Graded Paraparticle Algebra of Majorana Fields for Multidimensional Quantum Computing with Structured Light
Abstract
We present a theoretical framework that integrates Majorana's infinite-component relativistic equation within the algebraic structure of paraparticles through the minimal nontrivial --graded Lie algebras and -matrix quantization. By mapping spin-dependent mass spectra to graded sectors associated with generalized quantum statistics, we derive an equation embodying Majorana's mass-spin relation describing Majorana quasiparticles of structured light carrying spin and orbital angular momentum. These quanta in the --graded algebras and -matrix formulations extend the previous results from superconducting qubits to photonic platforms and set up deterministic 2-photon gates involving at least two qubits encoded in a single photon without nonlinear effects. This makes feasible general quantum computing pathways exploiting fractional statistics through Nelson's quantum mechanics and implement a novel procedure for error correction in photonic platforms. Furthermore, this approach makes possible to set paraparticle-based quantum information processing, beyond fermions and bosons, using graded qudits.
Cite
@article{arxiv.2505.23232,
title = {Graded Paraparticle Algebra of Majorana Fields for Multidimensional Quantum Computing with Structured Light},
author = {Fabrizio Tamburini and Nicolò Leone and Matteo Sanna and Roberto Siagri},
journal= {arXiv preprint arXiv:2505.23232},
year = {2025}
}
Comments
37 pages total, 4 figures, 11 tables