Elementary Quantum Mechanics in a Space-time Lattice

Abstract

Studies of quantum fields and gravity suggest the existence of a minimal length, such as Planck length Floratos,Kempf. It is natural to ask how the existence of a minimal length may modify the results in elementary quantum mechanics (QM) problems familiar to us Gasiorowicz. In this paper we address a simple problem from elementary non-relativistic quantum mechanics, called "particle in a box", where the usual continuum (1+1)-space-time is supplanted by a space-time lattice. Our lattice consists of a grid of λ0 × τ0 rectangles, where λ0, the lattice parameter, is a fundamental length (say Planck length) and, we take τ0 to be equal to λ0/c. The corresponding Schrodinger equation becomes a difference equation, the solution of which yields the q-eigenfunctions and q-eigenvalues of the energy operator as a function of λ0 . The q-eigenfunctions form an orthonormal set and both q-eigenfunctions and q-eigenvalues reduce to continuum solutions as λ0 → 0 . The corrections to eigenvalues because of the assumed lattice is shown to be O(λ02). We then compute the uncertainties in position and momentum, x, p for the box problem and study the consequent modification of Heisenberg uncertainty relation due to the assumption of space-time lattice, in contrast to modifications suggested by other investigations such as Floratos.