A quantum number theory
Abstract
We employ an algebraic procedure based on quantum mechanics to propose a `quantum number theory' (QNT) as a possible extension of the `classical number theory'. We built our QNT by defining pure quantum number operators (-numbers) of a Hilbert space that generate classical numbers (-numbers) belonging to discrete Euclidean spaces. To start with this formalism, we define a 2-component natural -number , such that , satisfying a Heisenberg-Dirac algebra, which allows to generate a set of natural -numbers . A probabilistic interpretation of QNT is then inferred from this representation. Furthermore, we define a 3-component integer -number , such that and obeys a Lie algebra structure. The eigenvalues of each component generate a set of classical integers , , albeit all components do not generate simultaneously. We interpret the eigenvectors of the -numbers as `-number state vectors' (QNSV), which form multidimensional orthonormal basis sets useful to describe state-vector superpositions defined here as quits. To interconnect QNSV of different dimensions, associated to the same -number, we propose a quantum mapping operation to relate distinct Hilbert subspaces, and its structure can generate a subset , the field of non-zero rationals. In the present description, QNT is related to quantum computing theory and allows dealing with nontrivial computations in high dimensions.
Cite
@article{arxiv.2108.10145,
title = {A quantum number theory},
author = {Lucas Daiha and Roberto Rivelino},
journal= {arXiv preprint arXiv:2108.10145},
year = {2021}
}