# X-ray view of a massive node of the Cosmic Web at z=3 II. Discovery of extended X-ray emission around a hyperluminous QSO

**Authors:** Andrea Travascio, Sebastiano Cantalupo, Gabriele Pezzulli, Paolo Tozzi, Luca Di Mascolo, Michela Esposito, Titouan Lazeyras, Marika Lepore, Stefano Borgani, Martin Elvis, Giuseppina Fabbiano, Marta Galbiati, Nicholas Ledos, Riccardo Middei, Antonio Pensabene, Enrico Piconcelli, Giada Quadri, Fabio Vito, Weichen Wang, and Luca Zappacosta

arXiv: 2508.20074 · 2025-08-28

## TL;DR

This study reports the discovery of extended X-ray emission around a hyperluminous QSO at z=3, revealing hot gas in the circumgalactic medium with properties similar to those in galaxy clusters, providing insights into early hot halo formation.

## Contribution

First detection of extended hot X-ray emitting gas around a high-redshift QSO, characterizing its properties and implications for galaxy formation models.

## Key findings

- Hot gas temperature ~1.8 keV and mass ~2.6e12 solar masses.
- X-ray luminosity exceeds typical values for similar systems.
- Hot gas constitutes about 8.3% of the halo's virial mass.

## Abstract

While the warm, ionized gas in the CGM at z>3 is now routinely observed around bright QSOs in Lya emission, little is known about the CGM hot phase due to its expected faintness in the X-ray band, often referred to as the ICM. Here, we report the analysis of 634 ks of Chandra X-ray observations in the MQN01 Cosmic Node, a region containing one of the brightest Lya nebulae and the largest galaxy overdensity discovered so far at z>3. We detect 66 net counts of X-ray emission in the 0.5-2 keV band extending to at least 30 kpc from the brightest QSO in MQN01. The morphology and spectrum are consistent with thermal emission from hot plasma in CIE. Photoionization is negligible, and IC is disfavored. A joint spatial and spectral MCMC analysis provides consistency with a beta-model with a steep density profile and a gas temperature kT~1.8 keV and virial halo mass Mvir~3e13 Mo. The inferred hot gas mass is Mhot(<Rvir)~2.6e12 Mo, which is ~8.3% of Mvir, or ~56% of the theoretical cosmological baryon budget of the halo. The hot gas also emits an exceptionally high Lx, with a measured L2-10~2.3e45 erg/s within the central 30 kpc. This system is a clear outlier in the Lx-Tx plane, indicating a thermodynamic state distinct from that of evolved lower-redshift hot halos. The cooling time in the inner 15-30 kpc is comparable to the local dynamical time, suggesting that the gas could become locally unstable in the absence of heating or feedback. Moreover, the thermal pressure associated with the detected CGM hot phase is large enough to confine the cold and dense clumps, which are required to reproduce the high Lya emission associated with the inner regions of the MQN01 structure. Although limited to a single system, our results provide unique information on the multi-phase properties of the CGM and a view of the nascent thermal hot gas phase observed in local galaxy clusters.

## Full text

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## Figures

16 figures with captions in the complete paper: https://tomesphere.com/paper/2508.20074/full.md

## References

104 references — full list in the complete paper: https://tomesphere.com/paper/2508.20074/full.md

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Source: https://tomesphere.com/paper/2508.20074