REVIEW 2 major objections 1 minor 1 cited by
A definition of nonnegative scalar curvature for merely continuous three-dimensional metrics is given by requiring monotonicity of the Hawking mass along the inverse mean curvature flow.
Reviewed by Pith at T0; open to challenge. T0 means a machine referee read the full paper against a public rubric. the ladder, T0–T4 →
T0 review · grok-4.3
2026-06-30 17:57 UTC pith:VDGJFEQD
load-bearing objection Defines nonnegative scalar curvature for C^0 metrics via Hawking mass monotonicity under IMCF and gives a stability theorem, but the weak flow setup for continuous data needs checking. the 2 major comments →
Scalar curvature bounds for 3D continuous metrics through the Inverse Mean Curvature Flow
The pith
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
We propose a notion of scalar curvature lower bounds in a three-dimensional Riemannian manifold endowed with a C^0 metric based on the monotonicity of the Hawking mass along the inverse mean curvature flow. We present a stability theorem for continuous Riemannian metrics with nonnegative scalar curvature in such IMCF sense.
What carries the argument
Monotonicity of the Hawking mass along the inverse mean curvature flow, which is taken to encode the scalar curvature lower bound for the C^0 metric.
Load-bearing premise
The inverse mean curvature flow and the Hawking mass can be meaningfully defined and their monotonicity imposed on metrics that are only continuous.
What would settle it
Construct a C^0 metric on a compact three-manifold such that the Hawking mass decreases along an inverse mean curvature flow starting from some surface, yet the metric is a smooth limit of metrics with nonnegative scalar curvature.
If this is right
- Continuous metrics satisfying the IMCF monotonicity condition are stable with respect to suitable convergence to smooth metrics with nonnegative scalar curvature.
- Results that previously required smooth metrics with nonnegative scalar curvature can now be stated for a larger class of merely continuous metrics.
- The definition provides a way to pass curvature bounds to limits of smooth metrics that converge only in C^0.
Where Pith is reading between the lines
- The same monotonicity condition might serve as a curvature bound in other geometric flows or in the presence of singularities.
- One could test whether the stability theorem extends to noncompact manifolds or to metrics with additional symmetry assumptions.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript proposes a notion of lower bounds on scalar curvature for C^0 Riemannian metrics on 3-manifolds, defined by requiring monotonicity of the Hawking mass along the inverse mean curvature flow (IMCF). It then states a stability theorem for metrics satisfying nonnegative scalar curvature in this IMCF sense.
Significance. If the weak IMCF and associated monotonicity can be made rigorous for C^0 data, the definition would supply a natural extension of scalar-curvature conditions to low-regularity metrics, with potential utility in geometric analysis and general relativity. The stability result, if established, would give a robustness statement for the proposed notion.
major comments (2)
- [Definition of the IMCF notion (Introduction and §2)] The precise weak formulation of IMCF (level-set, viscosity, or varifold) and the existence/uniqueness result invoked for merely C^0 initial data are not specified. This is load-bearing for both the definition of nonnegative scalar curvature and the stability theorem, as the Hawking mass monotonicity cannot be imposed without a well-defined flow.
- [Stability theorem (main result section)] The stability theorem assumes that monotonicity of the Hawking mass along the flow implies the curvature bound, but without a rigorous justification that the Hawking mass remains well-defined and the monotonicity condition is meaningful for C^0 metrics, the implication rests on an unverified extension of classical IMCF theory.
minor comments (1)
- Notation for the weak Hawking mass and the precise statement of monotonicity should be clarified with explicit formulas or references to the relevant weak quantities.
Simulated Author's Rebuttal
We are grateful to the referee for the insightful comments which help improve the clarity of the manuscript. We address each major comment below.
read point-by-point responses
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Referee: [Definition of the IMCF notion (Introduction and §2)] The precise weak formulation of IMCF (level-set, viscosity, or varifold) and the existence/uniqueness result invoked for merely C^0 initial data are not specified. This is load-bearing for both the definition of nonnegative scalar curvature and the stability theorem, as the Hawking mass monotonicity cannot be imposed without a well-defined flow.
Authors: We use the level-set formulation of the weak IMCF as introduced by Huisken and Ilmanen. For C^0 metrics, the existence and uniqueness of the flow follow from the theory developed for Lipschitz or continuous data in the literature on weak mean curvature flows. We will revise the introduction and Section 2 to explicitly cite the precise formulation and the relevant existence theorem for C^0 initial hypersurfaces. revision: yes
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Referee: [Stability theorem (main result section)] The stability theorem assumes that monotonicity of the Hawking mass along the flow implies the curvature bound, but without a rigorous justification that the Hawking mass remains well-defined and the monotonicity condition is meaningful for C^0 metrics, the implication rests on an unverified extension of classical IMCF theory.
Authors: The Hawking mass for the evolving surfaces in the weak flow is defined using the area and the integral of the mean curvature, which remain meaningful for the C^0 metric as the flow is constructed to have the necessary regularity. The monotonicity is imposed by definition for the notion of nonnegative scalar curvature. For the stability, it follows from the fact that if the monotonicity holds, then by approximation or direct computation, the limit metric has nonnegative scalar curvature in the classical sense. We will add a paragraph in the main result section providing this justification and referencing the extension of the Hawking mass to weak flows. revision: yes
Circularity Check
No circularity: definition and stability rest on external IMCF theory
full rationale
The paper defines a notion of nonnegative scalar curvature for C^0 metrics via Hawking-mass monotonicity along IMCF and states a stability theorem in that sense. No quoted equations or steps reduce a claimed result to its inputs by construction, no fitted parameters are relabeled as predictions, and no load-bearing uniqueness theorem is imported solely via self-citation. The construction is explicitly novel for the C^0 setting but invokes classical IMCF results as independent support; the derivation chain therefore remains self-contained rather than tautological.
Axiom & Free-Parameter Ledger
read the original abstract
We propose a notion of scalar curvature lower bounds in a three-dimensional Riemannian manifold endowed with a $C^0$ metric based on the monotonicity of the Hawking mass along the inverse mean curvature flow. We present a stability theorem for continuous Riemannian metrics with nonnegative scalar curvature in such IMCF sense.
Forward citations
Cited by 1 Pith paper
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A Positive Mass Theorem for Continuous Metrics
Proves that the harmonic mass of a continuous asymptotically flat metric on R^3 is non-negative, with equality only when the metric is flat.
Reference graph
Works this paper leans on
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Quantification of scalar curvature under $C^0$ convergence using smoothing
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[2]
Quantification of $C^0$ Convergence in Dimension Three
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discussion (0)
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