Spin-Adapted Fermionic Unitaries: From Lie Algebras to Compact Quantum Circuits
Ilias Magoulas, Francesco A. Evangelista
TL;DR
This paper develops Lie algebra-based methods to create highly efficient, symmetry-preserving quantum circuits for simulating many-body systems, significantly reducing quantum resource requirements.
Contribution
It introduces exact product formulas for symmetry-adapted unitaries and a minimal universal operator pool, advancing quantum circuit design for chemistry applications.
Findings
Derived exact product formulas for symmetry-adapted unitaries
Designed the most efficient symmetry-preserving quantum circuits to date
Proposed a minimal universal operator pool for resource reduction
Abstract
Conservation of symmetries plays a crucial role in both classical and quantum simulations of many-body systems, enabling the tracking of states with specific symmetry properties and leading to substantial reductions in the number of optimization parameters. The design of efficient quantum circuits that enforce all symmetries typically encountered in chemistry has remained elusive, mainly due to the interplay of point group and spin symmetries. By exploiting Lie algebraic techniques, we derive exact product formulas representing symmetry-adapted unitaries. These decompositions allow us to design the most efficient symmetry-preserving quantum circuits to date. Finally, we introduce a minimum universal symmetry-adapted operator pool to further reduce the required quantum resources.
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Taxonomy
TopicsQuantum many-body systems · Quantum Computing Algorithms and Architecture · Magnetism in coordination complexes