# Strong lensing reveals jets in a sub-microJy radio quiet quasar

**Authors:** P. Hartley, N. Jackson, D. Sluse, H. R. Stacey, H. Vives-Arias

arXiv: 1901.05791 · 2019-03-06

## TL;DR

This study uses gravitational lensing and VLBI imaging to detect jets in a very faint radio quiet quasar, challenging the idea that such quasars lack AGN-driven radio emission and revealing complex lensing mass structures.

## Contribution

First direct imaging of jets in a sub-microJy radio quiet quasar at 0.27 pc resolution, showing AGN activity in the faintest radio sources and implications for the radio--FIR correlation.

## Key findings

- Detected jets in the faintest radio source ever imaged.
- Showed radio quiet quasars can host AGN-driven jets.
- Revealed dark matter substructure through lensing perturbations.

## Abstract

We present e-MERLIN and EVN observations which reveal unambiguous jet activity within radio quiet quasar HS~0810+2554. With an intrinsic flux density of 880~nJy, this is the faintest radio source ever imaged. The findings present new evidence against the idea that radio loud and radio quiet quasars are powered by different underlying radio emission mechanisms, showing instead that the same AGN mechanism can operate as the dominant source of radio emission even in the very lowest radio luminosity quasars. Thanks to strong gravitational lensing, our source is not only visible, but with VLBI is imaged to a scale of just 0.27~pc: the highest ever resolution image of a radio quiet quasar. Brightness temperatures of at least $8.4\times 10^6$~K are associated with two highly compact components, and subsequent modelling of the lensed system has revealed that the components are linearly aligned on opposing sides of the optical quasar core, with the typical morphology of a compact symmetric object (CSO). Given that this source has been found to fall on the radio--FIR correlation, we suggest that the radio--FIR correlation cannot always be used to rule out AGN activity in favour of star-formation activity. The correlation -- or at least its scatter -- may conceal the coexistence of kinetic and radiative feedback modes in AGN. Modelling of the lensing mass itself points to a non-smooth mass distribution, hinting at the presence of dark matter substructure which has manifested as astrometric perturbations of the VLBI lensed images, posing no threat to the CDM paradigm.

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/1901.05791/full.md

## References

122 references — full list in the complete paper: https://tomesphere.com/paper/1901.05791/full.md

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Source: https://tomesphere.com/paper/1901.05791