JWST observations of photodissociation regions III. Dust modelling at the illuminated edge of the Horsehead PDR

TL;DR

This study uses JWST data to analyze dust and nano-grain properties at the Horsehead PDR edge, revealing less depletion of small grains and slower recovery in moderate-UV environments compared to more intense PDRs.

Contribution

First detailed dust modeling of the Horsehead PDR edge using JWST data, highlighting differences in nano-grain abundance and size distribution from other PDRs.

Findings

Small grains are not depleted at the Horsehead edge.

A sharp density increase occurs at the illuminated edge.

Nano-grain destruction is less efficient in moderate-UV fields.

Abstract

Carbonaceous nano-grains are a significant component of interstellar dust and dominate the mid-infrared emission of photodissociation regions (PDRs). We study the evolution of nano-grains across the illuminated edge of the Horsehead PDR, especially their abundance and size properties. This work is part of the Physics and Chemistry of PDR Fronts program studying dust and gas in PDRs with JWST. We use NIRCam+MIRI photometric bands and NIRSpec+MRS spectroscopy to map the illuminated edge. We model dust emission using the THEMIS dust model with the SOC radiative transfer code. Detailed modeling of high angular resolution JWST data allows us to obtain constraints on nano-grain properties. We find that diffuse ISM dust cannot account for the observed data, requiring evolved grains. A sharp density increase is observed at the illuminated edge, consistent with ALMA observations revealing a sharp transition between molecular and ionized gas. Although the PDR length could not be directly determined, we estimate an upper limit of approximately 0.015 pc. This implies a lower limit on small grain abundance (greater than 0.003), showing small grains are not depleted at the Horsehead edge, unlike in the Orion Bar. Our findings indicate a high-density environment and less steep size distribution for nano-grains at the illuminated edge versus the diffuse ISM. This implies nano-grain destruction mechanisms might be less efficient in the Horsehead's moderate-UV field than in more intense PDRs. These results support a model where nano-grain population recovery is slower in moderate-UV environments, leading to a unique dust size distribution at the edge of the Horsehead Nebula.