The stability of simple plane-symmetric shock formation for three-dimensional compressible Euler flow with vorticity and entropy

Luk, Jonathan; Speck, Jared

doi:10.2140/apde.2024.17.831

Analysis & PDE

2024

DOI: 10.2140/apde.2024.17.831

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The stability of simple plane-symmetric shock formation for three-dimensional compressible Euler flow with vorticity and entropy

Jonathan Luk,

Jared Speck

Abstract: Consider a one-dimensional simple small-amplitude solution (ϱ (bkg) , v 1 (bkg) ) to the isentropic compressible Euler equations which has smooth initial data, coincides with a constant state outside a compact set, and forms a shock in finite time. Viewing (ϱ (bkg) , v 1 (bkg) ) as a plane-symmetric solution to the full compressible Euler equations in three dimensions, we prove that the shock-formation mechanism for the solution (ϱ (bkg) , v 1 (bkg) ) is stable against all sufficiently small and compactly supp… Show more

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Cited by 3 publications

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Remarkable Localized Integral Identities for 3D Compressible Euler Flow and the Double-Null Framework

Abbrescia,

Speck

2024

Arch Rational Mech Anal

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We derive new, localized geometric integral identities for solutions to the 3D compressible Euler equations under an arbitrary equation of state when the sound speed is positive. The integral identities are coercive in the derivatives of the specific vorticity (defined to be vorticity divided by density) and the derivatives of the entropy gradient vectorfield, and the error terms exhibit remarkable regularity and null structures. Our framework plays a fundamental role in our companion works (Abbrescia L, Speck J. The emergence of the singular boundary from the crease in 3D compressible Euler flow, 2022; Abbrescia and Speck, The emergence of the Cauchy horizon from the crease in 3D compressible Euler flow (in preparation)) on the structure of the maximal classical development for shock-forming solutions. It allows one to simultaneously unleash the full power of the geometric vectorfield method for both the wave- and transport- parts of the flow on compact regions, and our approach reveals fundamental new coordinate-invariant structural features of the flow. In particular, the integral identities yield localized control over one additional derivative of the vorticity and entropy compared to standard results, assuming that the initial data enjoy the same gain. Similar results hold for the solution’s higher derivatives. We derive the identities in detail for two classes of spacetime regions that frequently arise in PDE applications: (i) compact spacetime regions that are globally hyperbolic with respect to the acoustical metric, where the top and bottom boundaries are acoustically spacelike—but not necessarily equal to portions of constant Cartesian-time hypersurfaces; and (ii) compact regions covered by double-acoustically null foliations. Our results have implications for the geometry and regularity of solutions, the formation of shocks, the structure of the maximal classical development of the data, and for controlling solutions whose state along a pair of intersecting characteristic hypersurfaces is known. Our analysis relies on a recent new formulation of the compressible Euler equations that splits the flow into a geometric wave-part coupled to a div-curl-transport part. The main new contribution of the present article is our analysis of the spacelike, co-dimension one and two boundary integrals that arise in the div-curl identities. By exploiting interplay between the elliptic and hyperbolic parts of the new formulation and using careful geometric decompositions, we observe several crucial cancellations, which in total show that after a further integration with respect to an acoustical time function, the boundary integrals have a good sign, up to error terms that can be controlled due to their good null structure and regularity properties.

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Remarkable Localized Integral Identities for 3D Compressible Euler Flow and the Double-Null Framework

Abbrescia,

Speck

2024

Arch Rational Mech Anal

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The geometry of maximal development and shock formation for the Euler equations in multiple space dimensions

Shkoller,

Vicol

2024

Invent. math.

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Recent developments in mathematical aspects of relativistic fluids

Disconzi

2024

Living Rev Relativ

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We review some recent developments in mathematical aspects of relativistic fluids. The goal is to provide a quick entry point to some research topics of current interest that is accessible to graduate students and researchers from adjacent fields, as well as to researches working on broader aspects of relativistic fluid dynamics interested in its mathematical formalism. Instead of complete proofs, which can be found in the published literature, here we focus on the proofs’ main ideas and key concepts. After an introduction to the relativistic Euler equations, we cover the following topics: a new wave-transport formulation of the relativistic Euler equations tailored to applications; the problem of shock formation for relativistic Euler; rough (i.e., low-regularity) solutions to the relativistic Euler equations; the relativistic Euler equations with a physical vacuum boundary; relativistic fluids with viscosity. We finish with a discussion of open problems and future directions of research.

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The stability of simple plane-symmetric shock formation for three-dimensional compressible Euler flow with vorticity and entropy

Cited by 3 publications

References 50 publications

Remarkable Localized Integral Identities for 3D Compressible Euler Flow and the Double-Null Framework

Remarkable Localized Integral Identities for 3D Compressible Euler Flow and the Double-Null Framework

The geometry of maximal development and shock formation for the Euler equations in multiple space dimensions

Recent developments in mathematical aspects of relativistic fluids

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