合程度逐渐改善.     

共面双对称几何中Li+(1s2)(e,2e)反应的理论研究

利用Berakdar理论,考虑了入射道的库仑相互作用,在共面双对称碰撞几何中,计算了能量为251eV入射电子碰撞Li⁺(1s²)(e,2e)反应的三重微分截面(TDCS),讨论了不同散射振幅对截面的贡献,分析了干涉效应及入射道库仑场对截面的影响.结果表明,它们对决定TDCS的角度分布和大小起着重要作用. 关键词：     

低能电子碰撞Ar(e, 3e)双电离实验

通过Ar(e, 3e)五重微分截面3维图的理论与实验比较发现, 在低能电子入射的情况下, 理论与实验存在较大的偏差.     

氦原子(e,3-1e)反应中未探测电子屏蔽效应的理论研究

在DS3C模型的基础上,对氦原子(e,3-1e)反应的末态He+2场中未探测电子的屏蔽效应进行了研究.计算了(e,3-1e)过程中入射能为640 eV时,电子入射双电离He原子的四重微分截面(4DCS);讨论了非一级效应对截面结构的影响.所得结果与其他理论计算进行比较发现:文中结果与最新测量的实验数据较好地吻合.     

离子和原子共面不对称(e,2e)三重微分截面的比较

本文用自旋平均静态交换势三体扭曲波波恩近似(DWBA)计算了Li+(1s2)和He(1s2)、K+(3p6) 和Ar(3p6)在1?000?eV入射能下的共面不对称(e, 2e)三重微分截面(TDCS).通过比较离子和原子靶三重微分截面的角分布,表明两体碰撞图像在离子靶的情形不成立.     

利用正交投影解析求解氢原子的(e,2e)反应

利用能壳上跃迁矩阵元的后滞形式和双势公式,对快电子碰撞氢原子的单离化反应,提出了一个新的计算方法.跃迁矩阵元被表示为两项,当入射电子和散射电子近似为平面波时,跃迁矩阵元的第一项是一个发散的复数;而第二项计算的角分布就已有双峰结构了.那么通过碰出电子的库仑波函数在氢原子束缚态上的正交投影,使得前者对三重微分截面的贡献为零.计算发现正交投影过程增大了binary峰,降低了recoil峰.另外,当量子数n增大时,正交投影过程对三重微分截面的影响是减弱的.理论曲线与实验数据进行了比较.     

离子和原子共面不对称（e，2e）三重微分截面的比较

本用自旋平均静态交换势三体扭曲波波恩近似(DWBA)计算了Li^ (1s^2)和He(1s^2)、K^ (3p^6)和Ar(3p^6)在1000eV入射能下的共面不对称(e，2e)三重微分截面(TDCS)。通过比较离子和原子靶三重微分截面的角分布，表明两体碰撞图像在离子靶的情形不成立。     

Triple differential cross section in ionization of hydrogen by electron impact

A novel model is proposed to study the ionization of atomic hydrogen by fast election impact in coplanar asymmetric geometry making use of the post form of the transition matrix element for the energy shell and the two-potential formula. Based on the approximation of projectile plane waves and three-body problems, the transition matrix element is decomposed into two parts: the structure and scattering factor and the correlation factor. The contributions of these factors to triple differential cross sections are investigated using the method of asymptotic and convergent series.     

电子碰撞下氢原子单离化反应三重微分散射截面的计算

在共面非对称几何条件下，利用能壳上跃迁矩阵元的后滞形式和双势公式，对快电子碰撞下氢原子的单离化，提出了一个新的计算方法.通过分解动能算符，并且略去两电子的质心运动和相对运动的指数因子，对快电子采用平面波的近似形式，得到了库仑三体问题的近似解.散射振幅可以表示成两个因子乘积的形式，即结构散射因子T₂和关联因子T12.采用渐近级数展开和最佳截断的方法讨论了T₂和T₁₂对三重微分散射 截面的影响. 关键词： （e;2e）反应 三重微分截面 二体峰值 反冲峰值     

末态电子的关联在氢原子(e,2e)反应中的影响(英文)

在共面非对称几何条件下,利用双势公式解析计算了电子碰撞电离氢原子的三重微分截面.对快电子采用平面波近似,跃迁矩阵元可以表示成两个因子乘积的形式,即结构散射因子和出射道两电子的关联因子.在计算过程中对关联因子采取了最简单的近似,当入射能量为150 eV和54.4 eV时,计算结果与实验结果的符合说明对于这些入射能量该关联近似是有效的;而对于入射能量为27.2 eV时,计算结果与实验结果的较大差异说明这种关联近似是无效的.     

氢原子(e,2e)反应离化振幅的分析

利用双势公式的后滞形式并且在入射的快电子近似的取为平面波的基础上,在共面非对称几何条件下计算了电子离化氢原子的三重微分散射截面.变换矩阵元可以解析的表示为结构散射因子和关联因子的乘积形式(关联因子和结构散射因子分别对应于recoil peak和binary peak)解决了由于大量的数值计算而带来的麻烦.本文引入一个有效电荷,通过对它进行调整考虑了变换矩阵元中的第一项的影响.最后把计算结果与实验结果及他人的结果进行了比较,与实验结果符合的很好.     

Two-photon decay in strong central fields observed for the case of He-like gold

The photon energy differential shape of the second order matrix element for the two-photon (2E1) decay of the 1s2s¹S₀ level in He-like gold has been measured. The results are in agreement with a recent fully relativistic calculation. The corresponding 2E1 matrix element deviates from those in lighter He-like systems due to the strong central field in a heavy two-electron ion.     

Quasi-binary incident electron—centre of mass collision in (e, 3e) process on He and He-like ions

We present in this communication the results of our first Born calculation in the three-Coulomb (3C) wave approach for the (e, 3e) process on He and He-like ions at an incident electron energy 5599 eV in the coplanar constant θ12 as well as out-of-plane constant φ12 modes. These two geometrical modes are such that the quasi-binary collision between the incident electron and centre of mass of the ejected electrons is in the scattering plane. The theoretical formalism has been developed using plane waves, Le Sech wave function and approximated BBK-type wave function respectively for the incident and scattered, bound and ejected electrons to calculate five-fold differential crosssection (FDCS) of the (e, 3e) process. We emphasize on the similarities and dissimilarities (asymmetries) in the angular profile of the FDCS in two modes as well as the effects of post-collision interaction (between the ejected electrons) and nuclear chargeZ on the angular profile of the FDCS. We observe that with the increment of nuclear charge the two quasi-binary collisions approach towards identical behaviour at larger mutual angles and thus bringing less asymmetry in FDCS for higherZ target.     

Effect of pair breaking on mesoscopic persistent currents well above the superconducting transition temperature

We consider the mesoscopic normal persistent current (PC) in a very low-temperature superconductor with a bare transition temperature T_0(c) much smaller than the Thouless energy E(c). We show that in a rather broad range of pair-breaking strength, T_0(c) < or = Planck's/tau(s)< or =E(c), the transition temperature is renormalized to zero, but the PC is hardly affected. This may provide an explanation for the magnitude of the average PC's in the noble metals, as well as a way to determine their T_0(c)'s.     

Fourier transform technique in variational treatment of two-electron parabolic quantum dot

In this work,we propose an efficient method of reducing the computational effort of variational calculation with a Hylleraas-like trial wavefunction.The method consists of introducing integral transforms for the terms as r k 12 exp (λr 12) which provide the calculation of the expectation value of energy and the relevant matrix elements to be done analytically over single-electron coordinates instead of Hylleraas coordinates.We have used this method to calculate the ground state energy of a two-electron system in a spherical dot and a disk-like quantum dot separately.Under parabolic confinement potential and within effective mass approximation size and shape effects of quantum dots on the ground state energy of two electrons have been investigated.The calculation shows that our results even with a small number of basis states are in good agreement with previous theoretical results.     

Electron energy state spin-splitting in 3D cylindrical semiconductor quantum dots

In this article we study the impact of the spin-orbit interaction on the electron quantum confinement for narrow gap semiconductor quantum dots. The model formulation includes: (1) the effective one-band Hamiltonian approximation; (2) the position- and energy-dependent quasi-particle effective mass approximation; (3) the finite hard wall confinement potential; and (4) the spin-dependent Ben Daniel-Duke boundary conditions. The Hartree-Fock approximation is also utilized for evaluating the characteristics of a two-electron quantum dot system. In our calculation, we describe the spin-orbit interaction which comes from both the spin-dependent boundary conditions and the Rashba term (for two-electron quantum dot system). It can significantly modify the electron energy spectrum for InAs semiconductor quantum dots built in the GaAs matrix. The energy state spin-splitting is strongly dependent on the dot size and reaches an experimentally measurable magnitude for relatively small dots. In addition, we have found the Coulomb interaction and the spin-splitting are suppressed in quantum dots with small height. Received 15 May 2001 / Received in final form 14 May 2002 Published online 13 August 2002