Gradient RG Flow in Scalar-Fermion QFTs

TL;DR

This paper investigates the gradient property of the renormalisation group in scalar-fermion quantum field theories up to four-loop order, revealing scheme-independent conditions and the significance of the beta shift in conformal field theories.

Contribution

It provides a detailed analysis of the gradient RG flow conditions in scalar-fermion theories, highlighting the role of the beta shift and its implications for conformal field theories in various dimensions.

Findings

Over a thousand scheme-independent gradient-flow conditions identified.

The beta shift is crucial for the gradient property of RG flows.

Conformal field theories with non-zero beta shift dominate as the number of fields increases.

Abstract

The gradient property of the renormalisation group (RG) is examined to four-loop order in scalar-fermion systems in $d=4$ and $d=4-\varepsilon$ dimensions. The crucial role played by the beta shift, which is a modification of the standard dim-reg beta function, is elucidated, and specific conditions that it needs to satisfy for the RG flow to be gradient are derived. Over a thousand gradient-flow conditions are found, all of which are scheme-independent and satisfied whenever the full set of results needed to check them is available. It is shown, in the framework of the $\varepsilon=4-d$ expansion, that the space of conformal field theories (CFTs) is dominated by those with non-zero beta shift as the number of fields grows. Physical properties of CFTs obtained as solutions where the beta functions are not zero in the $\varepsilon$ expansion are discussed.