Symmetry Principles in Quantum Systems Theory

TL;DR

This paper explores how symmetry principles influence the controllability and simulability of quantum systems, providing a comprehensive classification of subalgebras and practical methods for analyzing system dynamics.

Contribution

It introduces a complete lattice of irreducible simple subalgebras of su(2^n) for up to 15 qubits, facilitating easier symmetry and controllability analysis.

Findings

Complete lattice of subalgebras for up to 15 qubits

Symmetry absence implies irreducibility and controllability

Methods for simulating fermionic and bosonic systems with spin systems

Abstract

General dynamic properties like controllability and simulability of spin systems, fermionic and bosonic systems are investigated in terms of symmetry. Symmetries may be due to the interaction topology or due to the structure and representation of the system and control Hamiltonians. In either case, they obviously entail constants of motion. Conversely, the absence of symmetry implies irreducibility and provides a convenient necessary condition for full controllability much easier to assess than the well-established Lie-algebra rank condition. We give a complete lattice of irreducible simple subalgebras of su(2^n) for up to n=15 qubits. It complements the symmetry condition by allowing for easy tests solving homogeneous linear equations to filter irreducible unitary representations of other candidate algebras of classical type as well as of exceptional types. --- The lattice of irreducible simple subalgebras given also determines mutual simulability of dynamic systems of spin or fermionic or bosonic nature. We illustrate how controlled quadratic fermionic (and bosonic) systems can be simulated by spin systems and in certain cases also vice versa.