Theoretical astrophysics and plasma physics at RPC

Centrifugal-mirror confinement with strong azimuthal magnetic field

Plasma Physics and Controlled Fusion 67:9 (2025)

Authors:

T Stoltzfus-Dueck, FI Parra

Abstract:

One practical challenge for the centrifugal-mirror confinement concept is the large radial voltage necessary to drive supersonic azimuthal rotation. In principle, the addition of a strong azimuthal field could reduce the required voltage, since the simple azimuthal E × B drift would be replaced by more rapid azimuthal trapped-particle precession. Also, if the mirror ratio is large enough, newly ionized ions are accelerated to the necessary parallel velocities in their first bounce orbit, both confining and significantly heating them. Unfortunately, MHD analysis shows that the centrifugal-force-confining plasma current is purely azimuthal. This implies that only the axial magnetic field contributes to the confining magnetic pressure, severely limiting the usefulness of the azimuthal magnetic field in a beta-limited plasma scenario.

Gravitational turbulence: The small-scale limit of the cold-dark-matter power spectrum

Physical Review D American Physical Society (APS) 112:6 (2025) 063501

Authors:

Yonadav Barry Ginat, Michael L Nastac, Robert J Ewart, Sara Konrad, Matthias Bartelmann, Alexander A Schekochihin

Abstract:

The matter power spectrum, $P(k)$ , is one of the fundamental quantities in the study of large-scale structure in cosmology. Here, we study its small-scale asymptotic limit, and show that for cold dark matter in $d$ spatial dimensions, $P(k)$ has a universal $k^{-d}$ asymptotic scaling with the wave number $k$ , for $k\gg k_{\mathrm{nl}}$ , where $k_{\mathrm{nl}}^{-1}$ denotes the length scale at which nonlinearities in gravitational interactions become important. We propose a theoretical explanation for this scaling, based on a nonperturbative analysis of the system’s phase-space structure. Gravitational collapse is shown to drive a turbulent phase-space flow of the quadratic Casimir invariant, where the linear and nonlinear time scales are balanced, and this balance dictates the $k$ dependence of the power spectrum. A parallel is drawn to Batchelor turbulence in hydrodynamics, where large scales mix smaller ones via tidal interactions. The $k^{-d}$ scaling is also derived by expressing $P(k)$ as a phase-space integral in the framework of kinetic field theory, which is analyzed by the saddle-point method; the dominant critical points of this integral are precisely those where the time scales are balanced. The coldness of the dark-matter distribution function—its nonvanishing only on a $d$ -dimensional submanifold of phase space—underpins both approaches. The theory is accompanied by 1D Vlasov-Poisson simulations, which confirm it.

Suppression of pair beam instabilities in a laboratory analogue of blazar pair cascades

(2025)

Authors:

Charles D Arrowsmith, Francesco Miniati, Pablo J Bilbao, Pascal Simon, Archie FA Bott, Stephane Burger, Hui Chen, Filipe D Cruz, Tristan Davenne, Anthony Dyson, Ilias Efthymiopoulos, Dustin H Froula, Alice Goillot, Jon T Gudmundsson, Dan Haberberger, Jack WD Halliday, Tom Hodge, Brian T Huffman, Sam Iaquinta, G Marshall, Brian Reville, Subir Sarkar, Alexander A Schekochihin, Luis O Silva, Raspberry Simpson, Vasiliki Stergiou, Raoul MGM Trines, Thibault Vieu, Nikolaos Charitonidis, Robert Bingham, Gianluca Gregori

Hydrodynamic simulations of black hole evolution in AGN discs I: orbital alignment of highly inclined satellites

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2025) staf1449

Authors:

Connar Rowan, Henry Whitehead, Gaia Fabj, Philip Kirkeberg, Martin E Pessah, Bence Kocsis

Abstract:

Abstract The frequency of compact object interactions in AGN discs is naturally tied to the number of objects embedded within it. We investigate the evolution of black holes in the nuclear stellar cluster on inclined orbits to the AGN disc by performing adiabatic hydrodynamical simulations of isolated black hole disc crossings over a range of disc densities and inclinations i ∈ [2○, 15○]. We find radiation dominates the pressure in the wake that forms around the BH across the full inclination and disc density range. We identify no well defined steady state wake morphology due to the thin geometry of the disc and the vertical exponential density drop off, where the wake morphology depends on the vertical depth of the transit within the disc. The inclination damping Δi relative the pre-transit inclination behaves as a power law in sin (i) and the ambient Hill mass mH, 0 as $\Delta i/i \propto m_{\rm H,0}^{0.4} \sin (i)^{-2.7}$. The drag on the BH is dominated by the gravity of the wake for the majority of our inclination range until accretion effects become comparable at sin (i) ≳ 30H0/R0, where H0/R0 is the disc aspect ratio. At low inclinations (sin (i) ≲ 3H0/R0) the wake morphology becomes more spherical, leading to a regime change in the inclination damping behaviour. Our results suggest that the inclination damping timescale is shorter than expected from only episodic Bondi-Hoyle-Lyttelton accretion events during each transit, implying inclined objects may be captured by the AGN disc earlier in its lifetime than previously thought.

Efficient ion re-acceleration in laboratory-produced interpenetrating collisionless shocks

(2025)

Authors:

W Yao, I Cohen, P Suarez Gerona, H Ahmed, AFA Bott, SN Chen, M Cook, R Lelièvre, P Martin, T Waltenspiel, P Antici, J Béard, M Borghesi, D Caprioli, A Ciardi, E d'Humières, M François, L Gremillet, A Marcowith, M Miceli, T Seebaruth, S Orlando, J Fuchs