Elementary Quantum Gates from Lie Group Embeddings in U(2n): Geometry, Universality, and Discretization

Abstract

In the standard circuit model, elementary gates are defined relative to a chosen tensor factorization and are therefore extrinsic to the ambient group U(2n). Writing N=2n, we introduce an intrinsic descriptor layer in U(N) by declaring as primitive the motions inside faithful embedded copies of SU(2) (phase-free), together with a phase-inclusive U(2) variant. We describe the embedding landscape (SU(2),U(N)) as a finite union of U(N)-homogeneous strata indexed by isotypic multiplicities, with stabilizers given by centralizers, and we isolate a canonical two-level sector parameterized by 2(N) up to a PSU(2) gauge. Equipping U(N) with the Hilbert--Schmidt bi-invariant metric, each embedded subgroup is totally geodesic, yielding a variational characterization of elementary motions via minimal-norm logarithms. On the constructive side, we prove phase-free universality in SU(N) from two-level primitives using QR/Givens factorizations together with explicit diagonal generation, and we obtain full universality in U(N) by explicit abelian phase bookkeeping (equivalently, via the U(2) two-level dictionary). Finally, we formalize a modular finite-alphabet compilation interface: any approximation routine in SU(2) (e.g.\ Solovay--Kitaev) can be lifted through two-level embeddings to yield U(N)-level synthesis with global operator-norm error control.