nLab fermionic path integral

Contents

Context

Quantum field theory

Physics

Super-Geometry

Integration theory

analytic integration	cohomological integration
measurable space	Poincaré duality
measure	orientation in generalized cohomology
volume form	(virtual) fundamental class
Riemann/Lebesgue integration of differential forms	push-forward in generalized cohomology/in differential cohomology

Analytic integration

integral calculus

Riemann integration, Lebesgue integration

line integral/contour integration

integration of differential forms

integration over supermanifolds, Berezin integral, fermionic path integral

Kontsevich integral, Selberg integral, elliptic Selberg integral

Cohomological integration

integration in ordinary differential cohomology

integration in differential K-theory

Riemann-Roch theorem

Variants

Lie integration

path integral

Batalin-Vilkovisky integral

Idea
Setup
Pfaffian bundles
Examples
Related concepts

Idea

The path integral over the fermionic variables of the standard kinetic action functional for fermions (see for instance spinors in Yang-Mills theory) has a well-defined meaning as a section of the Pfaffian line bundle of the corresponding Dirac operator.

Setup

For definiteness, we consider a sigma model quantum field theory on a worldvolume $\Sigma$ and pseudo-Riemannian target spacetime $X$ with fields

bosons: smooth functions $\phi : \Sigma \to X$
fermions (gravitino): $\psi \in \Gamma(S(\Sigma) \otimes \phi^* T X)$ , sections of the tensor product of a spinor bundle on $\Sigma$ and the pullback of the cotangent bundle of $X$ along the given bosonic field $\phi$ .

The action functional

S : (\phi, \psi) \mapsto S^{bos}(\phi) + S^{ferm}_{\phi}(\psi)

is the sum of the

bosonic action

$S^{bos}(\phi) = \int_\Sigma \langle d \phi \wedge \star d \phi\rangle$
fermionic action

$S^{ferm}_\phi(\psi) = \int_\Sigma \langle \psi, D_\phi \psi\rangle$

where $D_\phi$ is a Dirac operator on $S \otimes \phi^* T M$ (the Dirac operator on $S$ twisted by the pullback of the Levi-Civita connection on $T^* X$ ).

One imagines than that the hypothetical path integral symboilically written as

\int [d \phi] [d \psi] \exp(S(\psi)(\phi,\psi))

can be computed in two steps

\cdots = \int [d \phi] \exp(S^{bos}(\phi)) \left( \int [d \psi] \exp(S^{ferm}_\phi(\psi)) \right)

by first computing the integral over the fermions

pfaff(\phi) := \int [d \psi] \exp(S^{ferm}_\phi(\psi))

and then inserting this into the remaining bosonic integral. Now, as opposed to the bosonic integral, this fermionic integral can be given well-defined sense by interpreting it as an infinite-dimensional Berezinian integral.

However, while this makes the expression well defined, the result is not quite a function of $\phi$ , but is instead a section $pfaff$ of a Pfaffian line bundle

\array{ && Pfaff \\ {}^{pfaff := Z_{eff}^{ferm}}\nearrow & \downarrow \\ C^{\infty}(\Sigma, X) &= & C^{\infty}(\Sigma, X) }

over the space of bosonic field configurations.

If $Pfaff$ is not isomorphic to the trivial line bundle, we say the system has a fermionic quantum anomaly. If instead $Pfaff$ is trivializable, any choice of trivialization

t : Paff \stackrel{\simeq}{\to} C^\infty(\Sigma, X) \times \mathbb{C}

makes the fermionic path integral into a genuine function

Z_{eff}^{ferm} : = (t \circ pfaff) : C^\infty(\Sigma, X) \to \mathbb{C} \,.

Any such choice of $t$ is called a choice of quantum integrand.

With this one can then try to enter the remaining bosonic path integral

\int [d \phi] \exp(S^{bos}(\phi)) Z_{eff}^{ferm}(\phi)

Pfaffian bundles

We are implicitly assuming that $dim \Sigma = 2$ or maybe $8 n + 2$ in the following. Needs to be generalized.

For $n \in \mathbb{N}$ , there the square root of the determinant of a skew symmetric $(n\times n)$ -matrix $D$ – the Pfaffian of the matrix – can be understood as the Berezinian integral

pfaff(D) = \int [d \vec \theta] \exp( \langle \theta , D \theta\rangle) \in det \mathbb{R}^n

over the Grassmann algebra elements $\theta_i$ . Written this way this is an element of the determinant line of $\mathbb{R}^n$ : its identification with a number depends on the choice of basis for $\mathbb{R}^n$ . For this case this is unproblematic, since there is a canonical choice of basis for the single vector space $\mathbb{R}^n$ , but when $D$ instead depends on a parameter $\phi$ , then in general its Pfaffian can at best be a section of a determinant line bundle.

We now generalize this to the case that $D$ is not a finite-dimensional matrix, but a Dirac operator acting on spaces of sections of a spinor bundle. We discuss that we can reduce this “infinite-dimensional matrix” in a sense locally to a finite dimensional one in a consistent way, such that the above ordinary construction of Pfaffians applies.

In the above setup, write

\mathcal{H}_\phi^{\pm} := \Gamma(S^{\pm} \otimes \phi^* T^* X)

for the space of spinor sections for given $\phi : \Sigma \to X$ . Then the choral Dirac operators a maps

D_\phi^{\pm} : \mathcal{H}_\phi^{\pm} \to \mathcal{H}^{\mp}_\phi \,.

We also have a “quaternionic structure”

J_\phi^{\pm} : \mathcal{H}_\phi^{\pm} \to \mathcal{H}^{\mp}_\phi

Define then an open cover of the space $C^\infty(\Sigma,X)$ of the space of bosonic fields with open sets $U_\mu$ for $(0 \leq \mu)$ given by

U_\mu := \{ \phi \in C^\infty(\Sigma,X) | \mu \nin Spec D_\phi^2\} \,,

hence the collection of bosonic field configurations such that $\mu$ is not in the operator spectrum of the squared Dirac operator.

Over these open subsets we have the finite rank vector bundles

\mathcal{H}_\phi^{\mu \pm} := \oplus_{0 \leq \epsilon \leq \mu} Eig(D_\phi^2, \epsilon)

of eigenspaces of $D_\phi^2$ for eigenvalues bounded by $\mu$ .

The Dirac operator that we are interested in is

D_\phi^\mu := J_\phi^- \circ D_\phi^+ : \mathcal{H}_\phi^{\mu,+} \to \mathcal{H}_\phi^{\mu,+} \,.

This defines now a finite-dimensional matrix

\langle -, D_\phi^\mu -\rangle

whose Berezinian integral is the Pfaffian

\int [d \psi] \exp(\langle \psi , D^\mu_\phi \psi \rangle ) = pfaff(D^\mu_\phi) \in det \mathcal{H}^{\mu \pi}_\phi \,.

One shows that these constructions for each $\mu$ glue together to define

a smooth line bundle $Pfaff \to C^\infty(\Sigma, X)$
with a smooth section $pfaff(D)$ .

Moreover, there is canonically a Hermitian metric and a canonical unitary connection on a bundle (the Freed-Bismut connection?) on this bundle.

Examples

For the sigma model describing the heterotic superstring propagating on a pseudo-Riemannian manifold $X$ , the trivialization of the Pfaffian line bundle, hence the cancellation of its fermionic quantum anomaly is related to the existence of a (twisted) differential string structure on $X$ . See there for more details.

Related concepts

Last revised on April 23, 2024 at 15:07:17. See the history of this page for a list of all contributions to it.

nLab fermionic path integral

Context

Quantum field theory

Contents

Physics

Surveys, textbooks and lecture notes

Super-Geometry

Background

Introductions

Superalgebra

Supergeometry

Supersymmetry

Supersymmetric field theory

Applications

Integration theory

Analytic integration

Cohomological integration

Variants

Contents

Idea

Setup

Pfaffian bundles

Examples

Related concepts