A critical study of high energy electron scattering from H2

A s:udy of electron coliisions with ground-state CO2 mo!ecules in the energy range 0.07-lr3.0 eV is reported. An accurate static potential is augmented with a local exchange potential and induced polarization terms, and coupled radial equations are solved in a spherical coordinate system. Converged

The N-, molecule is known to display large discrepancies between calculated and experimental high-energy electron scattering cross sections. In order to resolve uncertainties with regard to the hitherto incomplete correlation treatment, experimentally accessible scattering cross sections (including

The Schrodinger equation for the scattering of an electron by a hydrogen molecule is solved by the finite element method, in spherical coordinates, using fifth-order Hermite interpolating polynomials. The computational method is quite similar to the w Ž . x work of Shertzer and Botero Phys. Rev. A

Neutron inelastic scattering from the intramolecular vibration of hydrogen at x 5 16 meV (4 162 cm-' ) has been observed for the tint time using the system C2&s(H2) 1.52 at 4 K. The data are consistent with an effective mass of the scattering particle of z 1.33 amu which confirms the presence of Hz