The Shock Dynamics of Heterogeneous YSO Jets:3D Simulations Meet Multi-epoch Observations

Hansen, Edward C.; Frank, Adam; Hartigan, Patrick; Лебедев, С. В.

doi:10.3847/1538-4357/aa5ca8

Cited by 27 publications

(16 citation statements)

References 43 publications

(72 reference statements)

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“…The bow shock driven by the fast plasma flow develops a number of regular, larger scale structures with the size comparable to the bow shock radius. It is interesting to note that very similar structures were recently observed in numerical simulations of the astrophysical bow shocks (Hansen et al, 2017) where they were interpreted as due to development of thin-shell instability advected along the bow-shock. Similar structures of bow shock were also seen in computational studies of radiatively cooled astrophysical jets (see e.g.…”

Section: Fig 13 (A)supporting

confidence: 69%

Exploring astrophysics-relevant magnetohydrodynamics with pulsed-power laboratory facilities

2019

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Laboratory facilities employing high pulsed currents and voltages, and called generally "pulsed-power facilities", allow experimenters to produce a variety of hydrodynamical structures replicating, often in a scalable fashion, a broad range of dynamical astrophysical phenomena. Among these are: astrophysical jets and outflows, astrophysical blast waves, magnetized radiatively dominated flows and, more recently, aspects of simulated accretion disks. The magnetic field thought to play significant role in most of the aforementioned objects is naturally present and controllable in pulsed-power environments. The size of the objects produced in pulsed-power experiments ranges from a centimeter to tens of centimeters, thereby allowing the use of a variety of diagnostic techniques. In a number of situations astrophysical morphologies can be replicated down to the finest structures. The configurations and their parameters are highly reproducible; one can vary them to isolate the most important phenomena and thereby help in developing astrophysical models. This approach has emerged as a useful tool in the quest to better understand magnetohydrodynamical effects in astronomical environments. The present review summarizes the progress made during the last decade and is designed to help readers identify and, perhaps, implement new experiments in this growing research area. Techniques used for generation and characterization of the flows are described. 1 Retired 2 CONTENTS I. Introduction II. Jets and outflows-weak magnetic field A. Generating plasma streams and plasma jets with wire arrays. B. Hypersonic, radiatively cooled hydrodynamic jets and their interaction with the ambient medium C. Hydrodynamic interaction of the jets with a side wind D. Highly-collimated jets produced by ablation of the central area of a metal foil III. Jets and outflows-significant magnetic field A. Magnetically-dominated tower jets B. Formation of energetic ions in a magnetic cavity C. Possible role of axial magnetic field B. Episodic events and internal shocks E. Magnetic arches and their stability F. MHD equilibria stabilized by the shear flow IV. Rotating plasmas-on the way to imitating the accretion discs V. Shock waves A. General comments B. Blast waves and radiative precursors C. Shocks in the colliding streams D. Introducing magnetic field E. Interaction of magnetized streams with clumps and globules VI. Non-MHD effects A. Hall and other two-fluid effects B. Generation of energetic particles C.

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Section: Fig 13 (A)supporting

confidence: 69%

Exploring astrophysics-relevant magnetohydrodynamics with pulsed-power laboratory facilities

2019

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“…An important application of the new non-equilibrium cooling routines in AstroBEAR is simulations of HH objects. In previous studies, we have run simulations of pulsed jets (Hansen et al 2015b) and interacting bow shocks (Hansen et al 2017). The example outflow and synthetic emission map we show here is similar to the simulations from the latter work.…”

Section: Applications To Hh Objectssupporting

confidence: 77%

“…There are other similarities between Figure 8 and Figure 7 such as the heterogeneous nature of the emission. These structures and other details of such outflows will are discussed in (Hansen et al 2017).…”

Section: Applications To Hh Objectsmentioning

confidence: 96%

Erratum: Simulating radiative magnetohydrodynamical flows with astrobear: implementation and applications of non-equilibrium cooling

Hansen

Hartigan

Frank

et al. 2018

Monthly Notices of the Royal Astronomical Society

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Radiative cooling plays a crucial role in the dynamics of many astrophysical flows, and is particularly important in the dense shocked gas within Herbig-Haro (HH) objects and stellar jets. Simulating cooling processes accurately is necessary to compare numerical simulations with existing and planned observations of HH objects, such as those from the Hubble Space Telescope and the James Webb Space Telescope. In this paper we discuss a new, non-equilibrium cooling scheme we have implemented into the 3-D magnetohydrodynamic (MHD) code AstroBEAR. The new cooling function includes ionization, recombination, and excitation of all the important atomic species that cool below 10000 K. We tested the routine by comparing its predictions with those from the well-tested 1-D Cox-Raymond shock code (Raymond 1979). The results show that AstroBEAR accurately tracks the ionization fraction, temperature, and other MHD variables for all low-velocity ( 90 km/s) magnetized radiative shock waves. The new routine allows us to predict synthetic emission maps in all the bright forbidden and permitted lines observed in stellar jets, including Hα, [N II], [O I], and [S II]. We present an example as to how these synthetic maps facilitate a direct comparison with narrowband images of HH objects.

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“…We can estimate characteristic time scales for the growth of hydrodynamic instabilities from a shocked-clump model presented in Ref. [21]. For a strong shock, the Rayleigh-Taylor instability is expected to grow in a time scale given by t RT ∼ √ η r spot v shock with η the ratio of post-shock to pre-shock density, r spot the radius of the laser focal spot and v shock the tip shock velocity.…”

Section: Discussionmentioning

confidence: 99%

First radiative shock experiments on the SG-II laser

Suzuki-Vidal

Clayson²,

Stehlé

et al. 2021

High Pow Laser Sci Eng

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We report on the design and first results from experiments looking at the formation of radiative shocks on the Shenguang-II (SG-II) laser at the Shanghai Institute of Optics and Fine Mechanics in China. Laser-heating of a two-layer CH/CH–Br foil drives a $\sim 40$ km/s shock inside a gas cell filled with argon at an initial pressure of 1 bar. The use of gas-cell targets with large (several millimetres) lateral and axial extent allows the shock to propagate freely without any wall interactions, and permits a large field of view to image single and colliding counter-propagating shocks with time-resolved, point-projection X-ray backlighting ( $\sim 20$ μm source size, 4.3 keV photon energy). Single shocks were imaged up to 100 ns after the onset of the laser drive, allowing to probe the growth of spatial nonuniformities in the shock apex. These results are compared with experiments looking at counter-propagating shocks, showing a symmetric drive that leads to a collision and stagnation from $\sim 40$ ns onward. We present a preliminary comparison with numerical simulations with the radiation hydrodynamics code ARWEN, which provides expected plasma parameters for the design of future experiments in this facility.

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The Shock Dynamics of Heterogeneous YSO Jets:3D Simulations Meet Multi-epoch Observations

Cited by 27 publications

References 43 publications

Exploring astrophysics-relevant magnetohydrodynamics with pulsed-power laboratory facilities

Exploring astrophysics-relevant magnetohydrodynamics with pulsed-power laboratory facilities

Erratum: Simulating radiative magnetohydrodynamical flows with astrobear: implementation and applications of non-equilibrium cooling

First radiative shock experiments on the SG-II laser

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