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When, where, and how star formation happens in a galaxy pair at cosmic noon using CANUCS <i>JWST</i>/NIRISS grism spectroscopy

Vicente Estrada-Carpenter, Marcin Sawicki, Gabriel Brammer, G. Desprez, Roberto Abraham, Yoshihisa Asada, Maruša Bradač, Kartheik G. Iyer, Nicholas S. Martis, Jasleen Matharu, Lamiya Mowla, Adam Muzzin, Gaël Noirot, Ghassan T. E. Sarrouh, Victoria Strait, Chris J. Willott

2024Monthly Notices of the Royal Astronomical Society12 citationsDOIOpen Access PDF

Abstract

ABSTRACT Spatially resolved studies are key to understanding when, where, and how stars form within galaxies. Using slitless grism spectra and broad-band imaging from the CAnadian NIRISS Unbiased Cluster Survey (CANUCS), we study the spatially resolved properties of a strongly lensed (μ = 5.4$\pm$1.8) z = 0.8718 galaxy pair consisting of a blue face-on galaxy (10.2 $\pm$ 0.2 log($M/M_\odot$)) with multiple star-forming clumps and a dusty red edge-on galaxy (9.9 $\pm$ 0.3 log($M/M_\odot$)). We produce accurate H $\alpha$ maps from JWST/NIRISS grism data using a new methodology that accurately models spatially varying continuum and emission line strengths. With spatially resolved indicators, we probe star formation on time-scales of $\sim$10 Myr (NIRISS H $\alpha$ emission line maps) and $\sim$100 Myr (UV imaging and broad-band SED fits). Taking the ratio of the H $\alpha$ to UV flux ($\eta$), we measure spatially resolved star formation burstiness. We find that in the face-on galaxy both H $\alpha$ and broad-band star formation rates (SFRs) drop at large galactocentric radii by a factor of $\sim$4.7 and 3.8, respectively, while SFR over the last $\sim$100 Myrs has increased by a factor of 1.6. Additionally, of the 20 clumps identified in the galaxy pair we find that 7 are experiencing bursty star formation, while 10 clumps are quenching, and 3 are in equilibrium (either being in a state of steady star formation or post-burst). Our analysis reveals that the blue face-on galaxy disc is predominantly in a quenching or equilibrium phase. However, the most intense quenching within the galaxy is seen in the quenching clumps. This pilot study demonstrates what JWST/NIRISS data can reveal about spatially varying star formation in galaxies at Cosmic Noon.

Topics & Concepts

PhysicsAstrophysicsGrismGalaxyStar formationAstronomyExtinction (optical mineralogy)RedshiftOpticsGalaxies: Formation, Evolution, PhenomenaAstronomy and Astrophysical ResearchStellar, planetary, and galactic studies
When, where, and how star formation happens in a galaxy pair at cosmic noon using CANUCS <i>JWST</i>/NIRISS grism spectroscopy | Litcius