User:EverettYou/Notes on QFT

In statistical field theory, the partition function reads

$Z\equiv e^{-F}=\int\mathcal{D}[\psi]\,e^{-S[\psi]}$.

In the path integral formalism, the free energy (functional) $F$ is obtained from the action $S$ by integrating out the $\psi$ field, denoted as a transformation from the action into the free energy.

$S[\psi]\overset{\int\psi}{\longrightarrow} F.$

The factor $\beta$ (inverse temperature) has been absorbed into the (dimensionless) free energy $F$.

If the action is of quadratic form

$S[\psi]=\psi^\dagger\cdot K \cdot\psi,$

then Gaussian integral can be performed to obtain the free energy, and hence the correlations of the field. The operator $K$ is the kernel of the action, whose explicit form depends on the dynamics of the field. The following two types of dynamics are of interests.

Equation of motion

$-\partial_\tau\psi=H\cdot\psi.$

In the frequency representation ($\partial_\tau=-\mathrm{i}\omega$),

$\mathrm{i}\omega\psi=H\cdot\psi.$

So the kernel of the action is

$K = -\mathrm{i}\omega + H.$

The convension is that $H$ is of the same sign as $K$ (or the action $S$), because the path integral is derived from $Z=\operatorname{Tr} e^{-H}$. As a consequence, every term lowering from the action (or raising to the action) will aquire a minus sign.

Equation of motion in imaginary time ($\tau=\mathrm{i}t$),

$(-\partial_\tau^2 + \Omega^2)\cdot\psi=0.$

In the frequency representation ($\partial_\tau=-\mathrm{i}\omega$),

$(-(\mathrm{i}\omega)^2 + \Omega^2)\cdot\psi=0.$

So the kernel of the action is

$K = -(\mathrm{i}\omega)^2 + \Omega^2.$

Here $\pm\Omega$ plays the role of boson energy.

Free energy is obtained from the action by integrating out the field

$F=\operatorname{sTr}\ln K.$

sTr denotes the supertrace, which equals to Tr for bosonic fields and -Tr for fermionic fields.

The Matsubara frequency summation can be carried out given the specific form of the kernel $K$. For diffusive dynamics, the result is

$F=\operatorname{sTr}\ln(1-\eta e^{-\beta H}).$

For wave dynamics, the result is

$F=2\operatorname{Tr}\ln 2 \operatorname{sinh}\frac{\beta\Omega}{2}$ (bosonic),

$F=-2\operatorname{Tr}\ln 2\mathrm{i} \operatorname{cosh}\frac{\beta\Omega}{2}$ (fermionic).

To probe the field correlation, a source term coupled with the field is introduced. The quadratic action becomes

$S[\psi]=\psi^\dagger\cdot K \cdot\psi - J^\dagger\cdot\psi - \psi^\dagger\cdot J.$

Integrating over the field leads to the free energy with source

$F[J]=\operatorname{sTr}\ln K -J^\dagger\cdot K^{-1}\cdot J,$

where $\eta$ depends on the statistics of the field (bosonic: $\eta=+1$, fermionic: $\eta=-1$).

The negative free energy $\ln Z[J]=-F[J]$ serves as the generator of connected diagrams (i.e. the cumulants),

$\langle\psi(1)\psi^\dagger(2)\cdots\rangle_\text{con}= - \left.\delta_{J^\dagger(1)}\eta\delta_{J(2)}\cdots F[J]\right|_{J=0}.$

Note that the arrangement of the derivatives $\delta_{J^\dagger}$, $\eta\delta_J$ should follow the same ordering as that of the fields $\psi$, $\psi^\dagger$ in the vacuum expectation value (the ordering is particularly important for the Grassmann field). Note that each $\eta\delta_{J}$ operator must carry a statistical sign $\eta$, because the operator must commute through the field $\psi^\dagger$ to reach the field $J$, i.e. $\eta\delta_{J}\psi^\dagger\cdot J=\psi^\dagger\cdot\delta_{J}J=\psi^\dagger$, which will cosume the sign $\eta$. Intuitively, $-F$ can be considered as a kind of averaged $\langle -S\rangle\sim\langle J^\dagger\cdot\psi + \psi^\dagger\cdot J\rangle$, therefore applying the derivative operators on $-F$ yields the fields.

Define the bilinear correlation function (aka Green's function)

$G \equiv -\langle \psi\psi^\dagger \rangle_\text{con} = -\longleftarrow = - K^{-1}$.

It is diagrammatically represented as a line propagating from right to left (creation followed by annihilation, representing $\langle \psi\psi^\dagger\rangle_\text{con}$) with a minus sign in the front. The bilinear correlation function can be evaluated from

$\langle \psi\psi^\dagger \rangle_\text{con}=-\delta_{J^\dagger}\eta\delta_{J}F[J]=\delta_{J^\dagger}\eta\delta_{J}J^\dagger\cdot K^{-1}\cdot J=K^{-1}.$

This result is universal for both bosonic and fermionic fields.

Reversing the ordering leads to transpose of the correlation function and a statistical sign $\eta$ (+1 for bosons, -1 for fermions),

$\langle (\psi^\dagger)^\intercal \psi^\intercal \rangle_\text{con} = \eta (K^{-1})^\intercal = - \eta G^\intercal.$

So the advantage of defining the propagator as $-\langle\psi\psi^\dagger\rangle$ other than $\langle(\psi^\dagger)^\intercal\psi^\intercal\rangle$ is to avoid both the transpose field indices and the statistical sign dependancy.

The response to perturbations is simply obtained by partial derivatives. By introducing the Green's function $G=-K^{-1}$, the results can be written in a compact from: to the first order

$\partial_\mu F= -\operatorname{sTr} G\cdot\partial_\mu K,$

and to the second order,

$\partial_\mu\partial_\nu F= -\operatorname{sTr} G\cdot\partial_\mu \partial_\nu K - \operatorname{sTr} G\cdot\partial_\mu K\cdot G\cdot\partial_\nu K.$

This is because by definition $G\cdot K=-1$, so $\partial (G\cdot K)=0$, from which we have $\partial G = G\cdot \partial K \cdot G$.

Consider trilinear vertex terms

${\displaystyle S[\psi _{a},\psi _{b}]=\psi _{a}^{\dagger }\cdot K_{a}\cdot \psi _{a}+\psi _{b}^{\dagger }\cdot K_{b}\cdot \psi _{b}+(V^{\dagger }\vdots \psi _{a}^{\dagger }\psi _{a}\psi _{b}+h.c.)}$ .

Integrating out field ψ_b results in the effective action for ψ_a.

${\displaystyle S[\psi _{a},\psi _{b}]\;{\overset {\int \psi _{b}}{\longrightarrow }}\;S[\psi _{a}]=\psi _{a}^{\dagger }\cdot K_{a}\cdot \psi _{a}-\psi _{a}^{\dagger }\psi _{a}:V^{\dagger }\cdot K_{b}^{-1}\cdot V:\psi _{a}^{\dagger }\psi _{a}+\operatorname {sTr} K_{b}}$ .

This correspond to a tree diagram, which leads to the effective interaction of the field ψ_a.

Integrating out field ψ_a results in the effective action for ψ_b.

${\displaystyle S[\psi _{a},\psi _{b}]\;{\overset {\int \psi _{a}}{\longrightarrow }}\;S[\psi _{b}]=\operatorname {sTr} (K_{a}+V^{\dagger }\cdot \psi _{b}+\psi _{b}^{\dagger }\cdot V)+\psi _{b}^{\dagger }\cdot K_{b}\cdot \psi _{b}}$ ,

which may be expand to the 2nd order of ψ_b

${\displaystyle S[\psi _{b}]=\psi _{b}^{\dagger }\cdot (K_{b}-\operatorname {sTr} G_{a}\cdot V\cdot G_{a}\cdot V^{\dagger })\cdot \psi _{b}+\operatorname {sTr} K_{a}}$ .

This corresponds to a loop diagram, which gives the self-energy correction Σ_a to the action kernel K_a

${\displaystyle \Sigma _{a}=-\operatorname {sTr} G_{a}\cdot V\cdot G_{a}\cdot V^{\dagger }}$ ,

such that K_a → K_a+Σ_a.

If the field action is in a quadratic form of the field, Gaussian integral can be performed to obtained the effective action.

With source J:

${\displaystyle {\frac {1}{2}}\psi ^{\text{T}}\cdot K\cdot \psi -J^{\text{T}}\cdot \psi \;{\overset {\int \psi }{\longrightarrow }}\;{\frac {1}{2}}\operatorname {sTr} \ln K-{\frac {1}{2}}J^{\text{T}}\cdot K^{-1}\cdot J}$ .

With source J:

${\displaystyle \psi ^{\dagger }\cdot K\cdot \psi -J^{\dagger }\cdot \psi -\psi ^{\dagger }\cdot J\;{\overset {\int \psi }{\longrightarrow }}\;\operatorname {sTr} \ln K-J^{\dagger }\cdot K^{-1}\cdot J}$ .

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