Divergency problem of the electron capture to the continuum cusp: Classical trajectory Monte Carlo simulation and experimental data

被引:12
|
作者
Sarkadi, L [1 ]
Barrachina, RO [1 ]
机构
[1] Hungarian Acad Sci, Nucl Res Inst, ATOMKI, H-4001 Debrecen, Hungary
来源
PHYSICAL REVIEW A | 2005年 / 71卷 / 06期
关键词
D O I
10.1103/PhysRevA.71.062712
中图分类号
O43 [光学];
学科分类号
070207 ; 0803 ;
摘要
The question whether the velocity of the projectile and that of the electrons at the maximum of the ECC (electron capture to the continuum) cusp are equal is analyzed by means of classical mechanical calculations. The analysis is made for collisions of 20 keV protons with He atoms. Our theoretical results as well as experimental data do not support the large energy shift of the ECC cusp observed recently by Shah [Phys. Rev. A 67, 010704(R) (2003)].
引用
收藏
页数:6
相关论文
共 50 条
  • [21] Two active-electron classical trajectory Monte Carlo methods for ion-He collisions
    Guzman, F.
    Errea, L. F.
    Pons, B.
    PHYSICAL REVIEW A, 2009, 80 (04):
  • [22] GPU-accelerated Classical Trajectory Calculation Direct Simulation Monte Carlo applied to shock waves
    Norman, Paul
    Valentini, Paolo
    Schwartzentruber, Thomas
    JOURNAL OF COMPUTATIONAL PHYSICS, 2013, 247 : 153 - 167
  • [23] Development of Monte Carlo simulation of characteristic and continuum X-ray generation by electron impact
    Nagatomi, T
    Fujii, K
    Kimura, Y
    Takai, Y
    Shimizu, R
    Yurugi, T
    Obori, K
    MICROBEAM ANALYSIS 2000, PROCEEDINGS, 2000, (165): : 289 - 290
  • [24] Single electron ionization and electron capture cross sections for (C6+, H2O) interaction within the Classical Trajectory Monte Carlo (CTMC) approach
    Tran, H. N.
    Dao, D. D.
    Incerti, S.
    Bernal, M. A.
    Karamitros, M.
    Hao, T. V. Nhan
    Dang, T. M.
    Francis, Z.
    NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION B-BEAM INTERACTIONS WITH MATERIALS AND ATOMS, 2016, 366 : 140 - 144
  • [25] Study of an epithermal neutron filter for neutron capture therapy: experimental validation of the Monte Carlo simulation
    Colomb, F
    Ermont, G
    JOURNAL DE CHIMIE PHYSIQUE ET DE PHYSICO-CHIMIE BIOLOGIQUE, 1998, 95 (04) : 698 - 702
  • [26] Monte Carlo simulation of x-ray spectra in electron probe microanalysis: comparison of continuum with experiment
    1600, American Inst of Physics, Woodbury, NY, USA (76):
  • [27] MONTE CARLO SIMULATION OF TURBULENT ATMOSPHERIC TRANSPORT AND COMPARISONS WITH EXPERIMENTAL DATA.
    Alsmiller, F.S.
    Alsmiller Jr., R.G.
    Bertini, H.W.
    Begovich, C.L.
    Journal of Applied Meteorology, 1979, 18 (01): : 17 - 26
  • [28] Validation of total skin electron irradiation technique dosimetry data by Monte Carlo simulation
    Borzov, E.
    Nevelsky, A.
    Daniel, S.
    Bar-Deroma, R.
    RADIOTHERAPY AND ONCOLOGY, 2015, 115 : S752 - S752
  • [29] Monte Carlo direct simulation of rotational relaxation of diatomic molecules using classical trajectory calculations: Nitrogen shock wave
    Koura, K
    PHYSICS OF FLUIDS, 1997, 9 (11) : 3543 - 3549
  • [30] Monte Carlo simulation for the estimation of iron in human whole blood and comparison with experimental data
    M E MEDHAT
    S P SHIRMARDI
    V P SINGH
    Pramana, 2017, 88
12345