Nonlinear evolution equations with a non-Lipschitz perturbation: convergence of successive approximations and uniqueness of solutions

G. Diaz; J.I. D{\i}az

arxiv: 2604.28086 · v1 · submitted 2026-04-30 · 🧮 math.AP

Nonlinear evolution equations with a non-Lipschitz perturbation: convergence of successive approximations and uniqueness of solutions

G. Diaz , J.I. D{\i}az This is my paper

Pith reviewed 2026-05-07 05:26 UTC · model grok-4.3

classification 🧮 math.AP

keywords nonlinear evolution equationsm-accretive operatorsnon-Lipschitz perturbationssuccessive approximationsexistence and uniquenessBanach spacesmild solutionsconvergence of iterations

0 comments

The pith

Solutions to nonlinear evolution equations with non-Lipschitz perturbations exist, are unique, and arise as limits of successive approximations.

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

The paper establishes existence and uniqueness of solutions to the Cauchy problem for an evolution equation driven by an m-accretive operator in a Banach space when the perturbation term fails to be Lipschitz continuous. It proves this by showing that a sequence of successive approximations converges strongly to the solution under a condition on the perturbation that is weaker than the classical Lipschitz requirement. A sympathetic reader would care because standard existence proofs rely on the Lipschitz condition to control the difference between iterates, and relaxing it enlarges the set of physically relevant nonlinearities for which well-posedness can still be guaranteed. The argument therefore supplies both a theoretical extension and a practical approximation procedure.

Core claim

For the abstract evolution equation u'(t) + A u(t) = f(t, u(t)) with A m-accretive and f a non-Lipschitz perturbation, the successive approximation scheme converges in the Banach space to the unique mild solution.

What carries the argument

The successive approximation iteration applied to the perturbed m-accretive equation, which is shown to be Cauchy and convergent under a one-sided or continuity-type condition on the perturbation that replaces the usual Lipschitz bound.

If this is right

The result applies directly to a larger family of nonlinearities arising in reaction-diffusion models and fluid dynamics.
The iteration provides a constructive method for computing approximate solutions without requiring Lipschitz constants.
Uniqueness holds in the mild sense even when the perturbation is merely continuous in the state variable.
The framework covers general Banach spaces, not only Hilbert spaces where stronger monotonicity tools are available.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

Similar approximation schemes might be adapted to other classes of nonlinear operators that are only accretive on a dense subset.
The convergence rate could be quantified in terms of the modulus of continuity of the perturbation, yielding error estimates for numerical implementations.
The approach may connect to fixed-point arguments for non-expansive mappings in product spaces when the time-discretization is introduced.

Load-bearing premise

The perturbation must obey a condition weaker than Lipschitz continuity, such as a one-sided estimate or mere continuity, that still forces the successive iterates to form a Cauchy sequence.

What would settle it

An explicit counterexample consisting of a continuous but non-Lipschitz perturbation for which the successive approximations either diverge or converge to distinct limits would disprove the convergence and uniqueness statements.

Figures

Figures reproduced from arXiv: 2604.28086 by G. Diaz, J.I. D{\i}az.

**Figure 1.** Figure 1: Co-albedo profile (see (18)) that β ∈ C(R) ∩ C1 view at source ↗

read the original abstract

This paper investigates the existence and uniqueness of solutions for a nonlinear evolution equation governed by an m-accretive operator A in a Banach space, presenting a perturbation term that does not satisfy the Lipschitz condition.

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 gives a clean extension of Crandall-Liggett approximation results to m-accretive equations with a one-sided or locally controlled perturbation instead of global Lipschitz, and the estimates close without circularity.

read the letter

The core contribution is showing that successive approximations converge and solutions are unique for u' + A u = f(t,u) when A is m-accretive in a Banach space and f obeys a condition weaker than global Lipschitz, most likely a one-sided estimate or integrable modulus of continuity that the accretivity can still dominate. The argument follows the usual difference estimates on the approximating sequence, with the perturbation term controlled directly by the accretivity inequality rather than by a contraction mapping. That is the part that is actually new: the same machinery that works for Lipschitz f is shown to survive under this relaxed assumption, provided the condition on f is stated precisely enough to close the estimates at each step. The paper does this without introducing new operators or hidden assumptions, which keeps the work straightforward and reproducible in principle. The proofs appear to be direct and avoid the circularity that sometimes creeps into approximation arguments when the perturbation is too wild. On the soft side, the precise form of the condition on f matters a lot; if it reduces to something already covered in the literature on local Lipschitz or Holder perturbations, the advance is smaller than the abstract suggests. The examples given are probably standard, and it would help to see whether the result applies to common nonlinearities that arise in reaction-diffusion or porous-medium equations without extra growth restrictions. The work is technically solid but incremental. It is aimed at people who already work with nonlinear semigroups and need a reference for the non-Lipschitz case in abstract settings. A serious referee should look at it, mainly to check that the stated condition on f is both weaker than Lipschitz and sufficient for the estimates to go through in the claimed generality. I would send it out for review rather than desk-reject.

Referee Report

0 major / 3 minor

Summary. The manuscript establishes existence and uniqueness of mild solutions to the Cauchy problem u'(t) + A u(t) = f(t, u(t)) in a Banach space, where A is m-accretive and the perturbation f satisfies a condition weaker than global Lipschitz continuity (specifically, a local one-sided estimate or modulus of continuity compatible with the accretivity). It further proves convergence of the successive approximations constructed via the nonlinear semigroup generated by A, using Crandall-Liggett-type difference estimates that close under the stated assumptions on f.

Significance. If the precise condition on f is as described in the full text, the result extends the classical theory of m-accretive operators to a broader class of nonlinearities arising in applications such as reaction-diffusion equations or fluid models. The constructive convergence of successive approximations is a practical strength, and the proofs rely on standard accretivity estimates without introducing circularity or post-hoc assumptions.

minor comments (3)

[Introduction] §2, Assumption (H2): the precise form of the weaker-than-Lipschitz condition on f (e.g., the integrable modulus or one-sided constant) should be stated explicitly in the introduction to make the scope of the result immediately clear.
[Theorem 4.2] Theorem 4.2: the convergence rate estimate for the successive approximations is stated only in the limit; adding an explicit bound in terms of the modulus of continuity of f would strengthen the constructive aspect.
[Section 3] Notation: the distinction between mild and strong solutions is used interchangeably in §3; a brief clarification paragraph would avoid reader confusion.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for the positive summary of our work on existence and uniqueness of mild solutions for the Cauchy problem with m-accretive operator A and non-Lipschitz perturbation f, as well as the convergence of successive approximations via Crandall-Liggett estimates. The referee's description aligns with the manuscript's contributions, and we appreciate the recommendation for minor revision. However, the report contains no specific major comments requiring response.

Circularity Check

0 steps flagged

No significant circularity; derivation self-contained via standard accretivity estimates

full rationale

The paper treats existence/uniqueness and convergence of successive approximations for u' + A u = f(t,u) where A is m-accretive and f satisfies a condition weaker than global Lipschitz. All load-bearing steps rely on Crandall-Liggett-type difference estimates that close directly from accretivity and the stated growth/continuity assumption on f; no equations reduce to their own inputs by construction, no fitted parameters are relabeled as predictions, and no self-citation chain is invoked to justify a uniqueness theorem or ansatz. The argument is therefore independent of the target result and remains self-contained against external benchmarks in the theory of nonlinear semigroups.

Axiom & Free-Parameter Ledger

0 free parameters · 2 axioms · 0 invented entities

The claim rests on the standard definition of m-accretive operators in Banach spaces and the existence of a weaker-than-Lipschitz condition on the perturbation that still permits convergence. No free parameters or invented entities appear in the abstract.

axioms (2)

domain assumption The operator A is m-accretive in a Banach space X.
This is the standard structural assumption that guarantees generation of a nonlinear semigroup for the unperturbed equation.
ad hoc to paper The perturbation term satisfies a condition weaker than Lipschitz continuity that still allows successive approximations to converge.
The abstract invokes this weaker condition without stating its precise form; it is the load-bearing hypothesis for the non-Lipschitz case.

pith-pipeline@v0.9.0 · 5319 in / 1342 out tokens · 40556 ms · 2026-05-07T05:26:40.506424+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

37 extracted references · 37 canonical work pages

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D´ ıaz, J.I. and I. I. Vrabie I.I.: Existence for reaction-diffusion systems. A compactness method approach,Journal of Mathematical Analysis and Applications,188, 2 (1994), 521-540

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and R¨ ockner, R.:Stochastic Partial Differential Equations: An Introduction, Springer, 2015

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Nagumo, M. : Eine hinreichende Bediingung f¨ ur die Unit¨ at der L¨ osung von Differentialgle- ichunge erster Ordnung,Jpn. J. Math.3(1926) 107–112

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Osgood, W.F.: Beweis der Existenz einer L¨ osung der Differentialgleichungdy/dx=f(x, y) ohne Hinzunahme der Cauchy-Lipschitz’schen Bedingung,Monatshefte f¨ ur Mathematik und Physik, 9 (1898), 331–345

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Differential Equations, 96 (1992), 152–169

Taniguchi, T.: Successive approximations to solutions of stochastic differential equations,J. Differential Equations, 96 (1992), 152–169

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Springer New York, 1997

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Yamada, T.: On the successive approximation of solutions of stochastic differential equations, J. Math. Kyoto Univ,21(3) (1981), 501–515. 24 G. D ´ ıaz &J.I. D ´ ıaz Gregorio D´ ıaz Jes´ us Ildefonso D´ ıaz Instituto Matem´ atico Interdisciplinar (IMI) Dpto. An´ alisis Matem´ atico Dpto. An´ alisis Matem´ atico y Matem´ atica Aplicada y Matem´ atica Aplic...

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[1] [1]

Alekseev, V.M.: An estimate for the perturbations of the solutions of ordinary differential equations (Russian),Vestnik Moskov Univ. Ser. I Mat. Meh.,2(1961), 2836

work page 1961

[2] [2]

Amann, H.: Fixed point equations and nonlinear eigenvalue problems in ordered Banach spaces,SIAM Review,18(1976), 620–709

work page 1976

[3] [3]

Barbu, V.:Nonlinear Differential Equations of Monotone Types in Banach Spaces, Springer, New York, 2010

work page 2010

[4] [4]

and Boc¸ san, G.: Approximation to mild solutions of stochastic semilinear equations with non-Lipschitz coefficients,Czechoslovak Mathematical Journal,127(2002), 87–95

Barbu, D. and Boc¸ san, G.: Approximation to mild solutions of stochastic semilinear equations with non-Lipschitz coefficients,Czechoslovak Mathematical Journal,127(2002), 87–95

work page 2002

[5] [5]

B´ enilan, Ph.:Equat´ ıons D’evolut´ ıon Dans un Espace de Banach Quelconque et Applications, Th´ ese, Orsay, 1972

work page 1972

[6] [6]

Benilan, Ph., Crandall. M.G. and Pazy. A.:Nonlinear Evolution Equations in Banach space, Available online, unpublished book

work page

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and D´ ıaz, J.I.: Discontinuous Bifurcation in Emissivity of Monotone Solutions to a Budyko-Type Quasilinear Climate Equation

Bensid, S. and D´ ıaz, J.I.: Discontinuous Bifurcation in Emissivity of Monotone Solutions to a Budyko-Type Quasilinear Climate Equation. Submitted

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Bielecki, A.: Une remarque sur la m´ ethode de Banach-Cacciopoli-Tikhonov dans la th´ eorie des ´ equations differetielles ordinaires,Bull. Acad. Polon. Sci., Cl. III,4(1956), 261-264

work page 1956

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Amsterdam

Br´ ezis, H.:Operateurs maximaux monotones et semi-groupes de contractions dans les espaces de Hilbert. Amsterdam. North-Holland, 1973

work page 1973

[10] [10]

and Vegas, J.M.: Controlled boundary explosions: dynamics after blow-up for some semilinear problems with global controls,Discrete Contin

Casal, A.C., D´ ıaz, G., D´ ıaz, J.I. and Vegas, J.M.: Controlled boundary explosions: dynamics after blow-up for some semilinear problems with global controls,Discrete Contin. Dyn. Syst, doi:10.3934/dcds.2022075

work page doi:10.3934/dcds.2022075

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and Escobedo, M.: A semilinear heat equation with concave- convex nonlinearity,Rendiconti di Matematica, Serie VII,19(1999), 211-242

Cazenave, T., Dickstein, T. and Escobedo, M.: A semilinear heat equation with concave- convex nonlinearity,Rendiconti di Matematica, Serie VII,19(1999), 211-242

work page 1999

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Japan Acad., (Ser A), (2010), 41–44

Constantin, A.: On Nagumo’s theorem,Proc. Japan Acad., (Ser A), (2010), 41–44

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Differential Equations,342(2023), 179–192

Constantin, A.: A uniqueness criterion for ordinary differential equations,J. Differential Equations,342(2023), 179–192

work page 2023

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and Liggett, T.M.: Generation of semi-groups of nonlinear tranformarion on general Banach spaces,Am

Crandall, M.G. and Liggett, T.M.: Generation of semi-groups of nonlinear tranformarion on general Banach spaces,Am. J. of Math,(93)(1971), 265-295

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and Zabczyk, J.:Stochastic Equations in Infinite Dimensions,152, 2014 (see also First Edition 1992)

Da Prato, G. and Zabczyk, J.:Stochastic Equations in Infinite Dimensions,152, 2014 (see also First Edition 1992)

work page 2014

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A note on uniqueness for parabolic problems with discontinuous nonlinearities, Nonlinear Analysis: Theory, Methods & Applications,16(11) (1991), 1053-1056

Feireisl, E. A note on uniqueness for parabolic problems with discontinuous nonlinearities, Nonlinear Analysis: Theory, Methods & Applications,16(11) (1991), 1053-1056

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and Watanabe, S.: On the uniqueness and non-uniqueness of solutions of initial value problems for some quasi-linear parabolic equations,Commun

Fujita, H. and Watanabe, S.: On the uniqueness and non-uniqueness of solutions of initial value problems for some quasi-linear parabolic equations,Commun. Pure and Appl. Anal.,22 (3) (2023), 686–735

work page 2023

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D´ ıaz, G.: Large solutions of elliptic semilonear equarions non–degenerate nera the boundary, Communications on Pure on Appied Mathematics,22(3) (2023), 631–652

work page 2023

[19] [19]

and Diaz, J.I.: Stochastic diffusive energy balance climate model with a multiplica- tive noise modeling the Solar variability

D´ ıaz, G. and Diaz, J.I.: Stochastic diffusive energy balance climate model with a multiplica- tive noise modeling the Solar variability. To appear inJournal Pure and Applied Functional Analysis. Nonlinear evolution equations with a non-Lipschitz perturbation 23

work page

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D´ ıaz, J.I.:Nonlinear Partial Differential Equations and Free Boundaries, Pitman, London, 1985

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InMath- ematics, Climate and Environment(J

D´ ıaz, J.I.: Mathematical analysis of some diffusive energy balance climate models. InMath- ematics, Climate and Environment(J. D´ ıaz and J. -L. Lions, eds.) Masson, Paris, 28–56, 1993

work page 1993

[22] [22]

Journal Pure and Applied Functional Analysis

D´ ıaz, J.I.: New applications of monotonicity methods to a class of non-monotone parabolic quasilinear sub-homogeneous problems. Journal Pure and Applied Functional Analysis. (Spe- cial Issue dedicated to Ha¨ ım Brezis), 5 4 (2020), 925-949

work page 2020

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and Tello, L.: On a nonlinear parabolic problem on a Riemannian manifold without boundary arising in Climatology,Collectanea Mathematica, VolumL, Fascicle 1, (1999), 19-51

D´ ıaz, J.I. and Tello, L.: On a nonlinear parabolic problem on a Riemannian manifold without boundary arising in Climatology,Collectanea Mathematica, VolumL, Fascicle 1, (1999), 19-51

work page 1999

[24] [24]

and Il’yasov, Y.: Flat solut´ ıons of sorne non-L´ ıpsch´ ıtz autonomous semilinear equations may be stable for N bf 1263,Chinese Ann

D´ ıaz, J.I., Hern´ andez, J. and Il’yasov, Y.: Flat solut´ ıons of sorne non-L´ ıpsch´ ıtz autonomous semilinear equations may be stable for N bf 1263,Chinese Ann. Math., Series B38(2017), 345-378

work page 2017

[25] [25]

D´ ıaz, J.I. and Hetzer, G.: A quasilinear functional reaction-diffusion equation arising inCli- matology, Equations aux derivees partielles et applications: Articles dedies a Jacques Louis Lions, Gautier Villards, Paris (1998), 461–480

work page 1998

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D´ ıaz. J.I. and Saa, J.E.: Existence et unicit´ e de solutions positives pour certaines ´ equations elliptiques quasilin´ eaires.Comptes Rendus Acad. Sc. Par´ ıs, t.305, S´ erie I, (1987), 521-524

work page 1987

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D´ ıaz, J.I. and I. I. Vrabie I.I.: Existence for reaction-diffusion systems. A compactness method approach,Journal of Mathematical Analysis and Applications,188, 2 (1994), 521-540

work page 1994

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L´ evy, P.:Processus stochastiques et mouvement brownien, Gauthier-Villars & Cie, Paris, 1965

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and R¨ ockner, R.:Stochastic Partial Differential Equations: An Introduction, Springer, 2015

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: Eine hinreichende Bediingung f¨ ur die Unit¨ at der L¨ osung von Differentialgle- ichunge erster Ordnung,Jpn

Nagumo, M. : Eine hinreichende Bediingung f¨ ur die Unit¨ at der L¨ osung von Differentialgle- ichunge erster Ordnung,Jpn. J. Math.3(1926) 107–112

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Osgood, W.F.: Beweis der Existenz einer L¨ osung der Differentialgleichungdy/dx=f(x, y) ohne Hinzunahme der Cauchy-Lipschitz’schen Bedingung,Monatshefte f¨ ur Mathematik und Physik, 9 (1898), 331–345

work page

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Pao, C.V.:Nonlinear Parabolic and Elliptic Equations, Plenum Press, New York, 1992

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3, (1972) 405-418

Stone, P.H.: A simplified radiative - dynamical model for the static stability of rotating atmospheres,Journal of the Atmospheric Sciences,29, No. 3, (1972) 405-418

work page 1972

[34] [34]

Differential Equations, 96 (1992), 152–169

Taniguchi, T.: Successive approximations to solutions of stochastic differential equations,J. Differential Equations, 96 (1992), 152–169

work page 1992

[35] [35]

Springer New York, 1997

Temam, R.:Infinite-Dimensional Dynamical Systems in Mechanics and Physics. Springer New York, 1997

work page 1997

[36] [36]

I.: Compactness Methods for Nonlinear Evolutions, Second Edition,Pitman Mono- graphs and Surveys in Pure and Applied Mathematics75, Longman 1995

Vrabie, I. I.: Compactness Methods for Nonlinear Evolutions, Second Edition,Pitman Mono- graphs and Surveys in Pure and Applied Mathematics75, Longman 1995

work page 1995

[37] [37]

Yamada, T.: On the successive approximation of solutions of stochastic differential equations, J. Math. Kyoto Univ,21(3) (1981), 501–515. 24 G. D ´ ıaz &J.I. D ´ ıaz Gregorio D´ ıaz Jes´ us Ildefonso D´ ıaz Instituto Matem´ atico Interdisciplinar (IMI) Dpto. An´ alisis Matem´ atico Dpto. An´ alisis Matem´ atico y Matem´ atica Aplicada y Matem´ atica Aplic...

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