Trace-to-Hilbert-Schmidt Speed Ratio in Quantum Dynamics: Universal Bounds and Effective Rank
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We study the ratio between the trace speed and the Hilbert-Schmidt speed for differentiable finite-dimensional quantum states, $\mathcal R(\phi)=\|\partial_\phi\rho(\phi)\|_1/\|\partial_\phi\rho(\phi)\|_2$. Because $\partial_\phi\rho(\phi)$ is always Hermitian and traceless, this ratio is constrained more strongly than for a generic operator. For any nonzero tangent operator $X=\partial_\phi\rho$ of rank $r$, we prove the sharp bounds $\sqrt{2}\le \|X\|_1/\|X\|_2\le \sqrt r$. The lower bound is attained exactly for rank-two tangents, while the upper bound is attained exactly when all nonzero singular values are equal, which in the traceless Hermitian setting requires even rank. At every nonstationary point of a pure-state family, the tangent has rank two, implying $\mathcal R=\sqrt2$. For odd Hilbert-space dimension $d$, we further prove the sharp global maximum $\mathcal R\le \sqrt{d-1/d}$, with equality characterized by full-rank spectra whose positive and negative eigenvalues are separately degenerate and have multiplicities differing by one. We identify $\mathcal R^2$ as the inverse participation ratio of the singular-value distribution of the tangent operator, giving $\mathcal R$ a natural interpretation as an effective-rank diagnostic for local quantum dynamics. Furthermore, we decompose the effective rank into classical (eigenvalue) and quantum (eigenvector) contributions and prove the bound $r_{\mathrm{eff}}\le r_C + r_Q$, with equality guaranteed when either component vanishes. We establish a direct inequality linking the effective rank to the quantum Fisher information (QFI), which forces a large number of active singular modes when the QFI is small relative to the squared trace speed. Finally, we derive a hierarchy of quantum speed limits in which the effective rank controls the tightness of bounds expressed through the Hilbert-Schmidt speed.
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