Berezin integral explained

In mathematical physics, the Berezin integral, named after Felix Berezin, (also known as Grassmann integral, after Hermann Grassmann), is a way to define integration for functions of Grassmann variables (elements of the exterior algebra). It is not an integral in the Lebesgue sense; the word "integral" is used because the Berezin integral has properties analogous to the Lebesgue integral and because it extends the path integral in physics, where it is used as a sum over histories for fermions.

Definition

Let

Λn

be the exterior algebra of polynomials in anticommuting elements

\theta1,...,\thetan

over the field of complex numbers. (The ordering of the generators

\theta1,...,\thetan

is fixed and defines the orientation of the exterior algebra.)

One variable

The Berezin integral over the sole Grassmann variable

\theta=\theta1

is defined to be a linear functional

\int[af(\theta)+bg(\theta)]d\theta=a\intf(\theta)d\theta+b\intg(\theta)d\theta,a,b\in\C

where we define

\int\thetad\theta=1,    \intd\theta=0

so that :

\int

\partial{\partial\theta}f(\theta)d\theta
=

0.

These properties define the integral uniquely and imply

\int(a\theta+b)d\theta=a,a,b\in\C.

Take note that

f(\theta)=a\theta+b

is the most general function of

\theta

because Grassmann variables square to zero, so

f(\theta)

cannot have non-zero terms beyond linear order.

Multiple variables

The Berezin integral on

Λn

is defined to be the unique linear functional
\int
Λn

rm{d}\theta

with the following properties:
\int
Λn

\thetan\theta1d\theta=1,

\int
Λn
\partialf
\partial\thetai

d\theta=0,i=1,...,n

for any

f\inΛn,

where

\partial/\partial\thetai

means the left or the right partial derivative. These properties define the integral uniquely.

Notice that different conventions exist in the literature: Some authors define instead[1]

\int
Λn

\theta1\thetand\theta:=1.

The formula

\int
Λn

f(\theta)

d\theta=\int
Λ1

\left(

\int
Λ1
\left(\int
Λ1

f(\theta)d\theta1\right)d\theta2\right)d\thetan

expresses the Fubini law. On the right-hand side, the interior integral of a monomial

f=g(\theta')\theta1

is set to be

g(\theta'),

where

\theta'=\left(\theta2,\ldots,\thetan\right)

; the integral of

f=g(\theta')

vanishes. The integral with respect to

\theta2

is calculated in the similar way and so on.

Change of Grassmann variables

Let

\thetai=\thetai\left(\xi1,\ldots,\xin\right),i=1,\ldots,n,

be odd polynomials in some antisymmetric variables

\xi1,\ldots,\xin

. The Jacobian is the matrix

D=\left\{

\partial\thetai
\partial\xij

,i,j=1,\ldots,n\right\},

where

\partial/\partial\xij

refers to the right derivative (

\partial(\theta1\theta2)/\partial\theta2=\theta1,\partial(\theta1\theta2)/\partial\theta1=-\theta2

). The formula for the coordinate change reads

\intf(\theta)d\theta=\intf(\theta(\xi))(\detD)-1d\xi.

Integrating even and odd variables

Definition

Consider now the algebra

Λm\mid

of functions of real commuting variables

x=x1,\ldots,xm

and of anticommuting variables

\theta1,\ldots,\thetan

(which is called the free superalgebra of dimension

(m|n)

). Intuitively, a function

f=f(x,\theta)\inΛm\mid

is a function of m even (bosonic, commuting) variables and of n odd (fermionic, anti-commuting) variables. More formally, an element

f=f(x,\theta)\inΛm\mid

is a function of the argument

x

that varies in an open set

X\subset\Rm

with values in the algebra

Λn.

Suppose that this function is continuous and vanishes in the complement of a compact set

K\subset\Rm.

The Berezin integral is the number
\int
Λm\mid

f(x,\theta)d\theta

dx=\int
\Rm

dx

\int
Λn

f(x,\theta)d\theta.

Change of even and odd variables

Let a coordinate transformation be given by

xi=xi(y,\xi),i=1,\ldots,m;\thetaj=\thetaj(y,\xi),j=1,\ldots,n,

where

xi

are even and

\thetaj

are odd polynomials of

\xi

depending on even variables

y.

The Jacobian matrix of this transformation has the block form:
J=\partial(x,\theta)
\partial(y,\xi)

=\begin{pmatrix}A&B\C&D\end{pmatrix},

where each even derivative

\partial/\partialyj

commutes with all elements of the algebra

Λm\mid

; the odd derivatives commute with even elements and anticommute with odd elements. The entries of the diagonal blocks

A=\partialx/\partialy

and

D=\partial\theta/\partial\xi

are even and the entries of the off-diagonal blocks

B=\partialx/\partial\xi,C=\partial\theta/\partialy

are odd functions, where

\partial/\partial\xij

again mean right derivatives.

We now need the Berezinian (or superdeterminant) of the matrix

J

, which is the even function

\operatorname{Ber}J=\det\left(A-BD-1C\right)\detD-1

defined when the function

\detD

is invertible in

Λm\mid.

Suppose that the real functions

xi=xi(y,0)

define a smooth invertible map

F:Y\toX

of open sets

X,Y

in

\Rm

and the linear part of the map

\xi\mapsto\theta=\theta(y,\xi)

is invertible for each

y\inY.

The general transformation law for the Berezin integral reads

\begin{align} &

\int
Λm\mid

f(x,\theta)d\thetadx=

\int
Λm\mid

f(x(y,\xi),\theta(y,\xi))\varepsilon\operatorname{Ber}Jd\xidy\\[6pt] ={}

&\int
Λm\mid

f(x(y,\xi),\theta(y,\xi))\varepsilon

\det\left(A-BD-1C\right)
\detD

d\xidy, \end{align}

where

\varepsilon=sgn(\det\partialx(y,0)/\partialy

) is the sign of the orientation of the map

F.

The superposition

f(x(y,\xi),\theta(y,\xi))

is defined in the obvious way, if the functions

xi(y,\xi)

do not depend on

\xi.

In the general case, we write

xi(y,\xi)=xi(y,0)+\deltai,

where

\deltai,i=1,\ldots,m

are even nilpotent elements of

Λm\mid

and set

f(x(y,\xi),\theta)=f(x(y,0),\theta)

+\sum
i\partialf
\partialxi

(x(y,0),\theta)\deltai+

1
2

\sumi,j

\partial2f
\partialxi\partialxj

(x(y,0),\theta)\deltai\deltaj+,

where the Taylor series is finite.

Useful formulas

The following formulas for Gaussian integrals are used often in the path integral formulation of quantum field theory:

\int\exp\left[-\thetaTAη\right]d\thetadη=\detA

with

A

being a complex

n x n

matrix.

\int\exp\left[-\tfrac{1}{2}\thetaTM\theta\right]d\theta=\begin{cases}PfM&neven\ 0&nodd\end{cases}

with

M

being a complex skew-symmetric

n x n

matrix, and

PfM

being the Pfaffian of

M

, which fulfills

(PfM)2=\detM

.

In the above formulas the notation

d\theta=d\theta1 … d\thetan

is used. From these formulas, other useful formulas follow (See Appendix A in[2]) :

\int\exp\left[\thetaTAη+\thetaTJ+KTη\right]dη1d\theta1...dηnd\thetan=\detA\exp[-KTA-1J]

with

A

being an invertible

n x n

matrix. Note that these integrals are all in the form of a partition function.

History

Berezin integral was probably first presented by David John Candlin in 1956.[3] Later it was independently discovered by Felix Berezin in 1966.[4]

Unfortunately Candlin's article failed to attract notice, and has been buried in oblivion. Berezin's work came to be widely known, and has almost been cited universally, becoming an indispensable tool to treat quantum field theory of fermions by functional integral.

Other authors contributed to these developments, including the physicists Khalatnikov[5] (although his paper contains mistakes), Matthews and Salam,[6] and Martin.[7]

See also

Further reading

Notes and References

  1. Book: Mirror symmetry. 2003. American Mathematical Society. Hori, Kentaro.. 0-8218-2955-6. Providence, RI. 155. 52374327.
  2. S. Caracciolo, A. D. Sokal and A. Sportiello,Algebraic/combinatorial proofs of Cayley-type identities for derivatives of determinants and pfaffians,Advances in Applied Mathematics,Volume 50, Issue 4,2013,https://doi.org/10.1016/j.aam.2012.12.001; https://arxiv.org/abs/1105.6270
  3. Nuovo Cimento . D.J. Candlin . 4 . On Sums over Trajectories for Systems With Fermi Statistics. 1956. 2 . 231–239. 10.1007/BF02745446. 1956NCim....4..231C. 122333001 .
  4. A. Berezin, The Method of Second Quantization, Academic Press, (1966)
  5. I.M.. Khalatnikov. 1955. Predstavlenie funkzij Grina v kvantovoj elektrodinamike v forme kontinualjnyh integralov. RU. Journal of Experimental and Theoretical Physics. 28. 3. 633. The Representation of Green's Function in Quantum Electrodynamics in the Form of Continual Integrals. 2019-06-23. 2021-04-19. https://web.archive.org/web/20210419060358/http://jetp.ac.ru/cgi-bin/dn/e_001_03_0568.pdf. dead.
  6. Matthews . P. T. . Salam . A. . Propagators of quantized field . Il Nuovo Cimento . Springer Science and Business Media LLC . 2 . 1 . 1955 . 0029-6341 . 10.1007/bf02856011 . 120–134. 1955NCimS...2..120M . 120719536 .
  7. J. L. . Martin . The Feynman principle for a Fermi system . Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences . The Royal Society . 251 . 1267 . 23 June 1959 . 2053-9169 . 10.1098/rspa.1959.0127 . 543–549. 1959RSPSA.251..543M . 123545904 .