The complex structure of HH 110 as revealed from Integral Field Spectroscopy

TL;DR

This study uses Integral Field Spectroscopy to analyze the 3D kinematics and physical conditions of the peculiar Herbig-Haro object HH 110, revealing complex spatial distributions and supporting models of jet deflection in an inhomogeneous medium.

Contribution

First detailed 3D spectroscopic analysis of HH 110 revealing its complex physical and kinematic structure, aiding future theoretical modeling.

Findings

Reproduces known morphology and kinematics.

Maps excitation and density variations across the jet.

Supports deflected jet model in inhomogeneous medium.

Abstract

HH 110 is a rather peculiar Herbig-Haro object in Orion that originates due to the deflection of another jet (HH 270) by a dense molecular clump, instead of being directly ejected from a young stellar object. Here we present new results on the kinematics and physical conditions of HH 110 based on Integral Field Spectroscopy. The 3D spectral data cover the whole outflow extent (~4.5 arcmin, ~0.6 pc at a distance of 460 pc) in the spectral range 6500-7000 \AA. We built emission-line intensity maps of H$\alpha$, [NII] and [SII] and of their radial velocity channels. Furthermore, we analysed the spatial distribution of the excitation and electron density from [NII]/H$\alpha$, [SII]/H$\alpha$, and [SII] 6716/6731 integrated line-ratio maps, as well as their behaviour as a function of velocity, from line-ratio channel maps. Our results fully reproduce the morphology and kinematics obtained from previous imaging and long-slit data. In addition, the IFS data revealed, for the first time, the complex spatial distribution of the physical conditions (excitation and density) in the whole jet, and their behaviour as a function of the kinematics. The results here derived give further support to the more recent model simulations that involve deflection of a pulsed jet propagating in an inhomogeneous ambient medium. The IFS data give richer information than that provided by current model simulations or laboratory jet experiments. Hence, they could provide valuable clues to constrain the space parameters in future theoretical works.