排序方式: 共有25条查询结果,搜索用时 18 毫秒
1.
2.
The (e, 2e) triple-differential cross sections of Ag + (4p, 4s) are calculated based on the three-body distorted-wave Born approximation considering post-collision interaction in coplanar symmetric geometry. The energy of the outgoing electron is set to be 50, 70, 100, 200, 300, 500, 700, and 1000 eV, and the intensity and splitting of forward and backward peaks are discussed in detail. Some new structures are observed around 15° and 85° for 4p and 4s orbitals. Structures in triple-differential cross sections at 15° are reported for the first time. A double-binary collision is proposed to explain the formation of such structures. The structures at 85° are also considered as the result of one kind of double-binary collision. 相似文献
3.
4.
通过比较相同电子成分轨道的实验和DFT-B3LYP/6-311+G*理论的电子动量分布,系统研究了CF3Cl,CF2Cl2 和CFCl3分子外价壳层的轨道特性.研究结果表明CF3Cl,CF2Cl2 和CFCl3分子的Cl(3p)孤对电子轨道随着Cl原子个数增多,分子内相互作用逐渐增强,Cl原子3p轨道电子动量分布的特征逐渐淹没;F孤对电子轨道和的电子动量分布在高动量区出现了一个弱结构,且随Cl原子个数增多和F原子个数减少逐渐消失,这可能是由于部分轨道C-Cl 键电子成分的贡献;除3a1轨道外,C-F成键轨道和的理论的电子动量分布均在低动量端低于实验结果,可能是由于“d-like” 轨道低动量端的扭曲波效应;3a1轨道理论的电子动量分布均在 范围内低于实验结果,可能是由于扭曲波效应和电子关联等效应的影响. 相似文献
5.
采用修正后的扭曲波玻恩近似理论,计算了共面不对称几何条件下Xe(4d10)(e, 2e)反应的三重微分截面。散射电子能量为1000eV,敲出电子能量为20eV,散射电子角度分别固定在2o,4o和7.5o。理论计算与Avaldi等人的实验结果和扭曲波玻恩近似理论计算进行了比较,发现出射电子之间的后碰撞相互作用较弱,极化效应在反应过程中起着重要作用。 相似文献
6.
Xe(4d~(10))(e,2e)反应三重微分截面的理论研究 总被引:1,自引:1,他引:0
采用修正后的扭曲波玻恩近似理论,计算了共面不对称几何条件下Xe(4d~(10))(e,2e)反应的三重微分截面.散射电子能量为1000 eV,敲出电子能量为20 eV,散射电子角度分别固定在2°,4°和7.5°.理论计算与Avaldi等人的实验结果和扭曲波玻恩近似理论计算进行了比较,发现出射电子之间的后碰撞相互作用较弱,极化效应在反应过程中起着重要作用. 相似文献
7.
8.
电子碰撞Kr(4s2)(e, 2e)反应三重微分截面的理论研究 总被引:1,自引:1,他引:0
采用扭曲波玻恩近似,计算了共面对称条件下低能电子碰撞Kr(4s2)的(e,2e)反应三重微分截面.与实验结果比较后发现,极化效应和后碰撞相互作用在共面对称几何条件下的~Kr(4s2)低能(e,2e)反应中起着重要的作用. 相似文献
9.
Electron impact ionization of neon and neonic ions under distorted-wave Born approximation 下载免费PDF全文
The (e, 2e) triple differential cross sections of 2s orbitals of neon and neonic ions (Z = 11-14) are calculated using a distorted-wave Born approximation under coplanar asymmetric geometry. The calculated results show that, with the increase in the nuclear charge number Z, the amplitude of triple differential cross sections decreases. The angle difference between the binary peak position and the direction of momentum transfer gradually increases with the increase in the nuclear charge Z, and a new structure appears at an ejected angle 90° 〈 θ2 〈 120°. Three kinds of collision processes are proposed to illustrate the formation mechanism of such collision peaks. 相似文献
10.