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1. Matrix Li–Yau–Hamilton estimates under Ricci flow and parabolic frequency

   https://doi.org/10.1007/s00526-024-02668-x  

   Li, Xiaolong; Zhang, Qi S. (February 2024, Calculus of Variations and Partial Differential Equations)

   Abstract We prove matrix Li–Yau–Hamilton estimates for positive solutions to the heat equation and the backward conjugate heat equation, both coupled with the Ricci flow. We then apply these estimates to establish the monotonicity of parabolic frequencies up to correction factors. As applications, we obtain some unique continuation results under the nonnegativity of sectional or complex sectional curvature. 

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2. Variable-coefficient parabolic theory as a high-dimensional limit of elliptic theory

   https://doi.org/10.1007/s00526-023-02644-x  

   Davey, Blair; Smit Vega Garcia, Mariana (January 2024, Calculus of Variations and Partial Differential Equations)

   Abstract This paper continues the study initiated in Davey (Arch Ration Mech Anal 228:159–196, 2018), where a high-dimensional limiting technique was developed and used to prove certain parabolic theorems from their elliptic counterparts. In this article, we extend these ideas to the variable-coefficient setting. This generalized technique is demonstrated through new proofs of three important theorems for variable-coefficient heat operators, one of which establishes a result that is, to the best of our knowledge, also new. Specifically, we give new proofs of$$L^2 \rightarrow L^2$$ $L^2\to L^2$Carleman estimates and the monotonicity of Almgren-type frequency functions, and we prove a new monotonicity of Alt–Caffarelli–Friedman-type functions. The proofs in this article rely only on their related elliptic theorems and a limiting argument. That is, each parabolic theorem is proved by taking a high-dimensional limit of a related elliptic result. 

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3. Scalar Curvature, Entropy, and Generalized Ricci Flow

   https://doi.org/10.1093/imrn/rnad002  

   Streets, Jeffrey (February 2023, International Mathematics Research Notices)

   Abstract We derive a family of weighted scalar curvature monotonicity formulas for generalized Ricci flow, involving an auxiliary dilaton field evolving by a certain reaction–diffusion equation motivated by renormalization group flow. These scalar curvature monotonicities are dual to a new family of Perelman-type energy and entropy monotonicity formulas by coupling to a solution of the associated weighted conjugate heat equation. In the setting of Ricci flow, we further obtain a new family of convex Nash entropies and pseudolocality principles. 

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4. The structure of the singular set in the thin obstacle problem for degenerate parabolic equations

   https://doi.org/10.1007/s00526-021-01938-2  

   Banerjee, Agnid; Danielli, Donatella; Garofalo, Nicola; Petrosyan, Arshak (April 2021, Calculus of Variations and Partial Differential Equations)

   Abstract We study the singular set in the thin obstacle problem for degenerate parabolic equations with weight$$|y|^a$$ ${\left|y\right|}^a$for$$a \in (-1,1)$$ $a\in (-1,1)$. Such problem arises as the local extension of the obstacle problem for the fractional heat operator$$(\partial _t - \Delta _x)^s$$ ${({\partial }_t-{\Delta }_x)}^s$for$$s \in (0,1)$$ $s\in (0,1)$. Our main result establishes the complete structure and regularity of the singular set of the free boundary. To achieve it, we prove Almgren-Poon, Weiss, and Monneau type monotonicity formulas which generalize those for the case of the heat equation ($$a=0$$ $a=0$). 

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5. Well-posedness of Keller–Segel systems on compact metric graphs

   https://doi.org/10.1007/s00028-024-01033-x  

   Shemtaga, Hewan; Shen, Wenxian; Sukhtaiev, Selim (December 2024, Journal of Evolution Equations)

   Abstract Chemotaxis phenomena govern the directed movement of microorganisms in response to chemical stimuli. In this paper, we investigate two Keller–Segel systems of reaction–advection–diffusion equations modeling chemotaxis on thin networks. The distinction between two systems is driven by the rate of diffusion of the chemo-attractant. The intermediate rate of diffusion is modeled by a coupled pair of parabolic equations, while the rapid rate is described by a parabolic equation coupled with an elliptic one. Assuming the polynomial rate of growth of the chemotaxis sensitivity coefficient, we prove local well-posedness of both systems on compact metric graphs, and, in particular, prove existence of unique classical solutions. This is achieved by constructing sufficiently regular mild solutions via analytic semigroup methods and combinatorial description of the heat kernel on metric graphs. The regularity of mild solutions is shown by applying abstract semigroup results to semi-linear parabolic equations on compact graphs. In addition, for logistic-type Keller–Segel systems we prove global well-posedness and, in some special cases, global uniform boundedness of solutions. 

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