Application of Gröbner basis in calculation of wave functions in nanostructures

Abstract: The knowledge of exact wave functions is required in calculating physical parameters such as optical dipole moments, scattering matrix elements, or in wave function engineering. In this report we describe how a system of algebraic equations that follows from the Schrödinger equation can be reduced to a Gröbner basis from which the exact wave function can be easily constructed. As an example, closed form solutions for a cylindrical electronic waveguide and double quantum well nanostructures are presented.

“…Congruent complexified quaternion representations have been considered before also by Edmonds [7], Baylis [38], Sobczyk [39], and Sachs [40,41]. Recently, the Pauli algebra has been applied to fermion spin by Baylis et al [49], to polarization optics by Tudor [50], and to semiconductor physics by Dargys, see [51] and references therein.…”

Higher Spin Quaternion Waves in the Klein-Gordon Theory

“…Congruent complexified quaternion representations have been considered before also by Edmonds [7], Baylis [38], Sobczyk [39], and Sachs [40,41]. Recently, the Pauli algebra has been applied to fermion spin by Baylis et al [49], to polarization optics by Tudor [50], and to semiconductor physics by Dargys, see [51] and references therein.…”

Higher Spin Quaternion Waves in the Klein-Gordon Theory