Finished first subsection on correlated tunnelling
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@ -791,6 +791,287 @@ the $\gamma/U \gg 1$ regime is reached.
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\subsection{Emergent Long-Range Correlated Tunnelling}
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\subsection{Emergent Long-Range Correlated Tunnelling}
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When $\gamma \rightarrow \infty$ the measurement becomes
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projective. This means that as soon as the probing begins, the system
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collapses into one of the observable's eigenstates. Since this
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measurement is continuous and doesn't stop after the projection the
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system will be frozen in this state. This effect is called the quantum
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Zeno effect from Zeno's classical paradox in which a ``watched arrow
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never moves'' that stated since an arrow in flight is not seen to move
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during any single instant, it cannot possibly be moving at
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all. Classically the paradox was resolved with a better understanding
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of infinity and infintesimal changes, but in the quantum world a
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watched quantum arrow will in fact never move. The system is being
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continuously projected into its initial state before it has any chance
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to evolve away. If degenerate eigenspaces exist then we can observe
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quantum Zeno dynamics where unitary evolution is uninhibited within
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such a degenerate subspace, called the Zeno subspace.
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These effects can be easily seen in our model when
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$\gamma \rightarrow \infty$. The system will be projected into one or
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more degenerate eignstates of $\cd \c$, $| \psi_i \rangle$, for which
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we define the projector
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$P_\varphi = \sum_{i \in \varphi} | \psi_i \rangle$ where $\varphi$
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denotes a single degenerate subspace. The Zeno subspace is determined
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randomly as per the Copenhagen postulates and thus it depends on the
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initial state. If the projection is into the subspace
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$\varphi^\prime$, the subsequent evolution is described by the
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projected Hamiltonian
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$P_{\varphi^\prime} \hat{H}_0 P_{\varphi^\prime}$. We have used the
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original Hamiltonian, $\hat{H}_0$, without the non-Hermitian term or
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the quantum jumps as their combined effect is now described by the
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projectors. Physically, in our model of ultracold bosons trapped in a
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lattice this means that tunnelling between different spatial modes is
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completely supressed since this process couples eigenstates belonging
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to different Zeno subspaces. If a small connected part of the lattice
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was illuminated uniformly such that $\hat{D} = \hat{N}_K$ then
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tunnelling would only be prohibited between the illuminated and
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unilluminated areas, but dynamics proceeds normally within each zone
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separately. Therefore, the goemetric patterns we have in which the
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modes are sptailly delocalised in such a way that neighbouring sites
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never belong to the same mode, e.g. $\hat{D} = \hat{N}_\mathrm{odd}$,
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would lead to a complete suppression of tunnelling across the whole
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lattice as there is no way for an atom to tunnel within this Zeno
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subspace.
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This is an interesting example of the quantum Zeno effect and dynamics
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and it can be used to prohibit parts of the dynamics of the
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Bose-Hubbard Hamiltonian in order to engineer desired Hamiltonians for
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quantum simulations or other applications. However, the infinite
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projective limit is uninteresting in the context of a global
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measurement scheme. The same effects and Hamiltonians can be achieved
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using multiple independent measurements which address a few sites
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each. The only advantage of the global scheme is that it might be
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simpler to achieve as it requires a less complicated optical setup. In
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order to take advantage of the nonlocal nature of the measurement it
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turns out that we need to consider a finite limit for $\gamma \gg
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J$. By considering a non-infinite $\gamma$ we observe additional
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dynamics while the usual atomic tunnelling is still heavily
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Zeno-suppressed. These new effects are shown in Fig. \ref{fig:zeno}.
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\begin{figure}[hbtp!]
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\includegraphics[width=\textwidth]{Zeno.pdf}
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\caption[Emergent Long-Range Correlated Tunnelling]{ Long-range
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correlated tunneling and entanglement, dynamically induced by
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strong global measurement in a single quantum
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trajectory. (a),(b),(c) show different measurement geometries,
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implying different constraints. Panels (1): schematic
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representation of the long-range tunneling processes. Panels (2):
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evolution of on-site densities. Panels (3): entanglement entropy
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growth between illuminated and non-illuminated regions. Panels
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(4): correlations between different modes (orange) and within the
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same mode (green); $N_I$ ($N_{NI}$) is the atom number in the
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illuminated (non-illuminated) mode. (a) (a.1) Atom number in the
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central region is frozen: system is divided into three
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regions. (a.2) Standard dynamics happens within each region, but
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not between them. (a.3) Entanglement build up. (a.4) Negative
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correlations between non-illuminated regions (green) and zero
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correlations between the $N_I$ and $N_{NI}$ modes
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(orange). Initial state: $|1,1,1,1,1,1,1 \rangle$, $\gamma/J=100$,
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$J_{jj}=[0,0,1,1,1,0,0]$. (b) (b.1) Even sites are illuminated,
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freezing $N_\text{even}$ and $N_\text{odd}$. Long-range tunneling
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is represented by any pair of one blue and one red arrow. (b.2)
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Correlated tunneling occurs between non-neighbouring sites without
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changing mode populations. (b.3) Entanglement build up. (b.4)
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Negative correlations between edge sites (green) and zero
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correlations between the modes defined by $N_\text{even}$ and
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$N_\text{odd}$ (orange). Initial state: $|0,1,2,1,0 \rangle$,
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$\gamma/J=100$, $J_{jj}=[0,1,0,1,0]$. (c) (c.1,2) Atom number
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difference between two central sites is frozen. (c.3) Entanglement
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build up. (c.4) In contrast to previous examples, sites in the
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same zones are positively correlated (green), while atoms in
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different zones are negatively correlated (orange). Initial state:
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$|0,2,2,0 \rangle$, $\gamma/J=100$, $J_{jj}=[0,-1,1,0]$. 1D
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lattice, $U/J=0$.}
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\label{fig:zeno}
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\end{figure}
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There are two crucial features of the resulting dynamics that are of
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note. First, just like in the infinite quantum Zeno limit the
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evolution between nearest neighbours within the same mode is
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unperturbed whilst tunnelling between different modes is heavily
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suppressed by the measurement. Therefore, we see the usual quantum
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Zeno dynamics within a single Zeno subspace and just like before, it
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is also possible to use the global probing scheme to engineer these
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eigenspaces and select which tunnelling processes should be
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uninhibited and which should be suppressed. However, there is a second
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effect that was not present before. In Fig. \ref{fig:zeno} we can
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observe tunnelling that violates the boundaries established by the
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spatial modes. When $\gamma$ is finite, second-order processes can now
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occur, i.e.~two correlated tunnelling events, via an intermediate
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(virtual) state outside of the Zeno subspace as long as the Zeno
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subspace of the final state remains the same. Crucially, these
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tunnelling events are only correlated in time, but not in space. This
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means that the two events do not have to occur for the same atom or
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even at the same site in the lattice. As long as the Zeno subspace is
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preserved, these processes can occur anywhere in the system, that is a
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pair of atoms separated by many sites is able to tunnel in a
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correlated manner. This is only possible due to the possibility of
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creating extensive and spatially nonlocal modes as described in
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section \ref{sec:modes} which in turn is enabled by the global nature
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of the measurement. This would not be possible to achieve with local
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measurements as this would lead to Zeno subspaces described entirely
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by local variables which cannot be preserved by such delocalised
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tunnelling events.
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In the subsequent sections we will rigorously derive the following
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Hamiltonian for the non-interacting dynamics within a single Zeno
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subspace, $\varphi = 0$, for a lattice where the measurement defines
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$Z = 2$ distinct modes, e.g. $\hat{D} = \hat{N}_K$ or
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$\hat{D} = \hat{N}_\mathrm{odd}$
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\begin{equation}
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\label{eq:hz}
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\hat{H}_\varphi = P_0 \left[ -J \sum_{\langle i, j \rangle}
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b^\dagger_i b_j - i \frac{J^2} {A \gamma} \sum_{\varphi}
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\sum_{\substack{\langle i \in \varphi, j \in \varphi^\prime
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\rangle \\ \langle k \in \varphi^\prime, l \in \varphi
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\rangle}} b^\dagger_i b_j b^\dagger_k b_l \right] P_0,
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\end{equation}
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where
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$A = (J_{\varphi,\varphi} - J_{\varphi^\prime,\varphi^\prime})^2$ is a
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constant that depends on the measurement scheme, $\varphi$ denotes a
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set of site belonging to a single mode and $\varphi^\prime$ is the
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set's complement (e.g.~odd and even or illuminated and non-illuminated
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sites). We see that this Hamiltonian consists of two parts. The first
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term corresponds to the standard quantum Zeno first-order dynamics
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that occurs within a Zeno subspace, i.e.~tunnelling between
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neighbouring sites that belong to the same mode. Otherwise,
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$P_0 \bd_i b_j P_0 = 0$. If $\gamma \rightarrow \infty$ we would
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recover the quantum Zeno Hamiltonian where this would be the only
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remaining term. It is the second term that shows the second-order
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corelated tunnelling terms. This is evident from the inner sum which
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requires that pairs of sites ($i$, $j$) and ($k$, $l$) between which
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atoms tunnel must be nearest neighbours, but these pairs can be as far
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apart from each other as possible within the mode structure. This is
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in particular explicitly shown in Figs. \ref{fig:zeno}(a,b). The
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imaginary coefficient means that the tinelling behaves like an
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exponential decay (overdamped oscillations). This also implies that
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the norm will decay, but this does not mean that there are physical
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losses in the system. Instead, the norm itself represents the
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probability of the system remaining in the $\varphi = 0$ Zeno
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subspace. Since $\gamma$ is not infinite there is now a finite
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probability that the stochastic nature of the measurement will lead to
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a discontinous change in the system where the Zeno subspace rapidly
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changes. However, later in this chapter we will see that steady states
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of this Hamiltonian exist which will no longer change Zeno subspaces.
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Crucially, what sets this effect apart from usual many-body dynamics
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with short-range interactions is that first order processes are
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selectively suppressed by the global conservation of the measured
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observable and not by the prohibitive energy costs of doubly-occupied
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sites, as is the case in the $t$-$J$ model \cite{auerbach}. This has
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profound consequences as this is the physical origin of the long-range
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correlated tunneling events represented in \eqref{eq:hz} by the fact
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that the pairs ($i$, $j$) and ($k$, $l$) can be very distant. This is
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because the projection $\hat{P}_0$ is not sensitive to individual site
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occupancies, but instead enforces a fixed value of the observable,
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i.e.~a single Zeno subspace.
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In Fig.~\ref{fig:zeno}a we consider illuminating only the central
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region of the optical lattice and detecting light in the diffraction
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maximum, thus we freeze the atom number in the $K$ illuminated sites
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$\hat{N}_\text{K}$~\cite{mekhov2009prl,mekhov2009pra}. The measurement
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scheme defines two different spatial modes: the non-illuminated zones
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$1$ and $3$ and the illuminated one $2$. Figure~\ref{fig:zeno}(a.2)
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illustrates the evolution of the mean density at each lattice site:
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typical dynamics occurs within each region but the standard tunnelling
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between different modes is suppressed. Importantly, second-order
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processes that do not change $N_\text{K}$ are still possible since an
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atom from $1$ can tunnel to $2$, if simultaneously one atom tunnels
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from $2$ to $3$. Therfore, effective long-range tunneling between two
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spatially disconnected zones $1$ and $3$ happens due to the two-step
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processes $1 \rightarrow 2 \rightarrow 3$ or
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$3 \rightarrow 2 \rightarrow 1$. These transitions are responsible for
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the negative (anti-)correlations
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$\langle \delta N_1 \delta N_3 \rangle = \langle N_1 N_3 \rangle -
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\langle N_1 \rangle \langle N_3 \rangle$ showing that an atom
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disappearing from zone $1$ appears in zone $3$, while there are no
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number correlations between illuminated and non-illuminated regions,
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$\langle( \delta N_1 + \delta N_3 ) \delta N_2 \rangle = 0$ as shown
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in Fig.~\ref{fig:zeno}(a.4). In contrast to fully-projective
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measurement, the existence of an intermediate (virtual) step in the
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correlated tunnelling process builds long-range entanglement between
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illuminated and non-illuminated regions as shown in
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Fig.~\ref{fig:zeno}(a.3).
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To make correlated tunneling visible even in the mean atom number, we
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suppress the standard Bose-Hubbard dynamics by illuminating only the
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even sites of the lattice in Fig.~\ref{fig:zeno}(b). Even though this
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measurement scheme freezes both $N_\text{even}$ and $N_\text{odd}$,
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atoms can slowly tunnel between the odd sites of the lattice, despite
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them being spatially disconnected. This atom exchange spreads
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correlations between non-neighbouring lattice sites on a time scale
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$\sim \gamma/J^2$. The schematic explanation of long-range correlated
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tunneling is presented in Fig.~\ref{fig:zeno}(b.1): the atoms can
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tunnel only in pairs to assure the globally conserved values of
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$N_\text{even}$ and $N_\text{odd}$, such that one correlated tunneling
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event is represented by a pair of one red and one blue
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arrow. Importantly, this scheme is fully applicable for a lattice with
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large atom and site numbers, well beyond the numerical example in
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Fig.~\ref{fig:zeno}(b.1), because as we can see in \eqref{eq:hz}
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it is the geometry of quantum measurement that assures this mode
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structure (in this example, two modes at odd and even sites) and thus
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the underlying pairwise global tunnelling.
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This global pair tunneling may play a role of a building block for
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more complicated many-body effects. For example, a pair tunneling
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between the neighbouring sites has been recently shown to play
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important role in the formation of new quantum phases, e.g., pair
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superfluid \cite{sowinski2012} and lead to formulation of extended
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Bose-Hubbard models \cite{omjyoti2015}. The search for novel
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mechanisms providing long-range interactions is crucial in many-body
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physics. One of the standard candidates is the dipole-dipole
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interaction in, e.g., dipolar molecules, where the mentioned pair
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tunneling between even neighboring sites is already considered to be
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long-range \cite{sowinski2012,omjyoti2015}. In this context, our work
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suggests a fundamentally different mechanism originating from quantum
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optics: the backaction of global and spatially structured measurement,
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which as we prove can successfully compete with other short-range
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processes in many-body systems. This opens promising opportunities for
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future research.
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The scheme in Fig.~\ref{fig:zeno}(b.1) can help to design a nonlocal
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reservoir for the tunneling (or ``decay'') of atoms from one region to
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another. For example, if the atoms are placed only at odd sites,
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according to \eqref{eq:hz} their tunnelling is suppressed since the
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multi-tunneling event must be successive, i.e.~an atom tunnelling into
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a different mode, $\varphi^\prime$, must then also tunnel back into
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its original mode, $\varphi$. If, however, one adds some atoms to even
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sites (even if they are far from the initial atoms), the correlated
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tunneling events become allowed and their rate can be tuned by the
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number of added atoms. This resembles the repulsively bound pairs
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created by local interactions \cite{winkler2006, folling2007}. In
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contrast, here the atom pairs are nonlocally correlated due to the
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global measurement. Additionally, these long-range correlations are a
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consequence of the dynamics being constrained to a Zeno subspace: the
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virtual processes allowed by the measurement entangle the spatial
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modes nonlocally. Since the measurement only reveals the total number
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of atoms in the illuminated sites, but not their exact distribution,
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these multi-tunelling events cause the build-up of long range
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entanglement. This is in striking contrast to the entanglement caused
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by local processes which can be very confined, especially in 1D where
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it is typically short range. This makes numerical calculations of our
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system for large atom numbers really difficult, since well-known
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methods such as DMRG and MPS \cite{schollwock2005} (which are successful
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for short-range interactions) rely on the limited extent of
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entanglement.
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The negative number correlations are typical for systems with
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constraints (superselection rules) such as fixed atom number. The
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effective dynamics due to our global, but spatially structured,
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measurement introduces more general constraints to the evolution of
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the system. For example, in Fig.~\ref{fig:zeno}(c) we show the
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generation of positive number correlations shown in
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Fig.~\ref{fig:zeno}(c.4) by freezing the atom number difference
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between the sites ($N_\text{odd}-N_\text{even}$). Thus, atoms can only
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enter or leave this region in pairs, which again is possible due to
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correlated tunneling as seen in Figs.~\ref{fig:zeno}(c.1,c.2) and
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manifests positive correlations. As in the previous example, two edge
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modes in Fig.~\ref{fig:zeno}(c) can be considered as a nonlocal
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reservoir for two central sites, where a constraint is applied. Note
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that, using more modes, the design of higher-order multi-tunneling
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events is possible.
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\subsection{Non-Hermitian Dynamics in the Quantum Zeno Limit}
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\subsection{Non-Hermitian Dynamics in the Quantum Zeno Limit}
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% Contrast with t-J model here how U localises events, but measurement
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% Contrast with t-J model here how U localises events, but measurement
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@ -52,6 +52,12 @@ year = {2010}
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year={2004},
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year={2004},
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publisher={Springer Science \& Business Media}
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publisher={Springer Science \& Business Media}
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}
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}
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@book{auerbach,
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title={Interacting electrons and quantum magnetism},
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author={Auerbach, Assa},
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year={2012},
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publisher={Springer Science \& Business Media}
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}
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||||
%% Igor's original papers
|
%% Igor's original papers
|
||||||
@ -912,3 +918,63 @@ doi = {10.1103/PhysRevA.87.043613},
|
|||||||
year={2012},
|
year={2012},
|
||||||
publisher={APS}
|
publisher={APS}
|
||||||
}
|
}
|
||||||
|
@article{sowinski2012,
|
||||||
|
title = {Dipolar Molecules in Optical Lattices},
|
||||||
|
author = {Sowi\ifmmode \acute{n}\else \'{n}\fi{}ski, Tomasz and
|
||||||
|
Dutta, Omjyoti and Hauke, Philipp and Tagliacozzo,
|
||||||
|
Luca and Lewenstein, Maciej},
|
||||||
|
journal = {Phys. Rev. Lett.},
|
||||||
|
volume = {108},
|
||||||
|
issue = {11},
|
||||||
|
pages = {115301},
|
||||||
|
numpages = {5},
|
||||||
|
year = {2012},
|
||||||
|
month = {Mar},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
doi = {10.1103/PhysRevLett.108.115301},
|
||||||
|
url = {http://link.aps.org/doi/10.1103/PhysRevLett.108.115301}
|
||||||
|
}
|
||||||
|
@article{omjyoti2015,
|
||||||
|
author={Omjyoti Dutta and Mariusz Gajda and Philipp Hauke and Maciej
|
||||||
|
Lewenstein and Dirk-Soren Luhmann and Boris A
|
||||||
|
Malomed and Tomasz Sowinski and Jakub Zakrzewski},
|
||||||
|
title={Non-standard Hubbard models in optical lattices: a review},
|
||||||
|
journal={Reports on Progress in Physics},
|
||||||
|
volume={78},
|
||||||
|
number={6},
|
||||||
|
pages={066001},
|
||||||
|
url={http://stacks.iop.org/0034-4885/78/i=6/a=066001},
|
||||||
|
year={2015}
|
||||||
|
}
|
||||||
|
@article{winkler2006,
|
||||||
|
title={{Repulsively bound atom pairs in an optical lattice}},
|
||||||
|
author={Winkler, K. and Thalhammer, G. and Lang, F. and Grimm,
|
||||||
|
R. and Hecker Denschlag, J. and Daley, A. and
|
||||||
|
Kantian, A. and B\"{u}chler, H. P. and Zoller, P.},
|
||||||
|
journal={Nature},
|
||||||
|
volume={441},
|
||||||
|
pages = {853-856},
|
||||||
|
year={2006},
|
||||||
|
publisher={Nature Publishing Group}
|
||||||
|
}
|
||||||
|
@article{folling2007,
|
||||||
|
title={{Direct observation of second-order atom tunnelling}},
|
||||||
|
author={F\"{o}lling, S. and Trotzky, S. and Cheinet, P. and Feld,
|
||||||
|
M. and Saers, R. and Widera, A. and M\"{u}ller,
|
||||||
|
T. and Bloch, I.},
|
||||||
|
journal={Nature},
|
||||||
|
volume={448},
|
||||||
|
pages={1029},
|
||||||
|
year={2007},
|
||||||
|
publisher={Nature Publishing Group}
|
||||||
|
}
|
||||||
|
@article{schollwock2005,
|
||||||
|
title = {The density-matrix renormalization group},
|
||||||
|
author = {Schollw\"ock, U.},
|
||||||
|
journal = {Rev. Mod. Phys.},
|
||||||
|
volume = {77},
|
||||||
|
issue = {1},
|
||||||
|
pages = {259--315},
|
||||||
|
year = {2005},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@ -1,6 +1,7 @@
|
|||||||
% ************************ Thesis Information & Meta-data **********************
|
% ************************ Thesis Information & Meta-data **********************
|
||||||
%% The title of the thesis
|
%% The title of the thesis
|
||||||
\title{Interaction of Quantized Light with Ultracold Bosons}
|
\title{Competition between Weak Quantum Measurement and Many-Body
|
||||||
|
Dynamics in Ultracold Bosonic Gases}
|
||||||
%\texorpdfstring is used for PDF metadata. Usage:
|
%\texorpdfstring is used for PDF metadata. Usage:
|
||||||
%\texorpdfstring{LaTeX_Version}{PDF Version (non-latex)} eg.,
|
%\texorpdfstring{LaTeX_Version}{PDF Version (non-latex)} eg.,
|
||||||
%\texorpdfstring{$sigma$}{sigma}
|
%\texorpdfstring{$sigma$}{sigma}
|
||||||
|
Reference in New Issue
Block a user