Functional renormalization group explained

In theoretical physics, functional renormalization group (FRG) is an implementation of the renormalization group (RG) concept which is used in quantum and statistical field theory, especially when dealing with strongly interacting systems. The method combines functional methods of quantum field theory with the intuitive renormalization group idea of Kenneth G. Wilson. This technique allows to interpolate smoothly between the known microscopic laws and the complicated macroscopic phenomena in physical systems. In this sense, it bridges the transition from simplicity of microphysics to complexity of macrophysics. Figuratively speaking, FRG acts as a microscope with a variable resolution. One starts with a high-resolution picture of the known microphysical laws and subsequently decreases the resolution to obtain a coarse-grained picture of macroscopic collective phenomena. The method is nonperturbative, meaning that it does not rely on an expansion in a small coupling constant. Mathematically, FRG is based on an exact functional differential equation for a scale-dependent effective action.

The flow equation for the effective action

\Gamma

is an analogue of the classical action functional

S

and depends on the fields of a given theory. It includes all quantum and thermal fluctuations. Variation of

\Gamma

yields exact quantum field equations, for example for cosmology or the electrodynamics of superconductors. Mathematically,

\Gamma

is the generating functional of the one-particle irreducible Feynman diagrams. Interesting physics, as propagators and effective couplings for interactions, can be straightforwardly extracted from it. In a generic interacting field theory the effective action

\Gamma

, however, is difficult to obtain. FRG provides a practical tool to calculate

\Gamma

employing the renormalization group concept.

The central object in FRG is a scale-dependent effective action functional

\Gammak

often called average action or flowing action. The dependence on the RG sliding scale

k

is introduced by adding a regulator (infrared cutoff)

Rk

to the full inverse propagator
(2)
\Gamma
k
. Roughly speaking, the regulator

Rk

decouples slow modes with momenta

q\lesssimk

by giving them a large mass, while high momentum modes are not affected. Thus,

\Gammak

includes all quantum and statistical fluctuations with momenta

q\gtrsimk

. The flowing action

\Gammak

obeys the exact functional flow equation

k\partialk\Gammak=

1
2

STr k\partialkRk

(1,1)
(\Gamma
k

+

-1
R
k)

,

derived by Christof Wetterich and Tim R. Morris in 1993. Here

\partialk

denotes a derivative with respect to the RG scale

k

at fixed values of the fields. Furthermore,
(1,1)
\Gamma
k
denotes the functional derivative of

\Gammak

from the left-hand-side and the right-hand-side respectively, due to the tensor structure of the equation. This feature is often shown simplified by the second derivative of the effective action.The functional differential equation for

\Gammak

must be supplemented with the initial condition

\Gammak\toΛ=S

, where the "classical action"

S

describes the physics at the microscopic ultraviolet scale

k

. Importantly, in the infrared limit

k\to0

the full effective action

\Gamma=\Gammak\to

is obtained. In the Wetterich equation

STr

denotes a supertrace which sums over momenta, frequencies, internal indices, and fields (taking bosons with a plus and fermions with a minus sign). The exact flow equation for

\Gammak

has a one-loop structure. This is an important simplification compared to perturbation theory, where multi-loop diagrams must be included. The second functional derivative
(2)
\Gamma
k
(1,1)
=\Gamma
k
is the full inverse field propagator modified by the presence of the regulator

Rk

.

The renormalization group evolution of

\Gammak

can be illustrated in the theory space, which is a multi-dimensional space of all possible running couplings

\{cn\}

allowed by the symmetries of the problem. As schematically shown in the figure, at the microscopic ultraviolet scale

k

one starts with the initial condition

\Gammak=S

.

As the sliding scale

k

is lowered, the flowing action

\Gammak

evolves in the theory space according to the functional flow equation. The choice of the regulator

Rk

is not unique, which introduces some scheme dependence into the renormalization group flow. For this reason, different choices of the regulator

Rk

correspond to the different paths in the figure. At the infrared scale

k=0

, however, the full effective action

\Gammak=0=\Gamma

is recovered for every choice of the cut-off

Rk

, and all trajectories meet at the same point in the theory space.

In most cases of interest the Wetterich equation can only be solved approximately. Usually some type of expansion of

\Gammak

is performed, which is then truncated at finite order leading to a finite system of ordinary differential equations. Different systematic expansion schemes (such as the derivative expansion, vertex expansion, etc.) were developed. The choice of the suitable scheme should be physically motivated and depends on a given problem. The expansions do not necessarily involve a small parameter (like an interaction coupling constant) and thus they are, in general, of nonperturbative nature.

Note however, that due to multiple choices regarding (prefactor-)conventions and the concrete definition of the effective action, one can find other (equivalent) versions of the Wetterich equation in the literature.[1]

Aspects of functional renormalization

Rk

in a given (fixed) truncation and determine the difference of the RG flows in the infrared for the respective regulator choices. If bosonization is used, one can check the insensitivity of final results with respect to different bosonization procedures.

\beta

-functions approach zero. The presence of (partially) stable infrared fixed points is closely connected to the concept of universality. Universality manifests itself in the observation that some very distinct physical systems have the same critical behavior. For instance, to good accuracy, critical exponents of the liquid–gas phase transition in water and the ferromagnetic phase transition in magnets are the same. In the renormalization group language, different systems from the same universality class flow to the same (partially) stable infrared fixed point. In this way macrophysics becomes independent of the microscopic details of the particular physical model.

S

and the finite ultraviolet cutoff

Λ

.

Λ

. In FRG a more efficient way to incorporate macroscopic degrees of freedom was introduced, which is known as flowing bosonization or rebosonization. With the help of a scale-dependent field transformation, this allows to perform the Hubbard–Stratonovich transformation continuously at all RG scales

k

.

Functional renormalization-group for Wick-ordered effective interaction

Contrary to the flow equation for the effective action, this scheme is formulated for the effective interaction

l{V}[η,η+]=-ln

-1
Z[G
0

η,

-1
G
0

η+]

-1
G
0

η+

which generates n-particle interaction vertices, amputated by the bare propagators

G0

;

Z[η,η+]

is the "standard" generating functional for the n-particle Green functions.

The Wick ordering of effective interaction with respect to Green function

D

can be defined by

l{W}[η,η+]=\exp(-\Delta

+
D)l{V}[η,η

]

.

where

\Delta=D\delta2/(\deltaη\deltaη+)

is the Laplacian in the field space. This operation is similar to Normal order and excludes from the interaction all possible terms, formed by a convolution of source fields with respective Green function D. Introducing some cutoff

Λ

the Polchinskii equation
\partial
{\partialΛ
}(\psi) = -(\psi) + \Delta _^\mathcal _\Lambda ^\mathcal _\Lambda ^

takes the form of the Wick-ordered equation

{\partialΛ}{l{W}Λ}=-{\Delta

{{D

Λ}+{{

G}

0,Λ

}}} + \Delta _^\mathcal _\Lambda ^\mathcal _\Lambda ^

where

\Delta

{{G

0,Λ

}}^\mathcal _\Lambda ^\mathcal _\Lambda ^=\frac\left(\right)

Applications

The method was applied to numerous problems in physics, e.g.:

O(N)

-symmetric scalar theories in different dimensions

d

, including critical exponents for

d=3

and the Berezinskii–Kosterlitz–Thouless phase transition for

d=2

,

N=2

.

See also

References

Pedagogic reviews

Notes and References

  1. Book: Kopietz . Peter . Bartosch . Lorenz . Schütz . Florian . Introduction to the Functional Renormalization Group . 2010 . Springer . 9783642050947.