Finished section deriving Hamiltonian
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@ -239,9 +239,10 @@ state we get
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\Psi(\b{r}) = \sum_i^M b_i w(\b{r} - \b{r}_i),
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\Psi(\b{r}) = \sum_i^M b_i w(\b{r} - \b{r}_i),
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\end{equation}
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\end{equation}
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where $b_i$ ($\bd_i$) is the annihilation (creation) operator of an
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where $b_i$ ($\bd_i$) is the annihilation (creation) operator of an
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atom at site $i$ with coordinate $\b{r}_i$ and $M$ is the number of
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atom at site $i$ with coordinate $\b{r}_i$, $w(\b{r})$ is the lowest
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lattice sites. Substituting this expression in Eq. \eqref{eq:FullH}
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band Wannier function, and $M$ is the number of lattice
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with $\H_{1,a} = \H_{1,a}^\mathrm{eff}$ and
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sites. Substituting this expression in Eq. \eqref{eq:FullH} with
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$\H_{1,a} = \H_{1,a}^\mathrm{eff}$ and
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$\H_{1,fa} = \H_{1,fa}^\mathrm{eff}$ given by Eq. \eqref{eq:aeff} and
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$\H_{1,fa} = \H_{1,fa}^\mathrm{eff}$ given by Eq. \eqref{eq:aeff} and
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\eqref{eq:faeff} respectively yields the following generalised
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\eqref{eq:faeff} respectively yields the following generalised
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Bose-Hubbard Hamiltonian, $\H = \H_f + \H_a + \H_{fa}$,
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Bose-Hubbard Hamiltonian, $\H = \H_f + \H_a + \H_{fa}$,
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@ -266,8 +267,135 @@ hopping rate given by
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\left( -\frac{\b{p}^2}{2 m_a} + V_\mathrm{cl}(\b{r}) \right) w(\b{r}
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\left( -\frac{\b{p}^2}{2 m_a} + V_\mathrm{cl}(\b{r}) \right) w(\b{r}
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- \b{r}_i),
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- \b{r}_i),
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\end{equation}
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\end{equation}
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and $U_{ijkl}$ is the interaction strength given by
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and $U_{ijkl}$ is the atomic interaction term given by
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\begin{equation}
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\begin{equation}
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U_{ijkl} = \frac{4 \pi a_s \hbar^2}{m_a} \int \mathrm{d}^3 \b{r}
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U_{ijkl} = \frac{4 \pi a_s \hbar^2}{m_a} \int \mathrm{d}^3 \b{r}
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w(\b{r} - \b{r}_i) w(\b{r} - \b{r}_j) w(\b{r} - \b{r}_k) w(\b{r} - \b{r}_l).
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w(\b{r} - \b{r}_i) w(\b{r} - \b{r}_j) w(\b{r} - \b{r}_k) w(\b{r} - \b{r}_l).
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\end{equation}
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\end{equation}
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Both integrals above depend on the overlap between Wannier functions
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corresponding to different lattice sites. This overlap decreases
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rapidly as the distance between sites increases. Therefore, in both
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cases we can simply neglect all terms but the one that corresponds to
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the most significant overlap. Thus, for $J_{i,j}^\mathrm{cl}$ we will
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only consider $i$ and $j$ that correspond to nearest neighbours.
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Furthermore, since we will only be looking at lattices that have the
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same separtion between all its nearest neighbours (e.g. cubic or
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square lattice) we can define $J_{i,j}^\mathrm{cl} = - J^\mathrm{cl}$
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(negative sign, because this way $J^\mathrm{cl} > 0$). For the
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inter-atomic interactions this simplifies to simply considering
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on-site collisions where $i=j=k=l$ and we define $U_{iiii} =
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U$. Finally, we end up with the canonical form for the Bose-Hubbard
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Hamiltonian
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\begin{equation}
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\H_a = -J^\mathrm{cl} \sum_{\langle i,j \rangle}^M \bd_i b_j +
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\frac{U}{2} \sum_{i}^M \hat{n}_i (\hat{n}_i - 1),
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\end{equation}
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where $\langle i,j \rangle$ denotes a summation over nearest
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neighbours and $\hat{n}_i = \bd_i b_i$ is the atom number operator at
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site $i$.
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Finally, we have the light-matter interaction part of the Hamiltonian
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given by
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\begin{equation}
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\H_{fa} = \frac{\hbar}{\Delta_a} \sum_{l,m} g_l g_m \ad_l \a_m
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\left( \sum_{i,j}^K J^{l,m}_{i,j} \bd_i b_j \right),
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\end{equation}
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where the coupling between the matter and optical fields is determined
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by the coefficients
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\begin{equation}
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J^{l,m}_{i,j} = \int \mathrm{d}^3 \b{r} w(\b{r} - \b{r}_i)
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u_l^*(\b{r}) u_m(\b{r}) w(\b{r} - \b{r}_j).
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\end{equation}
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This contribution can be separated into two parts, one which couples
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directly to the on-site atomic density and one that couples to the
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tunnelling operators. We will define the operator
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\begin{equation}
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\hat{F}_{l,m} = \hat{D}_{l,m} + \hat{B}_{l,m},
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\end{equation}
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where $\hat{D}_{l,m}$ is the direct coupling to atomic density
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\begin{equation}
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\hat{D}_{l,m} = \sum_{i}^K J^{l,m}_{i,i} \hat{n}_i,
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\end{equation}
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and $\hat{B}_{l,m}$ couples to the matter-field via the
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nearest-neighbour tunnelling operators
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\begin{equation}
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\hat{B}_{l,m} = \sum_{\langle i, j \rangle}^K J^{l,m}_{i,j} \bd_i b_j,
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\end{equation}
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and we neglect couplings beyond nearest neighbours for the same reason
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as before when deriving the matter Hamiltonian.
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It is important to note that we are considering a situation where the
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contribution of quantized light is much weaker than that of the
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classical trapping potential. If that was not the case, it would be
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necessary to determine thw Wannier functions in a self-consistent way
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which takes into account the depth of the quantum poterntial generated
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by the quantized light modes. This significantly complicates the
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treatment, but can lead to interesting physics. Amongst other things,
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the atomic tunnelling and interaction coefficients will now depend on
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the quantum state of light.
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\mynote{cite Santiago's papers and Maschler/Igor EPJD}
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Therefore, combining these final simplifications we finally arrive at
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our quantum light-matter Hamiltonian
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\begin{equation}
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\H = \H_f -J^\mathrm{cl} \sum_{\langle i,j \rangle}^M \bd_i b_j +
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\frac{U}{2} \sum_{i}^M \hat{n}_i (\hat{n}_i - 1) +
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\frac{\hbar}{\Delta_a} \sum_{l,m} g_l g_m \ad_l \a_m \hat{F}_{l,m} -
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i \sum_l \kappa_l \ad_l \a_l,
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\end{equation}
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where we have phenomologically included the cavity decay rates
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$\kappa_l$ of the modes $a_l$. A crucial observation about the
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structure of this Hamiltonian is that in the last term, the light
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modes $a_l$ couple to the matter in a global way. Instead of
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considering individual coupling to each site, the optical field
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couples to the global state of the atoms within the illuminated region
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via the operator $\hat{F}_{l,m}$. This will have important
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implications for the system and is one of the leading factors
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responsible for many-body behaviour beyong the Bose-Hubbard
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Hamiltonian paradigm.
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\subsection{Scattered light behaviour}
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Having derived the full quantum light-matter Hamiltonian we will no
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look at the behaviour of the scattered light. We begin by looking at
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the equations of motion in the Heisenberg picture
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\begin{equation}
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\dot{\a_l} = \frac{i}{\hbar} [\hat{H}, \a_l] =
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-i \left(\omega_l + U_{l,l}\hat{F}_{1,1} \right) \a_l
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- i \sum_{m \ne l} U_{l,m} \hat{F}_{l,m} \a_m
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- \kappa_l \a_l + \eta_l,
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\end{equation}
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where we have defined $U_{l,m} = g_l g_m / \Delta_a$. By considering
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the steady state solution in the frame rotating with the probe
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frequency $\omega_p$ we can show that the stationary solution is given
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by
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\begin{equation}
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\a_l = \frac{\sum_{m \ne l} U_{l,m} \a_m \hat{F}_{l,m} + i \eta_l}
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{(\Delta_{lp} - U_{l,l} \hat{F}_{l,l}) + i \kappa_l},
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\end{equation}
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where $\Delta_{lp} = \omega_p - \omega_l$ is the detuning between the
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probe beam and the light mode $a_l$. This equation gives us a direct
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relationship between the light operators and the atomic operators. In
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the stationary limit, the quantum state of the light field
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adiabatically follows the quantum state of matter.
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The above equation is quite general as it includes an arbitrary number
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of light modes which can be pumped directly into the cavity or
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produced via scattering from other modes. To simplify the equation
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slightly we will neglect the cavity resonancy shift,
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$U_{l,l} \hat{F}_{l,l}$ which is possible provided the cavity decay
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rate and/or probe detuning are large enough. We will also only
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consider probing with an external coherent beam and thus we neglect
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any cavity pumping $\eta_l$. This leads to a linear relationship
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between the light mode and the atomic operator $\hat{F}_{l,m}$
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\begin{equation}
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\a_l = \frac{\sum_{m \ne l} U_{l,m} \a_m}
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{\Delta_{lp} + i \kappa_l} \hat{F}_{l,m} = C \hat{F}_{l,m},
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\end{equation}
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where we have defined
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$C = \sum_{m \ne l} U_{l,m} \a_m / (\Delta_{lp} + i \kappa_l)$ which
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is essentially the Rayleigh scattering coefficient into the
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cavity. Whilst the light amplitude itself is only linear in atomic
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operators, we can easily have access to higher moments by simply
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simply considering higher moments of the $\a_l$ such as the photon
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number $\ad_l \a_l$.
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