Monte Carlo solution of the Schrödinger equation in Fock space representation

The importance ~mpling method is applied to the least SXJUZIXS solution of the Schrtidinger equation, using the sphericaS facssian orbital to sekct points. Application to the helium atom gives good results with relatively few points.

It is shown that a generalization of the Fourier convolution theorem can be used to iterate solutions of the many-particle Schrijdinger equation in momentum space. The method is developed both with ordinary coordinates and with hyperspherical coordinates, and as an illustration it is applied to elec

Using the Hi ion as an example, we discuss a fully numerical approach to the solution of the Hartree-Fock equation in momentum space which ensures accurate and stable solutions for polyatomic molecules. We made use of a "tangential" grid to solve the problems of truncation of momentum space and the

A new approach to the computational solution of the Schfbdinger equation is based on the partial transformation of the Hamiltonian to a tridiagonal matrix. The method is especially suited to tight-binding Hamiltonians encountered in solid state physics and permits of the order of iodegrees of freedo

## Abstract We consider the numerical solution of the time‐dependent Schrödinger equation in ℝ^3^. An artificial boundary is introduced to obtain a bounded computational domain. On the given artificial boundary the exact boundary condition and a series of approximating boundary conditions are const

## Abstract Using a general symmetry approach we establish transformations between different non‐linear space–time dependent evolution equations of Schrödinger type and their respective solutions. As a special case we study the transformation of the standard non‐linear Schrödinger equation (NLS)‐eq