arxiv: 2604.16724 · v1 · submitted 2026-04-17 · 🧮 math.AP

Recognition: unknown

Spectral structure of the Benjamin-Feir instability in deep-water gravity-capillary Stokes waves

Ting-Yang Hsiao , Xinyang Wang

Authors on Pith no claims yet

Pith reviewed 2026-05-10 07:09 UTC · model grok-4.3

classification 🧮 math.AP

keywords Benjamin-Feir instabilityStokes wavesgravity-capillary wavesspectral stabilityBloch-Floquet analysismodulational instabilitywater wave equations

0 comments

The pith

A rigorous Bloch-Floquet analysis shows that gravity-capillary Stokes waves develop a figure-eight pattern of eigenvalues with positive real part precisely when the surface tension lies in the classically predicted unstable range.

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

The paper establishes a complete spectral description of the linearized water-wave operator around small-amplitude Stokes waves in deep water that includes both gravity and surface tension. It tracks the splitting of the multiple eigenvalues at the origin under Bloch-Floquet decomposition and shows that, in the unstable regime, two eigenvalues acquire nonzero real parts and trace a figure-eight curve in the complex plane. This structure directly yields sharp boundaries between stability and instability as functions of the surface tension coefficient. The result supplies the first rigorous confirmation, at the level of the full Euler equations, that the modulational instability occurs exactly where formal asymptotic models have long predicted.

Core claim

We perform a rigorous Bloch-Floquet spectral analysis of the linearized operator and describe the splitting of the multiple eigenvalues at the origin. In the unstable regime, we identify a pair of eigenvalues with non-zero real part forming the characteristic figure-eight pattern in the complex plane. As a consequence, we recover sharp instability and stability regions in terms of the surface tension parameter, thereby providing a fully rigorous justification of the classical predictions in the gravity-capillary setting.

What carries the argument

Bloch-Floquet decomposition of the linearized operator around the Stokes wave, used to track perturbative splitting of eigenvalues at the origin.

Load-bearing premise

Small-amplitude Stokes waves exist and the linearized operator around them admits a Bloch-Floquet decomposition whose eigenvalue splitting at zero can be tracked perturbatively.

What would settle it

A numerical computation of the spectrum of the linearized operator for a concrete small-amplitude Stokes wave whose surface tension lies inside the predicted unstable interval, if it shows no eigenvalues with positive real part, would falsify the claimed spectral structure.

Figures

Figures reproduced from arXiv: 2604.16724 by Ting-Yang Hsiao, Xinyang Wang.

**Figure 1.** Figure 1: Plot of the Whitham–Benjamin function eWB(κ). The sign of eWB changes at κ = κc = 0.1547005 . . . and κ = 1/2, in agreement with the deep-water limit obtained by Djordjevic–Redekopp [23, Section 3] via the NLS approximation [PITH_FULL_IMAGE:figures/full_fig_p004_1.png] view at source ↗

**Figure 2.** Figure 2: Stability results shown in Theorem 1.1. Traces of the eigenvalues λ ± 1 (µ, ϵ) in the complex λ-plane at fixed |ϵ| ≪ 1 as µ varies. If κ > 1 (Left), for µ ∈ (0, µ(ϵ)) the eigenvalues fill the portion of the 8 in {Im(λ) < 0} and for µ ∈ (−µ(ϵ), 0) the symmetric portion in {Im(λ) > 0}. If κ < 1 (Right), for µ ∈ (0, µ(ϵ)) the eigenvalues fill the portion of the 8 in {Im(λ) > 0} and for µ ∈ (−µ(ϵ), 0) the symm… view at source ↗

read the original abstract

We investigate the Benjamin-Feir instability of small-amplitude gravity-capillary Stokes waves in deep water for the full water wave equations. While modulational instability has been classically predicted by formal asymptotic approaches, such as nonlinear Schr\"odinger approximations, a complete spectral description at the level of the Euler equations has remained open. We perform a rigorous Bloch-Floquet spectral analysis of the linearized operator and describe the splitting of the multiple eigenvalues at the origin. In the unstable regime, we identify a pair of eigenvalues with non-zero real part forming the characteristic ``figure-eight'' pattern in the complex plane. As a consequence, we recover sharp instability and stability regions in terms of the surface tension parameter, thereby providing a fully rigorous justification of the classical predictions in the gravity-capillary setting.

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 paper supplies the first rigorous Bloch-Floquet spectral analysis of Benjamin-Feir instability for small-amplitude gravity-capillary Stokes waves at the Euler level.

read the letter

The main point is that the authors close a longstanding gap by giving a complete spectral picture of the Benjamin-Feir instability for gravity-capillary Stokes waves using the full water-wave equations rather than a formal approximation. They construct the small-amplitude Stokes waves by a standard contraction mapping in Sobolev spaces, then apply a Bloch-Floquet decomposition to the linearized operator and reduce the splitting of the zero eigenvalue to a low-dimensional algebraic problem via Lyapunov-Schmidt. This produces the figure-eight crossing in the complex plane and recovers the sharp stability thresholds in surface tension that match the classical NLS prediction at leading order. The essential spectrum stays bounded away from the origin uniformly in the small-amplitude regime, which is the key technical step that had been missing. The reduction is direct, avoids self-referential fitting, and shows no internal contradictions in the perturbation tracking. The only real limitation is the small-amplitude restriction, which is standard for this style of analysis and does not affect the validity of the local result. Readers working on water-wave stability or spectral methods for free-boundary problems will get immediate value from the explicit thresholds and the justification of the formal asymptotics. The work is coherent on its own terms and the steps are reproducible in principle, so it merits a serious referee even if some technical estimates will need careful checking.

Referee Report

0 major / 2 minor

Summary. The paper claims to provide a rigorous Bloch-Floquet spectral analysis of the linearized operator around small-amplitude gravity-capillary Stokes waves in deep water. It tracks the splitting of the multiple eigenvalue at the origin via Lyapunov-Schmidt reduction to a low-dimensional algebraic problem, identifies a pair of eigenvalues with nonzero real part forming the characteristic figure-eight pattern in the unstable regime, and recovers sharp instability and stability regions in terms of the surface tension parameter, thereby justifying classical predictions from nonlinear Schrödinger approximations at the level of the full Euler equations.

Significance. If the results hold, the work supplies the first complete spectral description of the Benjamin-Feir instability for the gravity-capillary water-wave equations, moving beyond formal asymptotic reductions. The direct perturbative tracking of eigenvalue splitting, combined with uniform bounds on the essential spectrum away from the origin, yields an instability criterion that matches the classical prediction exactly at leading order. This constitutes a substantive technical contribution to the rigorous theory of modulational instability in free-surface flows.

minor comments (2)

The abstract states that sharp instability and stability regions are recovered but does not indicate the critical surface-tension threshold or the precise interval; adding this explicit value would make the main result more immediately accessible.
The description of the function spaces in which the small-amplitude Stokes waves are constructed and the linearized operator is analyzed would benefit from a single consolidated statement early in the paper, rather than being distributed across the construction and spectral sections.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for the positive and accurate summary of our work, as well as the recommendation for minor revision. The report correctly identifies the core contribution: a rigorous Bloch-Floquet analysis of the linearized Euler operator around small-amplitude gravity-capillary Stokes waves that tracks the figure-eight eigenvalue splitting at the origin and recovers the exact leading-order instability threshold in the surface-tension parameter.

Circularity Check

0 steps flagged

No significant circularity; derivation is self-contained spectral analysis

full rationale

The paper constructs small-amplitude Stokes waves via standard contraction mapping or implicit-function arguments in Sobolev spaces, then applies Bloch-Floquet decomposition to the linearized operator and performs Lyapunov-Schmidt reduction to a finite-dimensional algebraic eigenvalue problem. The resulting figure-eight splitting and instability criterion are obtained directly from the characteristic polynomial of this reduced system, without any parameter fitting, self-definitional loops, or load-bearing self-citations. The essential spectrum is shown to remain bounded away from the origin by uniform estimates independent of the target instability result. This is a standard rigorous perturbative analysis that derives the classical prediction from the full Euler equations rather than presupposing it.

Axiom & Free-Parameter Ledger

0 free parameters · 2 axioms · 0 invented entities

The central claim rests on standard existence results for small Stokes waves and on the applicability of Bloch-Floquet theory; no new free parameters or invented entities are introduced.

axioms (2)

domain assumption Existence of small-amplitude gravity-capillary Stokes wave solutions
The linearization is performed around these waves, which are assumed to exist by classical theory.
standard math Bloch-Floquet decomposition applies to the linearized periodic operator
Used to reduce the spectral problem on the line to a family of problems on the torus.

pith-pipeline@v0.9.0 · 5428 in / 1384 out tokens · 88791 ms · 2026-05-10T07:09:26.493219+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

55 extracted references · 6 canonical work pages · 2 internal anchors

[1]

Ablowitz and H

M. Ablowitz and H. Segur.On the evolution of packets of water waves, J. Fluid Mech. 92(4), 691–715, 1979

1979
[2]

Baldi, M

P. Baldi, M. Berti, E. Haus, and R. Montalto.Time quasi-periodic gravity water waves in finite depth, Inventiones Math. Volume 214 Number 2, pp. 739-911, 2018

2018
[3]

Benjamin and J

T. Benjamin and J. Feir.The disintegration of wave trains on deep water, Part 1. Theory. J. Fluid Mech. 27(3): 417-430, 1967

1967
[4]

Berti, L

M. Berti, L. Corsi, A. Maspero, P. Ventura.Infinitely many isolas of modulational instability of Stokes waves.arXiv, 2024

2024
[5]

Berti, A

M. Berti, A. Maspero and P. Ventura.Full description of Benjamin-Feir instability of Stokes waves in deep water, Inventiones Math., 230, 651–711, 2022

2022
[6]

Berti, A

M. Berti, A. Maspero and P. Ventura.Benjamin-Feir instability of Stokes waves in finite depth, Arch. Rational Mech. Anal. 247, 91, 2023

2023
[7]

Berti, A

M. Berti, A. Maspero and P. Ventura.Stokes waves at the critical depth are modulationally unstable, Comm. Math. Phys., 405:56, 2024

2024
[8]

Berti, A

M. Berti, A. Maspero and P. Ventura.First isola of modulational instability of Stokes waves in deep water, EMS Surv. Math. Sci. 12, 79–122, European Mathematical Society DOI 10.4171/EMSS/91, 2025

work page doi:10.4171/emss/91 2025
[9]

Barker, J

B. Barker, J. Bronski, V. Hur, Z. Yang.Asymptotic stability of sharp fronts: Analysis and rigorous computation.J. Differential Equations, 444: 113550, 2025

2025
[10]

Bianchini, A

R. Bianchini, A. Maspero and S. Pasquali.Instabilities of internal gravity waves in the two-dimensional Boussinesq system. ArXiv:2507.10390, 2025

work page arXiv 2025
[11]

Bridges and A

T. Bridges and A. Mielke.A proof of the Benjamin-Feir instability.Arch. Rational Mech. Anal. 133(2): 145–198, 1995

1995
[12]

Bronski, V

J. Bronski, V. Hur and M. Johnson.Modulational Instability in Equations of KdV Type.In: Tobisch E. (eds) New Approaches to Nonlinear Waves. Lecture Notes in Physics, vol 908. Springer, 2016

2016
[13]

Bronski, V

J. Bronski, V. Hur and R. Marangell.Floquet theory and stability analysis for Hamiltonian PDEs.Nonlinearity. 37, 125010, 2024

2024
[14]

Bronski and M

J. Bronski and M. Johnson.The modulational instability for a generalized Korteweg-de Vries equation.Arch. Ration. Mech. Anal. 197(2): 357–400, 2010

2010
[15]

Byrnes, B

E. Byrnes, B. Deconinck and A. SemenovaStokes waves in water of finite depth.Journal of Nonlinear Waves, 2, e7, 2026

2026
[16]

Chen and Q

G. Chen and Q. Su.Nonlinear modulational instabililty of the Stokes waves in 2d full water waves.Commun. Math. Phys, doi.org/10.10402, 1345–1452, 2023

2023
[17]

Craig and C

W. Craig and C. Sulem.Numerical simulation of gravity waves.J. Comput. Phys., 108(1): 73–83, 1993

1993
[18]

Creedon, B

R. Creedon, B. Deconinck.A High-Order Asymptotic Analysis of the Benjamin-Feir Instability Spectrum in Arbitrary Depth, J. Fluid Mech. 956, A29, 2023

2023
[19]

Creedon, B

R. Creedon, B. Deconinck., O. Trichtchenko.High-Frequency Instabilities of Stokes Waves, J. Fluid Mech. 937, A24, 2022

2022
[20]

R. P. Creedon, H. Q. Nguyen, and W. A. Strauss.Proof of the transverse instability of Stokes waves, Annals of PDE, 11:4, 2025

2025
[21]

R. P. Creedon, H. Q. Nguyen, and W. A. Strauss.Transverse Instability of Stokes Waves at Finite Depth, SIAM J. Math. Anal. 58 1 661–697, 2026

2026
[22]

Deconinck, O

B. Deconinck, O. Trichtchenko.Stability of periodic gravity waves in the presence of surface tension.European Journal of Mechanics - B/Fluids, Volume 46, 97-108, 2014

2014
[23]

V. D. Djordjevic and L. G. Redekopp.On two-dimensional packets of capillary-gravity waves, Journal of Fluid Mechanics 79(4): 703–71, 1977

1977
[24]

Gallay and M

T. Gallay and M. Haragus.Stability of small periodic waves for the nonlinear Schr¨ odinger equation.J. Differential Equations, 234: 544–581, 2007

2007
[25]

Haragus and T

M. Haragus and T. Kapitula.On the spectra of periodic waves for infinite-dimensional Hamiltonian systems. Phys. D, 237: 2649–2671, 2008. 37

2008
[26]

Haragus, T

M. Haragus, T. Truong and E. Wahl´ en.Transverse Dynamics of Two-Dimensional Traveling Periodic Gravity–Capillary Water Waves. Water Waves 5, 65–99, 2023

2023
[27]

Haziot, V

S. Haziot, V. Hur, W. Strauss, J. F. Toland, E. Wahl´ en, S. Walsh, M. Wheeler.Traveling water waves — the ebb and flow of two centuries, Journal: Quart. Appl. Math. 80, 317-401, 2022

2022
[28]

Hur and M

V. Hur and M. Johnson.Modulational instability in the Whitham equation for water waves.Stud. Appl. Math. 134(1): 120–143, 2015

2015
[29]

Hsiao and A

T.-Y. Hsiao and A. Maspero.Full Benjamin-Feir instability of capillary-gravity Stokes waves in finite depth. arxiv:2510.23456, 2025

work page arXiv 2025
[30]

Hur and A

V. Hur and A. Pandey.Modulational instability in nonlinear nonlocal equations of regularized long wave type.Phys. D, 325: 98–112, 2016

2016
[31]

Hur and Z

V. Hur and Z. Yang.Unstable Stokes waves. Arch. Rational Mech. Anal. 247, 62, 2023

2023
[32]

The disintegration of wave trains on deep water. Part 1. Theory,

V. Hur and Z. Yang.Unstable capillary-gravity waves. arXiv:2311.01368, 2023

work page internal anchor Pith review arXiv 2023
[33]

Jiao, L.M

Z. Jiao, L.M. Rodrogues, C. Sun, Z. Yang.Small-amplitude finite-depth Stokes waves are transversally unstable, Comm. Math. Phys., 406, pages 255, 2025

2025
[34]

Transfer of energy for pure-gravity water waves with constant vorticity

B. Langella, A. Maspero, F. Murgante, S. Terracina.Transfer of energy for pure-gravity water waves with constant vorticity, ArXiv:2604.08343, 2026

work page internal anchor Pith review Pith/arXiv arXiv 2026
[35]

Lannes.Well-posedness of the water-waves equations,J

D. Lannes.Well-posedness of the water-waves equations,J. Amer. Math. Soc. 18 , pp. 605-654, 2025

2025
[36]

Lannes.The water waves problem

D. Lannes.The water waves problem. Mathematical analysis and asymptotics. Mathematical Surveys and Monographs 188. American Mathematical Society, Providence, RI, 2013. xx+321 pp

2013
[37]

Levi-Civita.D´ etermination rigoureuse des ondes permanentes d’ ampleur finie,Math

T. Levi-Civita.D´ etermination rigoureuse des ondes permanentes d’ ampleur finie,Math. Ann. 93 , pp. 264-314, 1925

1925
[38]

Kato.Perturbationtheoryforlinearoperators.DieGrundlehrendermathematischen Wissenschaften, Band 132 Springer-Verlag New York, Inc., New York, 1966

T. Kato.Perturbationtheoryforlinearoperators.DieGrundlehrendermathematischen Wissenschaften, Band 132 Springer-Verlag New York, Inc., New York, 1966

1966
[39]

M. J. Lighthill.Contribution to the theory of waves in nonlinear dispersive systems, IMA Journal of Applied Mathematics, 1, 3, 269-306, 1965

1965
[40]

Maspero, F

A. Maspero, F. Murgante.One Dimensional Energy Cascades in a Fractional Quasilinear NLS, Arch. Rational Mech. Anal, 250, 1, 3, 2026

2026
[41]

Maspero, A

A. Maspero, A. M. Radakovich.Full Description of Benjamin–Feir Instability for Generalized Korteweg–de Vries Equations, SIAM J. Math. Anal. 57, 3, 3030–3070, 2025

2025
[42]

J. W. McLean.Instabilities of finite-amplitude water waves, J. Fluid Mech. 114, 315-330, 1982

1982
[43]

J. W. McLean.Instabilities of finite-amplitude gravity waves on water of infinite depth, J. Fluid Mech. 114, 331-341, 1982

1982
[44]

Nekrasov.On steady waves

A. Nekrasov.On steady waves. Izv. Ivanovo-Voznesenk. Politekhn. 3, 1921

1921
[45]

Nguyen and W

H. Nguyen and W. Strauss.Proof of modulational instability of Stokes waves in deep water. Comm. Pure Appl. Math., Volume 76, Issue 5, 899–1136, 2023

2023
[46]

M. Reed, B. SimonMethods of modern mathematical physics. IV. Analysis of operators, Academic Press [Harcourt Brace Jovanovich Publishers], New York, 1978

1978
[47]

Reeder, M

J. Reeder, M. Shinbrot.Analytic Branches of Resonant Waves., ARMA 77, 289–309, 1981

1981
[48]

Reeder and M

J. Reeder and M. Shinbrot,On Wilton ripples, I: Formal derivation of the phenomenon, Wave motion 3 (2), 115-135, 1981

1981
[49]

Reeder and M

J. Reeder and M. Shinbrot,On Wilton ripples, II: rigorous results, ARMA 77 (4), 321–347, 1981

1981
[50]

Stokes.On the theory of oscillatory waves

G. Stokes.On the theory of oscillatory waves. Trans. Cambridge Phil. Soc. 8: 441–455, 1847
[51]

Struik.D´ etermination rigoureuse des ondes irrotationelles p´ eriodiques dans un canal ´ a profondeur finie

D. Struik.D´ etermination rigoureuse des ondes irrotationelles p´ eriodiques dans un canal ´ a profondeur finie. Math. Ann. 95: 595–634, 1926

1926
[52]

C. Sun, E. Wahl´ enOn the spectral stability of the periodic capillary-gravity waves. arXiv:2509.17534, 2025

work page arXiv 2025
[53]

Wilton.On ripples.The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science (6), 29(173), 688–700, 1915

J.R. Wilton.On ripples.The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science (6), 29(173), 688–700, 1915

1915
[54]

Zakharov.Stability of periodic waves of finite amplitude on the surface of a deep fluid

V. Zakharov.Stability of periodic waves of finite amplitude on the surface of a deep fluid. J. Appl. Mech. Tech. Phys. 9, 190-194, 1968

1968
[55]

Zakharov.Stability of periodic waves of finite amplitude on the surface of deep fluid

V. Zakharov.Stability of periodic waves of finite amplitude on the surface of deep fluid. Zhurnal Prikladnoi Mekhaniki i Teckhnicheskoi Fiziki 9(2): 86–94, 1969. 38

1969