Trace-to-Hilbert-Schmidt Speed Ratio in Quantum Dynamics: Universal Bounds and Effective Rank

Abstract

We address the ratio between the trace speed and the Hilbert-Schmidt speed for differentiable finite-dimensional quantum states, R=\|∂ϕρ\|1/\|∂ϕρ\|2. Since the tangent ∂ϕρ is Hermitian and traceless, R obeys stronger bounds than those for generic operators. For any nonzero tangent of rank r, we prove the sharp bounds 2 Rr for even r and 2 Rr-1/r for odd r, characterizing all equality cases. Nonstationary pure-state and qubit families saturate the lower bound R=2. For odd Hilbert-space dimension d, we further prove the sharp global maximum Rd-1/d. Interpreting R2 as the participation ratio of the singular-value distribution yields an effective-rank picture, reff= R2. We decompose the effective rank into classical eigenvalue and quantum eigenvector contributions and obtain the bound reff rC+rQ, with equality when either component vanishes. Linking the effective rank to the quantum Fisher information F gives reff 8\,TS2/F, showing that a large effective rank is required when this lower bound substantially exceeds the universal minimum value 2. Finally, a hierarchy of quantum speed limits shows how the effective rank controls the tightness of bounds expressed through the Hilbert-Schmidt speed.

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