On the Existence of Linearly Oscillating Galaxies

Hadžić, Mahir; Rein, Gerhard; Straub, Christopher

doi:10.1007/s00205-021-01734-4

Cited by 10 publications

(21 citation statements)

References 62 publications

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“…Since ω 1 is continuous on the compact set D and T 1 is non-zero, certainly (b) follows from (a), but it is also possible to give a proof using the explicit period relation (6.12). Similar results have been obtained in [16]. ✷…”

Section: The Birman-schwinger Approachsupporting

confidence: 89%

“…These are the (somewhat extended) lecture notes for four lectures delivered at the spring school during the thematic programme "Mathematical Perspectives of Gravitation beyond the Vacuum Regime" at ESI Vienna in February 2022. The main reference for the lectures is [25], which has some overlap with [16], although we wanted to emphasize the action-angle variables approach and put a main focus on the Birman-Schwinger principle, as is done in [25]. Since the lectures have been aimed at newcomers, some parts of them cover basic background material.…”

Section: Introductionmentioning

confidence: 99%

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A Birman-Schwinger Principle in Galactic Dynamics

Kunze

2021

Progress in Mathematical Physics

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These are the (somewhat extended) lecture notes for four lectures delivered at the spring school during the thematic programme "Mathematical Perspectives of Gravitation beyond the Vacuum Regime" at ESI Vienna in February 2022. Contents 1 Introduction 2 The Birman-Schwinger principle in quantum mechanics 3 Galactic dynamics: The Vlasov-Poisson system 4 Spherically symmetric solutions 5 Steady state solutions 6 Action angle variables 7 Function spaces 8 Linearization 1 9 The Birman-Schwinger approach 21 10 An application 26 11 Open questions and further topics 30 Proof : See [28, Section 4.3.1]. If Hφ = (−∆+ V )φ = (−e)φ, then we define ψ = √ −V φ to obtainConversely, if B e ψ = ψ holds and if we put φ = (−∆ + e) −1 ( √ −V ψ), it follows thatand hence Hφ = (−∆ + V )φ = (−e)φ, which completes the argument. ✷Here are some facts:• The operators B e are non-negative Hilbert-Schmidt operators (if V decays sufficiently fast and n ≤ 3), and in particular they are compact.• Their eigenvalues can be ordered: λ 1 (e) ≥ λ 2 (e) ≥ . . . → 0 and the eigenvalue curves are decreasing in e, in that ẽ ≥ e implies that λ k (e) ≤ λ k (ẽ) for all k.

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Section: The Birman-schwinger Approachsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

A Birman-Schwinger Principle in Galactic Dynamics

Kunze

2021

Progress in Mathematical Physics

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“…For small values of z c -corresponding to less relativistic settings-we observe a stable oscillation of the solution around the original equilibrium. For the spherically symmetric Vlasov-Poisson system, which is the non-relativistic limit of the Einstein-Vlasov system [28], similar oscillations have been observed numerically [23] and have recently been proven to exist on the linear level for certain equilibria in [15].…”

Section: Review Of the Polytropic Case K =supporting

confidence: 55%

Collisionless equilibria in general relativity: stable configurations beyond the first binding energy maximum

Günther,

Straub,

Rein

2021

Preprint

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We numerically study the stability of collisionless equilibria in the context of general relativity. More precisely, we consider the spherically symmetric, asymptotically flat Einstein-Vlasov system in Schwarzschild and in maximal areal coordinates. Our results provide strong evidence against the well-known binding energy hypothesis which states that the first local maximum of the binding energy along a sequence of isotropic steady states signals the onset of instability. We do however confirm the conjecture that steady states are stable at least up to the first local maximum of the binding energy. For the first time, we observe multiple stability changes for certain models. The equations of state used are piecewise linear functions of the particle energy and provide a rich variety of different equilibria.

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“…Crucial parts of our investigation are based on action-angle type variables, which we introduce in Section 3.3. While action-angle variables are a classical tool in Hamiltonian mechanics [9,32,38], they have been used recently to derive a Birman-Schwinger principle in Newtonian galactic dynamics [25,31] and to analyze phase mixing [51].…”

Section: Methodology and Outline Of The Papermentioning

confidence: 99%

“…As in the non-relativistic setting [25,31], the radial period function T and its properties are crucial to derive a Birman-Schwinger principle. We next show that this function is bounded and bounded away from zero on the steady state support for sufficiently small shells around a Schwarzschild black hole.…”

Section: The Periodic Particle Motions and The Period Functionmentioning

confidence: 99%

A Birman-Schwinger Principle in General Relativity: Linearly Stable Shells of Collisionless Matter Surrounding a Black Hole

Günther¹,

Rein²,

Straub³

2022

Preprint

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We develop a Birman-Schwinger principle for the spherically symmetric, asymptotically flat Einstein-Vlasov system. It characterizes stability properties of steady states such as the positive definiteness of an Antonov-type operator or the existence of exponentially growing modes in terms of a one-dimensional variational problem for a Hilbert-Schmidt operator. This requires a refined analysis of the operators arising from linearizing the system, which uses action-angle type variables. For the latter, a single-well structure of the effective potential for the particle flow of the steady state is required. This natural property can be verified for a broad class of singularity-free steady states. As a particular example for the application of our Birman-Schwinger principle we consider steady states where a Schwarzschild black hole is surrounded by a shell of Vlasov matter. We prove the existence of such steady states and derive linear stability if the mass of the Vlasov shell is small compared to the mass of the black hole.

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On the Existence of Linearly Oscillating Galaxies

Cited by 10 publications

References 62 publications

A Birman-Schwinger Principle in Galactic Dynamics

A Birman-Schwinger Principle in Galactic Dynamics

Collisionless equilibria in general relativity: stable configurations beyond the first binding energy maximum

A Birman-Schwinger Principle in General Relativity: Linearly Stable Shells of Collisionless Matter Surrounding a Black Hole

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