arxiv: 2601.13255 · v3 · submitted 2026-01-19 · ❄️ cond-mat.str-el · cond-mat.stat-mech· quant-ph

Recognition: no theorem link

Resonant level model from a Krylov perspective: Lanczos coefficients in a quadratic model

Merlin F\"ullgraf , Jiaozi Wang , Jochen Gemmer , Stefan Kehrein

Authors on Pith no claims yet

Pith reviewed 2026-05-16 12:53 UTC · model grok-4.3

classification ❄️ cond-mat.str-el cond-mat.stat-mechquant-ph

keywords resonant level modelLanczos coefficientsKrylov subspaceintegrabilityquantum chaoshybridization functionquadratic model

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The pith

In the resonant level model, couplings can be chosen to produce essentially any growth pattern for the Lanczos coefficients.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The resonant level model consists of a fermionic impurity coupled to a continuum of modes through a hybridization function. The authors derive exact expressions for the Lanczos coefficients of the impurity operator under different hybridization structures at zero temperature. They demonstrate that these coefficients can grow constantly, as the square root of the index, linearly, or follow other patterns depending on the coupling choice. This shows that the same quadratic, integrable model can realize a wide range of Lanczos behaviors. The result implies that Lanczos coefficient growth cannot reliably classify systems as integrable or chaotic.

Core claim

We analytically derive closed expressions for the Lanczos coefficients of Majorana fermion operators of the impurity for different structures of the coupling to the hybridization band at zero temperature. While the model remains quadratic, we find that the growth of the Lanczos coefficients structurally depends strongly on the chosen coupling. Concretely, we find (i) approximately constant, (ii) exactly constant, (iii) square root-like as well as (iv) linear growth in the same model. We further argue that in fact through suitably chosen couplings, essentially arbitrary Lanczos coefficients can be obtained in this model. These altogether evince the inadequacy of the Lanczos coefficients as a

What carries the argument

The hybridization function that determines the recurrence relations yielding the Lanczos coefficients for the impurity Majorana operator in the Krylov basis.

Load-bearing premise

The derivations assume zero temperature and specific analytic forms for the hybridization function that allow closed-form expressions.

What would settle it

Numerical computation of Lanczos coefficients at finite temperature with a generic non-analytic hybridization function that cannot achieve arbitrary growth patterns.

Figures

Figures reproduced from arXiv: 2601.13255 by Jiaozi Wang, Jochen Gemmer, Merlin F\"ullgraf, Stefan Kehrein.

**Figure 2.** Figure 2: FIG. 2. Dynamics from the rescaled coupling densities given [PITH_FULL_IMAGE:figures/full_fig_p004_2.png] view at source ↗

**Figure 3.** Figure 3: FIG. 3. Dynamics of the autocorrelation function [PITH_FULL_IMAGE:figures/full_fig_p004_3.png] view at source ↗

**Figure 4.** Figure 4: FIG. 4. Krylov complexity [PITH_FULL_IMAGE:figures/full_fig_p006_4.png] view at source ↗

read the original abstract

We study the Lanczos coefficients in a quadratic model given by an impurity interacting with a multi-mode field of fermions, also known as resonant level model. We analytically derive closed expressions for the Lanczos coefficients of Majorana fermion operators of the impurity for different structures of the coupling to the hybridization band at zero temperature. While the model remains quadratic, we find that the growth of the Lanczos coefficients structurally depends strongly on the chosen coupling. Concretely, we find $(i)$ approximately constant, $(ii)$ exactly constant, $(iii)$ square root-like as well as $(iv)$ linear growth in the same model. We further argue that in fact through suitably chosen couplings, essentially arbitrary Lanczos coefficients can be obtained in this model. These altogether evince the inadequacy of the Lanczos coefficients as a reliable criterion for classifying the integrability or chaoticity of the systems. Eventually, in the wide-band limit, we find exponential decay of autocorrelation functions in all the settings $(i)-(iv)$, which demonstrates the different structures of the Lanczos coefficients not being indicative of different physical behavior.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

This quadratic model lets you tune Lanczos growth to constant, linear, or sqrt-like patterns via the hybridization function at zero T, which undercuts using those coefficients as a chaos diagnostic, but the arbitrary-sequence claim needs a clearer general proof.

read the letter

The paper shows that the resonant level model, despite being quadratic, can produce several different Lanczos coefficient growth patterns for the impurity Majorana operators depending on the bath coupling. They derive closed analytic expressions at zero temperature for roughly constant growth, exactly constant growth, square-root growth, and linear growth. They also note that the autocorrelation functions decay exponentially in the wide-band limit across all these cases, so the Lanczos patterns do not map to distinct physical behaviors. This is a concrete demonstration that Lanczos growth is not a universal indicator even inside quadratic systems. The explicit derivations are the strongest part; exact results like these are rarer than numerical Lanczos runs in the literature, and they make the counterexample easy to inspect. The argument that essentially arbitrary sequences are possible follows from the freedom to choose the hybridization function, which is an external input rather than something derived from the dynamics itself. The math for the specific cases appears direct and free of obvious circularity. The main limitation is that all closed forms are at zero temperature for analytic hybridization functions that permit exact expressions. It is not shown whether the same tuning freedom survives at finite temperature or for generic non-analytic couplings. If the flexibility is restricted to those special cases, the counterexample to Lanczos-based classification becomes narrower. No numerical cross-checks against direct Lanczos iteration are mentioned in the abstract, which would have helped confirm the analytic results. This work is aimed at researchers using Krylov methods to diagnose integrability or chaos in many-body systems. Anyone following that literature would get value from the explicit examples and the observation about autocorrelation decay. The calculations are grounded enough to merit a serious referee, though the authors should clarify the scope of the arbitrary-sequence claim. I would send it to peer review.

Referee Report

2 major / 1 minor

Summary. The manuscript studies Lanczos coefficients in the resonant level model (a quadratic impurity-bath fermionic system). At zero temperature, it derives closed analytic expressions for the Lanczos coefficients of impurity Majorana operators under several hybridization couplings, obtaining constant, exactly constant, square-root, and linear growth behaviors. It argues that suitable choice of couplings allows essentially arbitrary Lanczos sequences. In the wide-band limit, autocorrelation functions exhibit exponential decay for all examined cases, leading to the conclusion that Lanczos coefficient growth is not a reliable diagnostic for integrability versus chaoticity.

Significance. If the central claim holds, the work supplies exact analytic counterexamples in a simple quadratic model where distinct Lanczos growth structures all produce the same physical signature (exponential autocorrelation decay). This directly challenges the reliability of Lanczos coefficients or Krylov complexity as classifiers of integrability and chaos. The provision of closed-form expressions for multiple coupling structures constitutes a concrete strength, furnishing exact benchmarks that numerical studies can test.

major comments (2)

[argument following the specific cases (i)-(iv)] The assertion that 'through suitably chosen couplings, essentially arbitrary Lanczos coefficients can be obtained' (abstract and concluding discussion) is presented as a general claim but rests only on the explicit derivations for specific analytic hybridization functions at T=0. No general construction or proof is given showing that any prescribed sequence is achievable, nor is it demonstrated that the same freedom persists for non-analytic couplings or at finite temperature. This gap directly affects the strength of the inadequacy conclusion for the classification criterion.
[wide-band limit section] The wide-band limit analysis shows exponential autocorrelation decay for the four explicit cases (i)-(iv), but does not address whether the same decay persists for the broader class of 'arbitrary' couplings invoked in the central claim. If certain couplings yielding exotic Lanczos sequences produce non-exponential decay, the demonstration that Lanczos structure is uncorrelated with physical behavior would be incomplete.

minor comments (1)

[model definition] Notation for the hybridization function and the precise definition of the coupling structures should be collected in a single table or appendix for easier cross-reference with the derived Lanczos expressions.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading of our manuscript and the constructive comments. We address each major comment below and indicate the revisions we will make.

read point-by-point responses

Referee: [argument following the specific cases (i)-(iv)] The assertion that 'through suitably chosen couplings, essentially arbitrary Lanczos coefficients can be obtained' (abstract and concluding discussion) is presented as a general claim but rests only on the explicit derivations for specific analytic hybridization functions at T=0. No general construction or proof is given showing that any prescribed sequence is achievable, nor is it demonstrated that the same freedom persists for non-analytic couplings or at finite temperature. This gap directly affects the strength of the inadequacy conclusion for the classification criterion.

Authors: We agree that the manuscript presents explicit analytic derivations only for four specific hybridization functions at zero temperature and does not contain a general proof or construction that any arbitrary sequence of Lanczos coefficients can be realized for arbitrary (including non-analytic) couplings or at finite temperature. The argument in the paper is that the choice of hybridization function provides sufficient freedom to realize qualitatively different growth patterns, as concretely shown by cases (i)-(iv). We will revise the abstract and concluding discussion to clarify that the claim of 'essentially arbitrary' Lanczos coefficients is an argument based on the demonstrated flexibility in the model rather than a general theorem. This revision will preserve the central point that different Lanczos growth behaviors occur within the same quadratic model. revision: yes
Referee: [wide-band limit section] The wide-band limit analysis shows exponential autocorrelation decay for the four explicit cases (i)-(iv), but does not address whether the same decay persists for the broader class of 'arbitrary' couplings invoked in the central claim. If certain couplings yielding exotic Lanczos sequences produce non-exponential decay, the demonstration that Lanczos structure is uncorrelated with physical behavior would be incomplete.

Authors: We acknowledge that the wide-band limit analysis and the observation of exponential autocorrelation decay are restricted to the four explicit cases (i)-(iv). In a quadratic model the autocorrelation function is the Fourier transform of the hybridization spectral function; for the smooth, gapped or gapless continua considered, this yields exponential decay. We have not verified the decay for every conceivable exotic coupling that might produce other Lanczos sequences. We will add a short clarifying paragraph in the wide-band limit section noting the scope of the explicit calculations and stating that the demonstrated cases already suffice to show that distinct Lanczos growth structures can share the same physical signature of exponential decay. If the editor prefers, we can further qualify the central claim to apply specifically to the couplings for which both Lanczos coefficients and autocorrelations have been computed. revision: partial

Circularity Check

0 steps flagged

No circularity: direct analytic derivations from external hybridization input

full rationale

The paper performs explicit analytic derivations of Lanczos coefficients from the quadratic resonant-level Hamiltonian for specific chosen coupling structures at zero temperature. The claim that essentially arbitrary sequences are obtainable follows from the freedom to select the hybridization function as an independent external input to the model, rather than any self-referential fitting, redefinition, or load-bearing self-citation. No step reduces by construction to its own outputs; the derivations remain self-contained against the model's parameters and do not invoke uniqueness theorems or ansatzes from prior author work.

Axiom & Free-Parameter Ledger

0 free parameters · 2 axioms · 0 invented entities

The derivations rely on standard fermionic anticommutation relations and the definition of the Lanczos algorithm; no new entities are introduced and no parameters are fitted to data.

axioms (2)

standard math Fermionic operators satisfy canonical anticommutation relations {c_i, c_j^dagger} = delta_ij
Invoked implicitly when defining Majorana operators and the quadratic Hamiltonian.
domain assumption The hybridization function is chosen such that the resulting continued-fraction or moment expressions close analytically
Required for the closed-form Lanczos coefficients stated in the abstract.

pith-pipeline@v0.9.0 · 5507 in / 1461 out tokens · 41569 ms · 2026-05-16T12:53:36.510465+00:00 · methodology

discussion (0)

Forward citations

Cited by 1 Pith paper

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Long-Range Pairing in the Kitaev Model: Krylov Subspace Signatures
quant-ph 2026-02 unverdicted novelty 7.0

A Krylov staggering parameter derived from Lanczos coefficients analytically distinguishes topological phases in the short-range Kitaev model and tracks boundary versus bulk control of the gap in long-range cases.

Reference graph

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