Radio-quiet quasars (RQQs) are a subclass of quasars characterized by their low emission in radio wavelengths compared to their optical and X-ray emissions. They are among the most luminous objects in the universe, powered by supermassive black holes at the centers of distant galaxies. RQQs provide important insights into the mechanisms of active galactic nuclei (AGNs) and the processes governing black hole accretion.

Quasars are a type of AGN that emit enormous amounts of energy across the electromagnetic spectrum. They are typically classified based on their radio emissions into two categories: radio-loud quasars (RLQs) and radio-quiet quasars (RQQs). RQQs are defined as those quasars that have radio luminosities significantly lower than those of RLQs, often with radio flux densities less than 10% of their optical flux densities.

RQQs exhibit strong emission lines in their optical and ultraviolet spectra, indicating the presence of gas surrounding the supermassive black hole. They often show a wide range of spectral features, including broad emission lines from ionized gas and narrow emission lines from the host galaxy. The lack of significant radio emission in RQQs is thought to be related to the accretion processes at work in these systems.

Studies of RQQs have revealed a correlation between their optical luminosity and the mass of the central black hole, similar to RLQs. The accretion rates in RQQs are generally high, suggesting that the central black holes are actively feeding on surrounding material. However, the mechanisms for energy output in RQQs may differ from those in RLQs, which often have relativistic jets contributing to their radio emission.^[1]

The host galaxies of RQQs tend to be more massive and more luminous than those of RLQs. RQQs are often found in environments conducive to star formation, and their host galaxies can exhibit significant morphological diversity, ranging from spiral to elliptical types. The presence of dust and gas in these galaxies can also influence the properties of the quasar.

Several models have been proposed to explain the differences between RQQs and RLQs. One hypothesis suggests that the orientation of the accretion disk plays a crucial role, with RQQs viewed edge-on lacking the relativistic jets that produce strong radio emissions. Another model posits that the intrinsic properties of the black holes and their accretion mechanisms lead to the dichotomy observed between the two classes.^[2]

RQQs have been the subject of extensive observational studies using ground-based and space telescopes. Surveys such as the Sloan Digital Sky Survey (SDSS) have identified a large number of RQQs, allowing for statistical analyses of their properties. Advanced techniques in spectroscopy and multi-wavelength observations continue to enhance our understanding of these fascinating objects.