How Plasma Properties of the Fanaroff-Riley Jet can Shape its Morphology

TL;DR

This study uses 3D-MHD simulations to explore how jet plasma properties influence the morphological classification of extragalactic jets into FR I and FR II types, revealing composition-dependent evolution patterns.

Contribution

It introduces a comprehensive simulation framework examining the effects of plasma composition and injection parameters on jet morphology, highlighting conditions that lead to FR I or FR II structures.

Findings

Mixed plasma jets tend to develop into FR I structures.

Electron-proton jets can transition between FR I and FR II morphologies.

Jet morphology is significantly influenced by plasma composition and injection conditions.

Abstract

Extragalactic jets are broadly classified into two categories based on radio observations: core-brightened jets, known as Fanaroff-Riley Type I (FR I), and edge-brightened jets, classified as Type II (FR II). This FR dichotomy may arise due to variation in the ambient medium and/or the properties of the jet itself, such as injection speed, temperature, composition, magnetization, etc. To investigate this, we perform large-scale three-dimensional magnetohydrodynamic (3D-MHD) simulations of low-power, supersonic jets extending to kiloparsec scales. We inject a jet beam carrying an initially toroidal magnetic field into a denser, unmagnetized, and stratified ambient medium through a cylindrical nozzle. Our simulations explore jets with varying injection parameters to investigate their impact on morphology and emission properties. Furthermore, we examine jets with significantly different plasma compositions, such as hadronic and mixed electron-positron-proton configurations, to study the conditions that may drive transitions between FR I and FR II morphologies. We find that, under the same injection parameters, mixed plasma composition jets tend to evolve into FR I structures. In contrast, electron-proton jets exhibit a transition between FR I and FR II morphologies at different stages of their evolution.