B. Ummels scite author profile

B. Ummels

2Publications

15Citation Statements Received

36Citation Statements Given

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Imperial College London

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Numerical Simulations of Z-Pinch Experiments to Create Supersonic Differentially Rotating Plasma Flows

Bocchi

Ummels

Chittenden

et al. 2013

ApJ

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The physics of accretion disks is of fundamental importance for understanding of a wide variety of astrophysical sources that includes protostars, X-ray binaries, and active galactic nuclei. The interplay between hydrodynamic flows and magnetic fields and the potential for turbulence-producing instabilities is a topic of active research that would benefit from the support of dedicated experimental studies. Such efforts are in their infancy, but in an effort to push the enterprise forward we propose an experimental configuration which employs a modified cylindrical wire array Z-pinch to produce a rotating plasma flow relevant to accretion disks. We present three-dimensional resistive magnetohydrodynamic simulations which show how this approach can be implemented. In the simulations, a rotating plasma cylinder or ring is formed, with typical rotation velocity ∼30 km s −1 , Mach number ∼4, and Reynolds number in excess of 10 7 . The plasma is also differentially rotating. Implementation of different external magnetic field configurations is discussed. It is found that a modest uniform vertical field of 1 T can affect the dynamics of the system and could be used to study magnetic field entrainment and amplification through differential rotation. A dipolar field potentially relevant to the study of accretion columns is also considered.

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Numerical simulations of Z-Pinch experiments to create supersonic differentially-rotating plasma flows

Bocchi

Ummels

Chittenden

et al. 2012

EAS Publications Series

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Abstract. In the context of high energy density laboratory astrophysics, we aim to produce and study a rotating plasma relevant to accretion discs physics. We devised an experimental setup based on a modified cylindrical wire array and we studied it numerically with the three-dimensional, resistive magneto-hydrodynamic code GORGON. The simulations show that a rotating plasma cylinder is formed, with typical rotation velocity ∼35 km/s and Mach number ∼5. In addition, the plasma ring is differentially rotating and strongly radiatively cooled. The introduction of external magnetic fields is discussed.

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B. Ummels

Numerical Simulations of Z-Pinch Experiments to Create Supersonic Differentially Rotating Plasma Flows

Numerical simulations of Z-Pinch experiments to create supersonic differentially-rotating plasma flows

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