# Clustering with JWST: Constraining Galaxy Host Halo Masses, Satellite   Quenching Efficiencies, and Merger Rates at z=4-10

**Authors:** Ryan Endsley, Peter Behroozi, Daniel P. Stark, Christina C. Williams,, Brant E. Robertson, Marcia Rieke, Stefan Gottl\"ober, Gustavo Yepes

arXiv: 1907.02546 · 2020-02-12

## TL;DR

This paper demonstrates that JWST galaxy clustering measurements at high redshift (z=4-10) can accurately constrain galaxy host halo masses, satellite quenching, and merger rates, advancing understanding of early galaxy evolution.

## Contribution

It introduces a simulation framework for JWST clustering data, showing potential for precise measurements of halo masses, satellite quenching, and merger rates during reionization.

## Key findings

- Galaxy clustering measurable with >5σ at z=4-10.
- Halo mass precisions of 0.2-0.3 dex for different galaxy brightnesses.
- Identification of ~1000 satellites at z=4-8 for quenching studies.

## Abstract

Galaxy clustering measurements can be used to constrain many aspects of galaxy evolution, including galaxy host halo masses, satellite quenching efficiencies, and merger rates. We simulate JWST galaxy clustering measurements at z$\sim$4$-$10 by utilizing mock galaxy samples produced by an empirical model, the UniverseMachine. We also adopt the survey footprints and typical depths of the planned joint NIRCam and NIRSpec Guaranteed Time Observation program planned for Cycle 1 to generate realistic JWST survey realizations and to model high-redshift galaxy selection completeness. We find that galaxy clustering will be measured with $\gtrsim$5$\sigma$ significance at z$\sim$4$-$10. Halo mass precisions resulting from Cycle 1 angular clustering measurements will be $\sim$0.2 dex for faint (-18 $\gtrsim$ $\mathit{M}_{\mathrm{UV}}^{ }$ $\gtrsim$ -19) galaxies at z$\sim$4$-$10 as well as $\sim$0.3 dex for bright ($\mathit{M}_{\mathrm{UV}}^{ }$ $\sim$ -20) galaxies at z$\sim$4$-$7. Dedicated spectroscopic follow-up over $\sim$150 arcmin$^2$ would improve these precisions by $\sim$0.1 dex by removing chance projections and low-redshift contaminants. Future JWST observations will therefore provide the first constraints on the stellar-halo mass relation in the epoch of reionization and substantially clarify how this relation evolves at z$>$4. We also find that $\sim$1000 individual satellites will be identifiable at z$\sim$4$-$8 with JWST, enabling strong tests of satellite quenching evolution beyond currently available data (z$\lesssim$2). Finally, we find that JWST observations can measure the evolution of galaxy major merger pair fractions at z$\sim$4$-$8 with $\sim$0.1$-$0.2 dex uncertainties. Such measurements would help determine the relative role of mergers to the build-up of stellar mass into the epoch of reionization.

## Full text

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## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/1907.02546/full.md

## References

101 references — full list in the complete paper: https://tomesphere.com/paper/1907.02546/full.md

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Source: https://tomesphere.com/paper/1907.02546