JWST Observations of Starbursts: Polycyclic Aromatic Hydrocarbon Emission at the Base of the M 82 Galactic Wind (2401.16648v4)

Abstract: We present new observations of the central 1 kpc of the M 82 starburst obtained with the James Webb Space Telescope (JWST) near-infrared camera (NIRCam) instrument at a resolution ~0.05"-0.1" (~1-2 pc). The data comprises images in three mostly continuum filters (F140M, F250M, and F360M), and filters that contain FeII, H2 v=1-0 (F212N), and the 3.3 um PAH feature (F335M). We find prominent plumes of PAH emission extending outward from the central starburst region, together with a network of complex filamentary substructure and edge-brightened bubble-like features. The structure of the PAH emission closely resembles that of the ionized gas, as revealed in Paschen alpha and free-free radio emission. We discuss the origin of the structure, and suggest the PAHs are embedded in a combination of neutral, molecular, and photoionized gas.

• The paper reveals high-resolution PAH emission features at the base of M82's wind, highlighting intricate filamentary and bubble-like structures.
• Observations establish a strong correlation between PAH emissions and ionized gas, with thermal free-free radio signatures distinguishing gas phases.
• The study demonstrates JWST's power to resolve starburst-driven winds, providing new insights into galactic evolution and star formation regulation.

Observational Insights on Galactic Winds: JWST Analysis of PAH Emission in M82

The paper presents observations using the James Webb Space Telescope (JWST) focused on the central 1 kpc region of the starburst galaxy M82, particularly analyzing the emission of polycyclic aromatic hydrocarbons (PAHs) at the base of its galactic wind. This paper utilizes data from the JWST's NIRCam instrument, capturing previously inaccessible details with high resolution of around 0.1 arcseconds. The observations integrate images taken at multiple filters, including those sensitive to PAH emissions.

Key Observations and Findings

The high-resolution images reveal a sophisticated network of filamentary structures and bubble-like features extending outward from M82's central starburst region. These structures are formed by PAHs embedded in a mix of neutral, ionized, and molecular gases, which are likely entrained by the starburst-driven wind.

Structural and Morphological Analysis:

1. Filamentary and Bubble-like Features: The captured data shows plumes of PAH emissions forming complex, filamentous structures and bubble-like features. These observations suggest interactions between the starburst-induced outflow and the surrounding interstellar medium.
2. Correlation with Ionized and Molecular Gas: The PAH emissions closely correlate with ionized gas revealed by Paschen α and free-free radio emissions, indicating their presence in cooler gas phases. However, there is less alignment with molecular gas traced by CO emissions, suggesting different origins or evolutionary stages within the wind's structure.
3. Thermal vs. Non-Thermal Radio Emission: Analysis of the radio-to-recombination line emission ratio indicates that the extraplanar filamentary radio emission is thermal, primarily originating from free-free emissions, rather than from non-thermal synchrotron sources that would imply strong magnetic fields.

Implications and Theoretical Context

The findings contribute to the understanding of galactic wind dynamics and the lifecycle of interstellar media in starburst environments. The research supports the hypothesis that these winds can carry different phases of matter far into the circumgalactic medium, impacting the galaxy's evolution by regulating star formation and gas accretion processes.

Theoretical Considerations:

• Winds as Regulators: The paper implies that galactic winds, powered by intense starburst activity, play a critical role in the mass distribution and kinematic processes within the galaxy, potentially influencing galaxy mass function and supermassive black hole growth.
• Star-Formation Activity: By mapping these structures, insights can be derived regarding the star formation efficiency and the structural evolution within starburst galaxies, closely tied to the formation of super star clusters.

Future Directions

The paper opens avenues for further research into the dynamics of starburst-driven galactic winds. Future investigations could focus on:

• Spectroscopic studies to definitively characterize the molecular phases of outflows, especially using mid-infrared hydrogen lines.
• Enhanced modeling of galactic wind feedback processes, using the detailed morphological data as a baseline.
• Expanding the sample size to other starburst galaxies to test the generalizability of M82’s wind phenomena.

Overall, this research exemplifies the significant advancements facilitated by JWST’s capabilities, offering unprecedented detail that challenges existing models and enhances the understanding of complex astrophysical processes shaping galaxy evolution.