Saved in:
Bibliographic Details
Main Author: Muchane, Kagwe A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.07902
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866908949682323456
author Muchane, Kagwe A.
author_facet Muchane, Kagwe A.
contents We revisit the Pauli-Clifford connection to introduce a real, grade-preserving algebraic framework for $n$-qubit quantum computation based on the tensor product $C\ell_{2,0}(\mathbb{R})^{\otimes n}$. In this setting, the bivector $J = e_{12}$ satisfies $J^{2} = -1$ and supplies the complex structure on the $J$-closure of a minimal left ideal via right multiplication, while Pauli operations arise as left actions of Clifford elements. The Peirce decomposition organizes the algebra into sector blocks determined by primitive idempotents, with nilpotent elements generating transitions between sectors. Quantum states are represented as equivalence classes modulo the left annihilator, exhibiting the quotient description underlying the minimal left ideal. Adopting a canonical stabilizer mapping, the $n$-qubit computational basis state $|0\cdots 0\rangle$ is given natively by a tensor product of these idempotents. This structural choice leads to a compatibility law that is stable under the geometric product for $n$ qubits and aligns symbolic Clifford multiplication with unitary evolution on the Hilbert space.
format Preprint
id arxiv_https___arxiv_org_abs_2512_07902
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The State-Operator Clifford Compatibility: A Real Algebraic Framework for Quantum Information
Muchane, Kagwe A.
Quantum Physics
High Energy Physics - Theory
Mathematical Physics
We revisit the Pauli-Clifford connection to introduce a real, grade-preserving algebraic framework for $n$-qubit quantum computation based on the tensor product $C\ell_{2,0}(\mathbb{R})^{\otimes n}$. In this setting, the bivector $J = e_{12}$ satisfies $J^{2} = -1$ and supplies the complex structure on the $J$-closure of a minimal left ideal via right multiplication, while Pauli operations arise as left actions of Clifford elements. The Peirce decomposition organizes the algebra into sector blocks determined by primitive idempotents, with nilpotent elements generating transitions between sectors. Quantum states are represented as equivalence classes modulo the left annihilator, exhibiting the quotient description underlying the minimal left ideal. Adopting a canonical stabilizer mapping, the $n$-qubit computational basis state $|0\cdots 0\rangle$ is given natively by a tensor product of these idempotents. This structural choice leads to a compatibility law that is stable under the geometric product for $n$ qubits and aligns symbolic Clifford multiplication with unitary evolution on the Hilbert space.
title The State-Operator Clifford Compatibility: A Real Algebraic Framework for Quantum Information
topic Quantum Physics
High Energy Physics - Theory
Mathematical Physics
url https://arxiv.org/abs/2512.07902