Comparative tests of accretion rates of quasars derived using a new empirical and an existing theoretical relation: Insights into black hole properties and growth

A scaling relation based on thin-disc accretion theory has been used by some workers to determine the mass-inflow rate onto 20 high-redshift (z) and 80 Palomar-Green quasars. Based on several assumptions, it inexplicably implies that the inflow rate is an inverse function of black-hole (BH) mass Mbh...

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Bibliographic Details
Published in:arXiv.org 2023-06
Main Author: Aggarwal, Yash
Format: Article
Language:English
Subjects:
Deposition
Efficiency
Empirical analysis
Gas density
Inflow
Quasars
Red shift
Regression analysis
Temperature profiles
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Summary:A scaling relation based on thin-disc accretion theory has been used by some workers to determine the mass-inflow rate onto 20 high-redshift (z) and 80 Palomar-Green quasars. Based on several assumptions, it inexplicably implies that the inflow rate is an inverse function of black-hole (BH) mass Mbh. Moreover, its results remain untested. This paper offers a simple empirical relation essentially free of assumptions, found using available data for 59 highest-z quasars and the so-called Salpeter relation. We find that the accretion rate is proportional to Mbh(1+z)3, consistent with conventional astrophysics that the accretion rate is a direct function of both Mbh and the ambient gas density. We apply it to the 20 high-z and a subset of Palomar-Green quasars. Comparative analyses show that all empirically derived accretion rates and radiative efficiencies pass the tests, but their theoretical counterparts fail in most cases. A secondary relation defines the Eddington ratio as a function of z and radiative efficiency. Consistent with the empirical relations, spline regression analysis of Kozlowski's data for 132,000 quasars at z a billion solar masses, we get radiative efficiency of ~0.23 at z>5.7 and ~0.84 at z
ISSN:2331-8422