English

Simplified projection on total spin zero for state preparation on quantum computers

Quantum Physics 2025-01-08 v2 Nuclear Theory

Abstract

We introduce a simple algorithm for projecting on J=0J=0 states of a many-body system by performing a series of rotations to remove states with angular momentum projections greater than zero. Existing methods rely on unitary evolution with the two-body operator J2J^2, which when expressed in the computational basis contains many complicated Pauli strings requiring Trotterization and leading to very deep quantum circuits. Our approach performs the necessary projections using the one-body operators JxJ_x and JzJ_z. By leveraging the method of Cartan decomposition, the unitary transformations that perform the projection can be parameterized as a product of a small number of two-qubit rotations, with angles determined by an efficient classical optimization. Given the reduced complexity in terms of gates, this approach can be used to prepare approximate ground states of even-even nuclei by projecting onto the J=0J=0 component of deformed Hartree-Fock states. We estimate the resource requirements in terms of the universal gate set {HH,SS,CNOT,TT} and briefly discuss a variant of the algorithm that projects onto J=1/2J=1/2 states of a system with an odd number of fermions.

Cite

@article{arxiv.2410.02848,
  title  = {Simplified projection on total spin zero for state preparation on quantum computers},
  author = {Evan Rule and Ionel Stetcu and Joseph Carlson},
  journal= {arXiv preprint arXiv:2410.02848},
  year   = {2025}
}

Comments

13 pages, 3 figures, v2 matches PRC version

R2 v1 2026-06-28T19:07:36.751Z