Galaxy Zoo: Clump Scout: Surveying the Local Universe for Giant Star-forming Clumps

TL;DR

This study identifies and analyzes a large sample of low-redshift clumpy galaxies to understand the formation of giant star-forming clumps, revealing a decline in clump occurrence over cosmic time and supporting disk instability as the primary formation mechanism.

Contribution

It provides the largest low-redshift clumpy galaxy sample and links clump formation to galaxy turbulence rather than minor mergers.

Findings

Clumpy galaxy fraction declines sharply from z=0.5 to present.

Minor merger rate remains roughly constant over the same period.

Galaxy turbulence correlates with clump occurrence, supporting disk instability as the main formation process.

Abstract

Massive, star-forming clumps are a common feature of high-redshift star-forming galaxies. How they formed, and why they are so rare at low redshift, remains unclear. In this paper we identify the largest yet sample of clumpy galaxies (7,052) at low redshift using data from the citizen science project \textit{Galaxy Zoo: Clump Scout}, in which volunteers classified over 58,000 Sloan Digital Sky Survey (SDSS) galaxies spanning redshift $0.02 < z < 0.15$. We apply a robust completeness correction by comparing with simulated clumps identified by the same method. Requiring that the ratio of clump-to-galaxy flux in the SDSS $u$ band be greater than 8\% (similar to clump definitions used by other works), we estimate the fraction of local galaxies hosting at least one clump ($f_{clumpy}$) to be $2.68_{-0.30}^{+0.33}\%$. We also compute the same fraction with a less stringent cut of 3\% ($11.33_{-1.16}^{+0.89}\%$), as the higher number count and lower statistical noise of this fraction permits sharper comparison with future low-redshift clumpy galaxy studies. Our results reveal a sharp decline in $f_{clumpy}$ over $0 < z < 0.5$. The minor merger rate remains roughly constant over the same span, so we suggest that minor mergers are unlikely to be the primary driver of clump formation. Instead, the rate of galaxy turbulence is a better tracer for $f_{clumpy}$ over $0 < z < 1.5$ for galaxies of all masses, which supports the idea that clump formation is primarily driven by violent disk instability for all galaxy populations during this period.