Morphological merger fractions exceed close-pair fractions across 0.2<z<0.9 in DEVILS, with minimal sample overlap, attributed to different merger stages and timescales.
Early and Rapid Merging as a Formation Mechanism of Massive Galaxies: Empirical Constraints
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
We present the results of a series of empirical computations regarding the role of major mergers in forming the stellar masses of modern galaxies based on measurements of galaxy merger and star formation histories from z~0.5-3. We re-construct the merger history of normal field galaxies from z~3 to z~0 as a function of initial mass using published pair fractions and merger fractions from structural analyses. We calibrate the observed merger time-scale and mass ratios for galaxy mergers using self-consistent N-body models of mergers, composed of dark matter and stars, with mass ratios from 1:1 to 1:5 with various orbital properties and viewing angles. We use these simulations to determine the time-scales and mass ratios that produce structures that would be identified as major mergers. Based on these calculations we argue that a typical massive galaxy at z~3 with M_{*} > 10^{10} M_0 undergoes 4.4^{+1.6}_{-0.9} major mergers at z > 1. We find that by z~1.5 the stellar mass of an average massive galaxy is relatively established, a scenario qualitatively favored in a lambda dominated universe. We argue that the final masses of these systems increases by as much as a factor of 100 allowing Lyman-break galaxies, which tend to have low stellar masses, to become the most massive galaxies in today's universe with M > M^{*}. Induced star formation however only accounts for 10-30% of the stellar mass formed in these galaxies at z < 3. A comparison to semi-analytic models of galaxy formation shows that Cold Dark Matter (CDM) models consistently under-predict the merger fraction, and rate of merging, of massive galaxies at high redshift. This suggests that massive galaxy formation occurs through more merging than predicted in CDM models, rather than a rapid early collapse.
fields
astro-ph.GA 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
LEGGOS presents a uniform framework that jointly models lensing, photometry, and integral-field spectroscopy to disentangle stellar populations in clumps of high-redshift lensed galaxies.
citing papers explorer
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Deep Extragalactic VIsible Legacy Survey (DEVILS): Morphologically-selected galaxy merger fractions and their direct comparison to close-pair samples
Morphological merger fractions exceed close-pair fractions across 0.2<z<0.9 in DEVILS, with minimal sample overlap, attributed to different merger stages and timescales.
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LEGGOS I: The JWST LEGGOS Survey -- LEnsing and Galaxy Growth: Observing Substructures -- Unpacks the Nature of Clumpy Star Formation and Quenching in Gravitationally Lensed Galaxies beyond Cosmic Noon
LEGGOS presents a uniform framework that jointly models lensing, photometry, and integral-field spectroscopy to disentangle stellar populations in clumps of high-redshift lensed galaxies.