Hypersonic Buckshot: Astrophysical Jets as Heterogeneous Collimated Plasmoids

TL;DR

This paper proposes that astrophysical jets are composed of heterogeneous chains of dense clumps rather than homogeneous flows, with simulations showing complex structures and behaviors that match recent observations and challenge pulsed-jet models.

Contribution

It introduces a novel simulation approach modeling jets as chains of dense clumps, revealing new sub-radial structures and dynamics not seen in previous homogeneous jet models.

Findings

Clumps interact to form complex jet structures.

Sub-radial behaviors like backward bow shocks are observed.

Simulation results align with recent high-resolution jet observations.

Abstract

Herbig-Haro (HH) jets are commonly thought of as homogeneous beams of plasma traveling at hypersonic velocities. Structure within jet beams is often attributed to periodic or ``pulsed'' variations of conditions at the jet source. Simulations based on this scenario result in knots extending across the jet diameter. Observations and recent high energy density laboratory experiments shed new light on structures below this scale and indicate they may be important for understanding the fundamentals of jet dynamics. In this paper we offer an alternative to ``pulsed'' models of protostellar jets. Using direct numerical simulations we explore the possibility that jets are chains of sub-radial clumps propagating through a moving inter-clump medium. Our models explore an idealization of this scenario by injecting small ($r<r_{jet}$), dense ($\rho>\rho_{jet}$) spheres embedded in an otherwise smooth inter-clump jet flow. The spheres are initialized with velocities differing from the jet velocity by $\sim15$%. We find the consequences of shifting from homogeneous to heterogeneous flows are significant as clumps interact with each other and with the inter-clump medium in a variety of ways. Structures which mimic what is expected from pulsed-jet models can form, as can previously unseen ``sub-radial'' behaviors including backward facing bow shocks and off-axis working surfaces. While these small-scale structures have not been seen before in simulation studies, they are found in high resolution jet observations. We discuss implications of our simulations for the interpretation of protostellar jets with regard to characterization of knots by a ``lifetime'' or ``velocity history'' approach as well as linking observed structures with central engines which produce the jets.