How to obtain time-ordered density correlation function of free Bosonic system via Wick's theorem?

Question

Consider a free Bosonic system. The Hamiltonian is given by $$ H=\sum_k \frac{k^2}{2m}a_k^\dagger a_k. $$ Since the spectrum is gapless, the ground state can be of any particle number (or even superposition of different particle numbers) as long as all particles are in state $\vert k=0 \rangle$.

Now consider a particular bosonic condensed state with $N$ particles $\vert\Phi_0\rangle=\frac{(a_{k=0}^\dagger\ \ )^N}{\sqrt{N!}}\vert vac\rangle$. What is the time-ordered density correlation function defined as the following? $$ \langle\Phi_0\vert \hat{T}[\rho(x,t)\rho(0,0)]\vert\Phi_0\rangle $$ (This is Problem 3.1.2 in Wen's book)

I have done the problem by brute force (by which I mean I spanned all the states and operators and then evaluate them one by one.) My result is: $$ \begin{eqnarray} \langle\Phi_0\vert \hat{T}[\rho(x,t)\rho(0,0)]\vert\Phi_0\rangle&=&\theta(t)\langle \Phi_0\vert e^{iHt}a^\dagger(x)a(x)e^{-iHt}a^\dagger(0)a(0)\vert\Phi_0\rangle\\\ &+&\theta(-t)\langle \Phi_0\vert a^\dagger(0)a(0)e^{iHt}a^\dagger(x)a(x)e^{-iHt}\vert\Phi_0\rangle\\\ &=&\frac{N(N-1)}{V^2}+\frac{N}{V}\int\frac{\mathrm{d}k}{2\pi}[\theta(t)\exp(ikx-it\frac{k^2}{2m})+\theta(-t)\exp(-ikx+it\frac{k^2}{2m})], \end{eqnarray} $$ which indeed shows the off-diagonal long-range order of the system.

The calculation is a little bit painful. But as implied in the book, it should be obtained with Wick's theorem. However, I have some troubles:

1. The expectation value is evaluated in state $\Phi_0$ rather than vacuum. How do I use Wick's theorem in this case?
2. The book says "$a(x,t)$ is a linear combination of $a_k$ and $a_k^\dagger$" but I failed to prove it. Is it even right? I mean, using a Fourier transformation, $a(x)$ should only be involved with $a_k$ but no $a_k^\dagger$, and with the time-evolution operator $a(x,t)$ is more than just linear terms of $a_k$ and $a_k^\dagger$.

Answer 1

I have figured this out myself... The crucial point is that the non-equal time commutation relation $[a(t), a(t')]=0$ for free Bosonic fields (the same for $a^\dagger$).

(In the context of high energy physics, people usually use field operators $\phi(x)$ which involves with both $a_k$ and $a_k^\dagger$. This is because the dispersion relation is given by $E^2=p^2+m^2$. However, in our case, we will consider the non-relativistic limit $E=\frac{p^2}{2m}$ thus the field operator is just $\psi(x)=a(x)$ which is only related to $a_k$ but not $a_k^\dagger$.)

Now comes to the Wick's theorem. Things are perfectly nice when we are dealing with the vacuum state. However, here we are considering a ground state with $N$ particles. Of course, one may pull them out as $\vert\Phi_0\rangle=\frac{(a_0^\dagger)^N}{\sqrt{N!}}\vert vac\rangle$, but that is too many operator to contract! Let's use Wick Theorem here: $$ \begin{eqnarray} \hat{T}[a^\dagger(x,t)a(x,t)a^\dagger(0,0)a(0,0)]&=&:a^\dagger(x,t)a(x,t)a^\dagger(0,0)a(0,0):\\ &+&:a^\dagger(x,t)a(0,0):\langle vac\vert \hat{T}a(x,t)a^\dagger(0,0)\vert vac\rangle\\ &+&:a(x,t)a^\dagger(0,0):\langle vac\vert \hat{T}a(0,0)a^\dagger(x,t)\vert vac\rangle\\ &+&\langle vac \vert \hat{T}a^\dagger(x,t)a(0,0)\vert vac\rangle\langle vac\vert\hat{T}a(x,t)a^\dagger(0,0)\vert vac\rangle. \end{eqnarray} $$ (Terms containing $\langle vac\vert\hat{T}a^\dagger(x,t)a(x,t)\vert vac\rangle$ and $\langle vac\vert\hat{T}a^\dagger(0,0)a(0,0)\vert vac\rangle$ vanishes).

The last term containing $\theta(t)\theta(-t)$ so that it vanishes as well. So we are left with three terms.

The second and the third are easy to compute. I won't do it here (it is the first question under this problem in the book). What was confusing me is the first term:

How do I normal ordering it?

Should I first evolve $a(0,0)$ to $a(0,t)$ to make them at the same time then do the normal ordering? This will be too much compicated. Or should I just put the $a^\dagger$'s to the left of $a$'s ? If so, shall it be $a^\dagger(x,t)a^\dagger(0,0)a(x,t)a(0,0)$ or $a^\dagger(0,0)a^\dagger(x,t)a(x,t)a(0,0)$ or $a^\dagger(x,t)a^\dagger(0,0)a(0,0)a(x,t)$, or ...? The point is, I didn't realise it that $[a(x,t),a(0,0)]=0$ , since the Bosons are free, so that the order doesn't actually matter.

It is easy to see in $k$-space, $$ [H,a_k]=-\frac{k^2}{2m}a_k\Longrightarrow e^{iHt}a_k e^{-iHt}=\exp(-i\frac{k^2}{2m}t)a_k, $$ that the evolution of free Bosonic operator only gives rise to a phase factor so that $$ [a_k(t),a(0)]=0 $$ for all $t$. (That is, non-equal-time commutation relation is trivial as the equal-time one. This is only true if the field is free.) And then performing a Fourier transformation shows that $[a(x,t),a(0,0)]=0$ as well. I myself think this is not that trivial but few books talk about it. They just ignore all the time label when doing normal-ordering. A good reference about this is David Tong's lecture notes on QFT, Page 37. Moreover, non-equal-time commutation relation for $a$ and $a^\dagger$ is just a $c$-number rather than an operator for a free field. (We don't need this point here)

I think this means that the Wich's theorem is only a pertubative tool, which is not exact if interaction is turned on.

Now evaluate the operators in $\vert \Phi_0\rangle$, yields $$ \begin{eqnarray} \langle\Phi_0\vert\hat{T}\rho(x,t)\rho(0,0)\vert \Phi_0\rangle&=&\langle\Phi_0\vert (a(x,t)a(0,0))^\dagger (a(x,t)a(0,0))\vert \Phi_0\rangle\\ &+&\langle \Phi_0\vert a^\dagger(x,t)a(0,0)\vert \Phi_0\rangle\langle vac\vert\hat{T}a(x,t)a^\dagger(0,0)\vert vac\rangle\\ &+&\langle \Phi_0\vert a(x,t)a^\dagger(0,0)\vert \Phi_0\rangle\langle vac\vert\hat{T}a^\dagger(x,t)a(0,0)\vert vac\rangle. \end{eqnarray} $$ The first term can be evaluated by some trick: $(a(x)a(0))^\dagger$ can be somehow regarded as a pair creation operator so that $(aa)^\dagger(aa)$ is a pair-number operator which count how many pairs are in the state. Now that we have got $N$ Bosons in $\vert \Phi_0\rangle$, for each Boson there are $N-1$ to pair thus the number of pairs is $N(N-1)$ and the pair density is given by $\frac{N(N-1)}{V^2}$.

And then we end up with the same result: $$ \begin{eqnarray} \langle\Phi_0\vert\hat{T}\rho(x,t)\rho(0,0)\vert \Phi_0\rangle&=& \frac{N(N-1)}{V^2}\\ &+&\frac{N}{V}\int\frac{\mathrm{d}k}{2\pi}[\theta(t)\exp(ikx-it\frac{k^2}{2m})\\ &+&\theta(-t)\exp(-ikx+it\frac{k^2}{2m})]. \end{eqnarray} $$