Compressibility of micromagnetic solutions in tensor train format

Referee: [Abstract] Abstract: The assertion that accuracy is 'preserved in a controlled way' is not accompanied by any quantitative error measures (e.g., L^2 or L^∞ norm of the magnetization difference, or energy error relative to a dense reference solution), nor by a description of the rank-selection procedure (fixed tolerance, fixed rank, or adaptive). Without these, the claim that the reported L^{1.8} and (1/a)^{1.2} scalings are achieved at acceptable fidelity cannot be assessed.

Authors: We agree with the referee that explicit quantitative error measures and details on the rank selection are necessary to substantiate the claims. In the revised manuscript, we have expanded the abstract slightly and added a dedicated paragraph in the main text (Section II) describing the error control. Specifically, we now report the maximum L^∞ error in the magnetization vector (typically < 0.01) and the relative error in the total magnetic energy (< 0.5%) compared to reference dense-grid solutions obtained with OOMMF. The TT ranks are chosen adaptively by increasing the rank until the approximation error falls below a prescribed tolerance of 10^{-3} in the Frobenius norm of the residual. This procedure is now fully documented, allowing the reader to assess that the reported scalings correspond to controlled accuracy. revision: yes

Referee: [Abstract] Abstract (second paragraph): The scaling exponents are stated as 'approximately' L^{1.8} and (1/a)^{1.2} for flux-closure states, but no information is given on the fitting procedure, the range of L and a sampled, the number of configurations, or fit quality metrics. This makes it impossible to judge whether the exponents are robust or sensitive to the particular choice of test cases and TT ranks.

Authors: We have revised the manuscript to include a new subsection on the scaling analysis (Section III.B). There, we detail the fitting procedure: power-law fits were performed using least-squares regression on log-log plots of the TT parameter count versus L and versus 1/a. The sampled ranges are L from 200 nm to 2 μm (corresponding to 4 to 20 exchange lengths) and cell sizes a from 4 nm to 16 nm. We tested 15 distinct prism aspect ratios and sizes, each with 3-5 different discretizations. The fit quality is quantified by R^2 values exceeding 0.97, with standard errors on the exponents of ±0.05 for L^{1.8} and ±0.08 for (1/a)^{1.2}. These details confirm the robustness of the reported approximate exponents within the tested regime. revision: yes

Referee: [Abstract] The manuscript restricts the demonstration to static flux-closure configurations in rectangular prisms. It is therefore unclear whether the low TT ranks (and the associated favorable scaling) persist when the magnetization develops additional high-gradient features, such as those arising under applied fields, in the presence of topological defects, or during time evolution; the central claim of transcending dense-grid limitations would be strengthened by at least one such additional test case with explicit error control.

Authors: We concur that extending the analysis to cases with applied fields, topological defects (e.g., vortices or skyrmions), or dynamic evolution would further strengthen the work. However, the present Letter is intentionally focused on establishing the basic compression properties for the simplest class of flux-closure states that already exhibit the characteristic sparsity (sharp domain walls separating uniform domains). Developing TT-based solvers for dynamics or external fields involves additional algorithmic challenges (e.g., time integration in TT format or handling non-local demagnetizing fields in low-rank format) that we consider outside the scope of this initial report. In the revised manuscript, we have added a paragraph in the Discussion section explaining why the observed L^{1.8} scaling arises from the surface-like nature of domain walls (whose area scales as L^2 but with TT exploiting the low-rank structure across the third dimension), and we outline a roadmap for future extensions to dynamic problems. We believe this focused scope is appropriate for a Letter and provides the necessary benchmark before tackling more complex scenarios. revision: partial