Loop integral explained

In quantum field theory and statistical mechanics, loop integrals are the integrals which appear when evaluating the Feynman diagrams with one or more loops by integrating over the internal momenta.^[1] These integrals are used to determine counterterms, which in turn allow evaluation of the beta function, which encodes the dependence of coupling

for an interaction on an energy scale

\mu

One-loop integral

Generic formula

A generic one-loop integral, for example those appearing in one-loop renormalization of QED or QCD may be written as a linear combination of terms in the form

\int

	d^dk
	(2\pi)^d

…

k
	\mu_n

\mu₁

((k+q

	2
m
	b)

	2)
m
	b

where the

q_i

are 4-momenta which are linear combinations of the external momenta, and the

m_i

are masses of interacting particles. This expression uses Euclidean signature. In Lorentzian signature the denominator would instead be a product of expressions of the form

(k+q)²-m²+i\epsilon

Using Feynman parametrization, this can be rewritten as a linear combination of integrals of the form

\int

	d^dl
	(2\pi)^d

…

l
	\mu_n

\mu₁

(l²+\Delta)^b

where the 4-vector

and

\Delta

are functions of the

q_i,m_i

and the Feynman parameters. This integral is also integrated over the domain of the Feynman parameters. The integral is an isotropic tensor and so can be written as an isotropic tensor without

dependence (but possibly dependent on the dimension

), multiplied by the integral

\int

	d^dl
	(2\pi)^d

	(l²⁾^a
	(l²+\Delta)^b

Note that if

were odd, then the integral vanishes, so we can define

n=2a

Regularizing the integral

Cutoff regularization

In Wilsonian renormalization, the integral is made finite by specifying a cutoff scale

Λ>0

. The integral to be evaluated is then

\int^Λ

	d^dl
	(2\pi)^d

	(l²⁾^a
	(l²+\Delta)^b

where

\int^Λ

is shorthand for integration over the domain

\{l\inR^d:|l|<Λ\}

. The expression is finite, but in general as

Λ → infty

, the expression diverges.

Dimensional regularization

The integral without a momentum cutoff may be evaluated as

I_{d(b,a,\Delta)}:=

\int
	R^d

	d^dl
	(2\pi)^d

	(l²⁾^a
	(l²+\Delta)^b

	1
	(4\pi)^d/2

	1	B\left(b-a-
	\Gamma(d/2)

	d
	2

,a+

	d
	2

\right)\Delta^-(b-a-d/2),

where

is the Beta function. For calculations in the renormalization of QED or QCD,

takes values

0,1

and

For loop integrals in QFT,

actually has a pole for relevant values of

a,b

and

. For example in scalar

\phi⁴

theory in 4 dimensions, the loop integral in the calculation of one-loop renormalization of the interaction vertex has

(a,b,d)=(0,2,4)

. We use the 'trick' of dimensional regularization, analytically continuing

d=4-\epsilon

with

\epsilon

a small parameter.

For calculation of counterterms, the loop integral should be expressed as a Laurent series in

\epsilon

. To do this, it is necessary to use the Laurent expansion of the Gamma function,

\Gamma(\epsilon)=

	1
	\epsilon

-\gamma+l{O}(\epsilon)

where

\gamma

is the Euler–Mascheroni constant. In practice the loop integral generally diverges as

\epsilon → 0

For full evaluation of the Feynman diagram, there may be algebraic factors which must be evaluated. For example in QED, the tensor indices of the integral may be contracted with Gamma matrices, and identities involving these are needed to evaluate the integral. In QCD, there may be additional Lie algebra factors, such as the quadratic Casimir of the adjoint representation as well as of any representations that matter (scalar or spinor fields) in the theory transform under.

Examples

Scalar field theory

φ⁴ theory

The starting point is the action for

\phi⁴

theory in

R^d

S[\phi_0]=\int

dx	1
	2

(\partial

	2
\phi
	0)

	1
	2

m_0\phi

	2

	0

	1
	4!

λ_0\phi

	4.

	0

Where

	2
(\partial\phi
	0)

=\nabla\phi_{0 ⋅ \nabla\phi}₀=

	d
\sum
	i=1

\partial_i\phi_0\partial_i\phi₀

. The domain is purposefully left ambiguous, as it varies depending on regularisation scheme.

The Euclidean signature propagator in momentum space is

	2
m
	0

The one-loop contribution to the two-point correlator

\langle\phi(x)\phi(y)\rangle

(or rather, to the momentum space two-point correlator or Fourier transform of the two-point correlator) comes from a single Feynman diagram and is

	λ₀
	2

\int

	d^dk
	(2\pi)^d

	2
m
	0

This is an example of a loop integral.

d\geq2

and the domain of integration is

R^d

, this integral diverges. This is typical of the puzzle of divergences which plagued quantum field theory historically. To obtain finite results, we choose a regularization scheme. For illustration, we give two schemes.

Cutoff regularization: fix

Λ>0

. The regularized loop integral is the integral over the domain

k=|k|<Λ,

and it is typical to denote this integral by

	λ₀
	2

\int^Λ

	d^dk
	(2\pi)^d

	2
m
	0

This integral is finite and in this case can be evaluated.

Dimensional regularization: we integrate over all of

R^d

, but instead of considering

to be a positive integer, we analytically continue

d=n-\epsilon

, where

\epsilon

is small. By the computation above, we showed that the integral can be written in terms of expressions which have a well-defined analytic continuation from integers

to functions on

: specifically the gamma function has an analytic continuation and taking powers,

x^d

, is an operation which can be analytically continued.

Notes and References

Book: Michael E. Peskin . Michael E. . Peskin . Daniel V. . Schroeder . An Introduction to Quantum Field Theory . registration. 1995. 9780201503975 .

Loop integral explained

One-loop integral

Generic formula

Regularizing the integral

Cutoff regularization

Dimensional regularization

Examples

Scalar field theory

φ⁴ theory

See also

Further reading

Notes and References

Loop integral explained

One-loop integral

Generic formula

Regularizing the integral

Cutoff regularization

Dimensional regularization

Examples

Scalar field theory

φ4 theory

See also

Further reading

Notes and References

φ⁴ theory