入射电子被中性原子散射过程中的库仑波描述

在前期工作的基础上,给出了有效电荷Zeff的解析形式.研究发现:有效电荷Zeff与入射电子的能量和散射角有关.当入射电子处在有效电荷库仑场的情形下,我们计算了电子入射离化氦原子的三重微分截面,并发现现有的理论计算与实验结果很好的一致.     

氦原子（e，2e）反应中库仑波描述入射电子的理论研究

在前期工作的基础上，当初通道使用具有有效电荷库仑波时，完成了电子入射离化氯原子三重微分截面的理论推导。计算表明：初通道库仑场对较低入射能量情况下，(e，2e)过程的三重微分截面有较大影响。     

氦原子(e,2e)反应中库仑波描述入射电子的理论研究

在前期工作的基础上,当初通道使用具有有效电荷库仑波时,完成了电子入射离化氦原子三重微分截面的理论推导.计算表明:初通道库仑场对较低入射能量情况下,(e,2e)过程的三重微分截面有较大影响.     

氦原子(e,2e)反应中库仑波描述入射电子的理论研究

在前期工作的基础上,当初通道使用具有有效电荷库仑波时,完成了电子入射离化氦原子三重微分截面的理论推导.计算表明初通道库仑场对较低入射能量情况下,(e,2e)过程的三重微分截面有较大影响.     

低能电子离化H初通道库仑作用过程的理论研究

基于CDS3C模型,研究了初通道库仑场对低能电子碰撞H(e,2e)反应三重微分截面(TDCS)的影响,计算了在共面对称几何条件下,两个出射电子相对角取不同固定值时,能量近阈值(E0=30、20和17.6eV)的入射电子碰撞H(e,2e)反应的TDCS,将其计算结果与3C、DS3C模型所得结果与实验结果进行了比较.结果表明,初通道库仑场对低入射能,两个出射电子相对角较小时的TDCS有一定影响.     

氦原子(e,2e)反应中末通道屏蔽效应的理论研究

在Chen等人工作(2001,Chin. Phys. 10 290)的基础上,进一步对(e,2e)反应的末态He+中核外电子的有效屏蔽给出修正.并用修正后的索末菲参量计算了入射能为40 eV时,共面不对称几何条件下电子离化He原子的三重微分截面.所得结果与其它理论结果及最新绝对测量的实验数据进行比较发现:所得到的理论曲线更接近实验数据.     

初态波函数对电子与He原子碰撞同时电离激发反应的影响

在电子碰撞He原子同时电离同时激发的(e,2e)反应中,利用DWBA模型,考虑了入射通道基态He原子两种不同的初态波函数,计算了He原子同时电离激发反应的三重微分截面(TDCS),并与实验数据进行比较.结果表明,有关联的Silverman波函数计算得到的TDCS与实验数据吻合的更好点.     

电子入射双电离He原子的理论研究

完成了高入射能(E05.6keV),低敲出能(E1=E2=10eV)情形下,电子入射双电离He原子五重微分截面(FDCS)的理论计算.计算中使用了三个电子在He+2离子场中的四体末态波函数.计算结果与其他理论结果进行比较发现:所得结果与最新的(e,3e)实验数据较好地一致.     

初态波函数对电子与He原子碰撞同时电离激发反应的影响

在电子碰撞He原子同时电离同时激发的（e, 2e）反应中,利用DWBA模型,考虑了入射通道基态He原子两种不同的初态波函数,计算了He原子同时电离激发反应的三重微分截面(TDCS),并与实验数据进行比较。结果表明,有关联的Sliverman波函数计算得到的TDCS与实验数据吻合的更好点。     

1KeV电子入射单电离氦原子三重微分散射截面的理论研究

用3C模型、DS3C模型对1KeV电子入射氦原子(e,2e)反应中的三重微分散射截面进行了计算,并将理论计算结果与实验数据进行了比较,研究了各种屏蔽效应对散射平面内以及垂直平面内三重微分散射截面的影响,并对三重微分散射截面变化规律进行了探讨.结果表明:各种屏蔽效应对散射平面内三重微分散射截面的贡献可以忽略;而在垂直平面内,这些效应对三重微分散射截面结构存在较强影响;另外,末态出射电子与靶核的相互作用直接影响散射平面内和垂直平面内截面的结构及其变化规律.     

Differential, elastic integral and moment transfer cross sections for electron scattering from N2 at intermediate- and high-energies

A complex optical model potential modified by incorporating the concept of bonded atom, with the overlapping effect of electron clouds between two atoms in a molecule taken into consideration, is firstly employed to calculate the differential cross sections, elastic integral cross sections, and moment transfer cross sections for electron scattering from molecular nitrogen over the energy range 300—1000eV by using additivity rule model at Hartree—Fock level. The bonded-atom concept is used in the study of the complex optical model potential composed of static, exchange, correlation polarization and absorption contributions. The calculated quantitative molecular differential cross sections, elastic integral cross sections, and moment transfer cross sections are compared with the experimental and theoretical ones wherever available, and they are found to be in good agreement with each other. It is shown that the additivity rule model together with the complex optical model potential modified by incorporating the concept of bonded atom is completely suitable for the calculations of differential cross section, elastic integral cross section and moment transfer cross section over the intermediate- and high-energy ranges.     

Effect of initial-state target polarization on the single ionization of helium by l-keV electron impact

We report new results of triple differential cross sections for the single ionization of helium by 1-KeV electron impact at the ejection energy of 10 eV. Investigations have been made for both the perpendicular plane and the plane perpendicular to the momentum transfer geometries. The present calculation is based on the threewCoulomb wave function. Here we have also incorporated the effect of target polarization in the initial state. A comparison is made between the present calculation with the results of other theoretical methods and a recent experiment [Diirr M, Dimopoulou C, Najjari B, Dorn A, Bartschat K, Bray I, Fursa D V, Chen Z, Madison D H and Ullrich J 2008 Phys. Rev. A 77 032717]. At an impact energy of 1 KeV, the target polarization is found to induce a substantial change of the cross section for the ionization process. We observe that the effect of target polarization plays a dominant role in deciding the shape of triple differential cross sections.     

Effect of initial-state target polarization on the single ionization of helium by 1-keV electron impact

We report new results of triple differential cross sections for the single ionization of helium by 1-KeV electron impact at the ejection energy of 10 eV. Investigations have been made for both the perpendicular plane and the plane perpendicular to the momentum transfer geometries. The present calculation is based on the three-Coulomb wave function. Here we have also incorporated the effect of target polarization in the initial state. A comparison is made between the present calculation with the results of other theoretical methods and a recent experiment [Drr M, Dimopoulou C, Najjari B, Dorn A, Bartschat K, Bray I, Fursa D V, Chen Z, Madison D H and Ullrich J 2008 Phys. Rev. A 77 032717]. At an impact energy of 1 KeV, the target polarization is found to induce a substantial change of the cross section for the ionization process. We observe that the effect of target polarization plays a dominant role in deciding the shape of triple differential cross sections.     

Effect of initial-state target polarization on single ionization of helium by 1-keV electron impact

We report new results of triple differential cross sections for the single ionization of helium by 1-KeV electron impact at the ejection energy of 10 eV. Investigations have been made for both the perpendicular plane and the plane perpendicular to the momentum transfer geometries. The present calculation is based on the three-Coulomb wave function. Here we have also incorporated the effect of target polarization in the initial state. A comparison is made between the present calculation with the results of other theoretical methods and a recent experiment [D黵r M, Dimopoulou C, Najjari B, Dorn A, Bartschat K, Bray I, Fursa D V, Chen Z, Madison D H and Ullrich J 2008 Phys. Rev. A 77 032717]. At an impact energy of 1 KeV, the target polarization is found to induce a substantial change of the cross section for the ionization process. We observe that the effect of target polarization plays a dominant role in deciding the shape of triple differential cross sections.     

Calculation of the elastic scattering properties for cold and ultracold 39K atoms in a triplet state

The elastic scattering properties for collisions between cold and ultracold 39K atoms in a triplet state are investigated. Based on the recent theoretical and experimental results, the improved hybrid potential is presented for a triplet α3∑u^＋ ground state of K2. Our calculated value of the s-wave scattering length a by using the Numerov method for the triplet state is 79.578α0 and found to be in good agreement with the previous ones. The numbers of bound states are supported by the molecular potential. Pronounced shape resonances appear for the l = 3 partial waves for the α3∑u^＋ state. Furthermore, the s-wave scattering cross section, the total cross section and energy positions of shape resonances for the α3∑u^＋ state are calculated.     

中、高能电子被SO2分子散射的微分截面、动量转移截面及弹性积分截面

在考虑分子内成键原子间的电子云重叠效应的基础上,提出了一种能够准确计算“中、高能电子-分子”散射的微分截面、动量转移截面及弹性积分截面的修正势方法.利用可加性规则、使用Hartree-Fock波函数并采用被这一方法修正过的复光学势,在100—1000eV内对电子被SO2分子散射的微分截面、动量转移截面及弹性积分截面进行了计算,并将计算结果与实验及其他理论结果进行比较.结果表明,利用这一修正过的复光学势及可加性规则获得的微分截面比利用未修正的复光学势及可加性规则得到的结果准确得多,计算得到的动量转移截面及弹性积分截面在入射电子能量不低于200eV时也都比较接近实验值.     

Triple-differential cross section for single ionization of H2 by electron impact

The triple-differential cross section (TDCS) for the (e,2e) ionization of a hydrogen molecule is calculated using the molecule distorted-wave Born approximation (MDWBA). Distorted waves are obtained by solving momentum-space coupled-channel Lippmann-Schwinger equations, including the ground state and the lowest-lying electronic state of b3Σu . TDCSs at the incident energy 100 eV in coplanar asymmetric geometry are reported. The present calculations are compared with the available experimental measurements and the theoretical results.