M. Achler scite author profile

The four-particle process of proton-helium transfer ionization has been studied using cold target recoil ion momentum spectroscopy to measure the momenta of all three particles in the final state. Most of the electrons are emitted in the H0 scattering plane and in the backward direction. The final state momentum distributions show discrete structures very different from those expected for uncorrelated capture and ionization. The measured momentum pattern is interpreted to be due to a new transfer ionization reaction channel which results from strong correlations in the initial He ground state momentum wave function.

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Helicity Dependence of the Photon-Induced Three-Body Coulomb Fragmentation of Helium Investigated by Cold Target Recoil Ion Momentum Spectroscopy

Mergel

Achler

Dørner

et al. 1998

Phys. Rev. Lett.

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The angular and energy dependence of circular dichroism in photo-double-ionization of helium at a photon energy of 99 eV is investigated. Using cold target recoil ion momentum spectroscopy the absolute fivefold differential cross section has been obtained by a coincident measurement of the vector momenta of one electron and the recoiling He 21 ion covering all relative azimuthal and polar angles. The experimental results are contrasted with numerical calculations using different helium ground state wave functions and forms of the dipole operator. [S0031-9007(98)06337-6] PACS numbers: 32.80.Fb, 33.55.AdHelicity adds a new twist to photo-double-ionization of helium: How is the handedness of a circularly polarized photon, absorbed by the spherical symmetric He 1S ground state, transferred to the three-body Coulomb continuum? The handedness leads to a symmetry break in the phase space of the diverging two electrons and the target nucleus. This additional aspect provides a novel tool for the investigation of the photon-induced fragmentation of helium, which is one of the simplest and hence most fundamental manifestations of electron-electron correlation. Helicity dependence can also be used to prove symmetry principles of the three-body Coulomb problem as parity conservation and time reversal invariance.Helicity dependence in photoionization is termed circular dichroism (CD). CD is well known in magnetic solids and chiral or aligned molecules (for a recent review see [1]). However, Berakdar and Klar [2] have theoretically shown that CD does not require a chiral or aligned initial state. They predicted that CD may also be observable in a coincidence measurement (e.g., of the two electrons) in photo-double-ionization of helium from its ground state. In general an appropriate experimental approach to investigate a many body system is to measure the fully differential cross section for the fragmentation of the system by a coincident determination of the vector momenta of all outgoing particles. In their pioneering coincidence experiment Schwarzkopf et al.[3] reported the first fivefold differential cross sections (5DCS) [4] for photo-double-ionization of helium using linearly polarized light. Also the technique of cold target recoil ion momentum spectroscopy (COLTRIMS) has already been used to perform fully differential experiments on photo-double-ionization of helium with linearly polarized light [5]. In 1996 Viefhaus et al. [6] reported the first experimental evidence for CD in the helical photo-double-ionization of helium. They obtained the relative 5DCS for five electron energies each at three fixed angles.In the present experiment we have used COLTRIMS [7-9] to investigate the helical photo-double-ionization of helium at an energy of 20 eV above the double ionization threshold. We have measured the 5DCS for all relative polar and azimuthal angles in the electron energy range of 11.5 through 20 eV. A coincidence solid angle of 10% has been achieved, which is an increase of nearly 3 orders of magnitude compared to t...

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Double Photoionization of Spatially AlignedD2

et al. 1998

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The four-body breakup of spatially aligned D 2 by 58.8 eV photons from the Advanced Light Source has been investigated by measuring the three dimensional momentum vectors of both fragment ions and one of the two electrons in coincidence. Energy and angular correlation between ions and electrons is discussed. We find rotational symmetry of the electron angular distribution around the polarization vector of the light and significant differences between helium and D 2 as well as between molecular alignment parallel and perpendicular to the polarization axis. [S0031-9007(98)

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Intra-atomic Electron-Electron Scattering inp-He Collisions (Thomas Process) Investigated by Cold Target Recoil Ion Momentum Spectroscopy

et al. 1997

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We have performed a kinematically complete experiment for the transfer ionization reaction 0.15 1.4 MeV p 1 He ! H 0 1 He 21 1 e 2 by measuring the three-dimensional momentum vector of the He 21 ion in coincidence with the scattering angle and the plane of the H 0. In the measured fourfold differential cross section we can clearly distinguish between the independent two-step process of capture plus ionization and the correlated e-e Thomas scattering. We find a y 27.461 P scaling for the total cross section of the e-e Thomas process. [S0031-9007(97)03631-4]

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M. Achler

Strong Correlations in the He Ground State Momentum Wave Function Observed in the Fully Differential Momentum Distributions for thep+HeTransfer Ionization Process

Helicity Dependence of the Photon-Induced Three-Body Coulomb Fragmentation of Helium Investigated by Cold Target Recoil Ion Momentum Spectroscopy

Double Photoionization of Spatially AlignedD2

Intra-atomic Electron-Electron Scattering inp-He Collisions (Thomas Process) Investigated by Cold Target Recoil Ion Momentum Spectroscopy

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