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% ************************** Thesis Abstract *****************************
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% ************************** Thesis Abstract *****************************
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% Use `abstract' as an option in the document class to print only the titlepage and the abstract.
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% Use `abstract' as an option in the document class to print only the titlepage and the abstract.
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\begin{abstract}
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\begin{abstract}
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This is where you write your abstract ...
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Trapping ultracold atoms in optical lattices enabled the study of
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strongly correlated phenomena in an environment that is far more
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controllable and tunable than what was possible in condensed
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matter. Here, we consider coupling these systems to quantized light
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where the quantum nature of both the optical and matter fields play
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equally important roles in order to push the boundaries of
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what is possible in ultracold atomic systems.
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We show that light can serve as a nondestructive probe of the
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quantum state of the matter. By condering a global
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measurement scheme we show that it is possible to distinguish a
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highly delocalised phase like a superfluid from insulators. We also
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demonstrate that light scattering reveals not only density
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correlations, but also matter-field interference.
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By taking into account the effect of measurement backaction we show
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that the measurement can efficiently compete with the local atomic
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dynamics of the quantum gas. This can generate long-range
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correlations and entanglement which in turn leads to macroscopic
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multimode oscillations accross the whole lattice when the
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measurement is weak and correlated tunneling, as well as selective
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suppression and enhancement of dynamical processes beyond the
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projective limit of the quantum Zeno effect in the strong
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measurement regime.
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We also consider quantum measurement backaction due to the
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measurement of matter-phase-related variables such as global phase
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coherence. We show how this unconventional approach opens up new
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opportunities to affect system evolution and demonstrate how this
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can lead to a new class of measurement projections, thus extending
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the measurement postulate for the case of strong competition with
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the system’s own evolution.
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\end{abstract}
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\end{abstract}
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@ -12,46 +12,206 @@
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The field of ultracold gases has been a rapidly growing field ever
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The field of ultracold gases has been a rapidly growing field ever
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since the first Bose-Einstein condensate was obtained in 1995. This
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since the first Bose-Einstein condensate (BEC) was obtained in 1995
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new quantum state of matter is characterised by a macroscopic
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\cite{anderson1995, bradley1995, davis1995}. This new quantum state of
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occupancy of the single particle ground state at which point the whole
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matter is characterised by a macroscopic occupancy of the single
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system behaves like a single quantum object. This was revolutionary as
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particle ground state at which point the whole system behaves like a
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it enabled the study of coherent properties of macroscopic systems
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single many-body quantum object \cite{PitaevskiiStringari}. This was
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rather than single atoms or photons. Furthermore, the advanced state
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revolutionary as it enabled the study of coherent properties of
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of laser cooling and manipulation technologies meant that the degree
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macroscopic systems rather than single atoms or photons. Furthermore,
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of control and isolation from the environment was far greater than was
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the advanced state of laser cooling and manipulation technologies
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possible in condensed matter systems. Initially, the main focus of the
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meant that the degree of control and isolation from the environment
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was far greater than was possible in condensed matter systems
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\cite{lewenstein2007, bloch2008}. Initially, the main focus of the
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research was on the properties of coherent matter waves, such as
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research was on the properties of coherent matter waves, such as
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interference properties, long range phase coherence, or quantised
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interference properties \cite{andrews1997}, long range phase coherence
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vortices. Fermi degeneracy in ultracold gases was obtained shortly
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\cite{bloch2000}, or quantised vortices \cite{matthews1999,
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afterwards opening a similar field for fermions.
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madison2000, abo2001}. Fermi degeneracy in ultracold gases was
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obtained shortly afterwards opening a similar field for fermions
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\cite{demarco1999, schreck2001, truscott2001}.
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In 1998 it was shown that a degenerate ultracold gas trapped in an
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In 1998 it was shown that a degenerate ultracold gas trapped in an
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optical lattice is a near-perfect realisation of the Bose-Hubbard
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optical lattice is a near-perfect realisation of the Bose-Hubbard
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model and in 2002 it was already demonstrated in a ground-breaking
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model \cite{jaksch1998} and in 2002 it was already demonstrated in a
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experiment. The Bose-Hubbard Hamiltonian was already known in the
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ground-breaking experiment \cite{greiner2002}. The Bose-Hubbard
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field of condensed matter where it was considered a simple toy
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Hamiltonian was previously known in the field of condensed matter
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model. Despite its simplicity the model exhibits a variety of
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where it was considered a simple toy model. Despite its simplicity the
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different interesting phenomena such as the quantum phase transition
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model exhibits a variety of different interesting phenomena such as
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from a delocalised superfluid state to a Mott insulator as the on-site
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the quantum phase transition from a delocalised superfluid state to a
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interaction is increased above a critical point. In contrast to a
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Mott insulator as the on-site interaction is increased above a
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thermodynamic phase transition, a quantum phase transition is driven
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critical point which was originally studied in the context of liquid
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by quantum fluctuations and can occur at zero temperature. The ability
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helium \cite{fisher1989}. In contrast to a thermodynamic phase
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transition, a quantum phase transition is driven by quantum
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fluctuations and can occur at zero temperature. The ability to achieve
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a Bose-Hubbard Hamiltonian where the model parameters can be easily
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tuned by varying the lattice potential opened up a new regime in the
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many-body physics of atomic gases. Unlike Bose-Einstein condensates in
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free space which are described by weakly interacting theories
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\cite{dalfovo1999}, the behaviour of ultracold gases trapped in an
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optical lattice is dominated by atomic interactions opening the
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possibility of studying strongly correlated behaviour with
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unprecendented control.
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The modern field of ultracold gases is successful due to its
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The modern field of ultracold gases is successful due to its
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interdisciplinarity [1, 2]. Originally condensed matter effects are
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interdisciplinarity \cite{lewenstein2007, bloch2008}. Originally
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now mimicked in controlled atomic systems finding applications in
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condensed matter effects are now mimicked in controlled atomic systems
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areas such as quantum information processing (QIP). A really new
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finding applications in areas such as quantum information
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challenge is to identify novel phenomena which were unreasonable to
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processing. A really new challenge is to identify novel phenomena
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consider in condensed matter, but will become feasible in new systems.
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which were unreasonable to consider in condensed matter, but will
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One such direction is merging quantum optics and many-body physics [3,
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become feasible in new systems. One such direction is merging quantum
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4]. The former describes delicate effects such as quantum
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optics and many-body physics \cite{mekhov2012, ritsch2013}. Quantum
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measurement and state engineering, but for systems without strong
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optics has been developping as a branch of quantum physics
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many-body correlations (e.g. atomic ensembles). In the latter,
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independently of the progress in the many-body community. It describes
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decoherence destroys these effects in conventional condensed
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delicate effects such as quantum measurement, state engineering, and
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matter. Due to recent experimental progress, e.g. Bose-Einstein
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systems that can generally be easily isolated from their environnment
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condensates (BEC) in cavities [5–7], quantum optics of quantum gases
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due to the non-interacting nature of photons \cite{Scully}. However,
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can close this gap.
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they are also the perfect candidate for studying open systems due the
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advanced state of cavity technologies \cite{carmichael,
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MeasurementControl}. On the other hand ultracold gases are now used
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to study strongly correlated behaviour of complex macroscopic
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ensembles where decoherence is not so easy to avoid or control. Recent
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experimental progress in combining the two fields offered a very
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promising candidate for taking many-body physics in a direction that
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would not be possible for condensed matter \cite{baumann2010,
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wolke2012, schmidt2014}. Two very recent breakthrough experiments
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have even managed to couple an ultracold gas trapped in an optical
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lattice to an optical cavity enabling the study of strongly correlated
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systems coupled to quantized light fields where the quantum properties
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of the atoms become imprinted in the scattered light
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\cite{klinder2015, landig2016}.
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There are three prominent directions in which the field of quantum
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optics of quantum gases has progressed in. First, the use of quantised
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light enables direct coupling to the quantum properties of the atoms
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\cite{mekhov2007prl, mekhov2007prl, mekhov2012}. This allows us to
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probe the many-body system in a nondestructive manner and under
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certain conditions even perform quantum non-demolition (QND)
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measurements. QND measurements were originally developed in the
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context of quantum optics as a tool to measure a quantum system
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without significantly disturbing it \cite{braginsky1977, unruh1978,
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brune1990, brune1992}. This has naturally been extended into the
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realm of ultracold gases where such non-demolition schemes have been
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applied to both fermionic \cite{eckert2008qnd, roscilde2009} and
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bosonic \cite{hauke2013, rogers2014}. In this thesis, we consider
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light scattering in free space from a bosonic ultracold gas and show
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that there are many prominent features that go beyond classical
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optics. Even the scattering angular distribution is nontrivial with
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Bragg conditions that are significantly different from the classical
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case. Furthermore, we show that the direct coupling of quantised light
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to the atomic systems enables the nondestructive probing beyond a
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standard mean-field description. We demonstrate this by showing that
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the whole phase diagram of a disordered one-dimensional Bose-Hubbard
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Hamiltonian, which consists of the superfluid, Mott insulating, and
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Bose glass phases, can be mapped from the properties of the scattered
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light. Additionally, we go beyond standard QND approaches, which only
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consider coupling to density observables, by also considering the
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direct coupling of the quantised light to the interference between
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neighbouring lattice sites. We show that not only is this possible to
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achieve in a nondestructive manner, it is also achieved without the
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need for single-site resolution. This is in contrast to the standard
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destructive time-of-flight measurements currently used to perform
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these measurements \cite{miyake2011}. Within a mean-field treatment
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this enables probing of the order parameter as well as matter-field
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quadratures and their squeezing. This can have an impact on atom-wave
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metrology and information processing in areas where quantum optics has
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already made progress, e.g.,~quantum imaging with pixellized sources
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of non-classical light \cite{golubev2010, kolobov1999}, as an optical
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lattice is a natural source of multimode nonclassical matter waves.
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Second, coupling a quantum gas to a cavity also enables us to study
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open system many-body dynamics either via dissipation where we have no
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control over the coupling to the environment or via controlled state
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reduction using the measurement backaction due to photodetections. A
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lot of effort was expanded in an attempt to minimise the influence of
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the environment in order to extend decoherence times. However,
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theoretical progress in the field has shown that instead being an
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obstacle, dissipation can actually be used as a tool in engineering
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quantum states \cite{diehl2008}. Furthermore, as the environment
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coupling is varied the system may exhibit sudden changes in the
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properties of its steady state giving rise to dissipative phase
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transitions \cite{carmichael1980, werner2005, capriotti2005,
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morrison2008, eisert2010, bhaseen2012, diehl2010,
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vznidarivc2011}. An alternative approach to open systems is to look
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at quantum measurement where we consider a quantum state conditioned
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on the outcome of a single experimental run \cite{carmichael,
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MeasurementControl}. In this approach we consider the solutions to a
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stochastic Schr\"{o}dinger equation which will be a pure state, which
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in contrast to dissipative systems is generally not the case. The
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question of measurement and its effect on the quantum state has been
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around since the inception of quantum theory and still remains a
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largely open question \cite{zurek2002}. It wasn't long after the first
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condenste was obtained that theoretical work on the effects of
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measurement on BECs appeared \cite{cirac1996, castin1997,
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ruostekoski1997}. Recently, work has also begun on combining weak
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measurement with the strongly correlated dynamics of ultracold gases
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in optical lattices \cite{mekhov2009prl, mekhov2009pra, mekhov2012,
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douglas2012, douglas2013, ashida2015, ashida2015a}.
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In this thesis we focus on the latter by considering a quantum gas in
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an optical lattice coupled to a cavity \cite{mekhov2012}. This
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provides us with a flexible setup where the global light scattering
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can be engineered. We show that this introduces a new competing energy
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scale into the system and by considering continuous measurement, as
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opposed to discrete projective measurements, we demonstrate the
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quantum backaction can effectively compete with the standard
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short-range processes of the Bose-Hubbard model. The global nature of
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the optical fields leads to new phenomena driven by long-range
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correlations that arise from the measurement. The flexibility of the
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optical setup lets us not only consider coupling to different
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observables, but by carefully choosing the optical geometry we can
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suppress or enhace specific dynamical processes, realising spatially
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nonlocal quantum Zeno dynamics.
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The quantum Zeno effect happens when frequent measurements slow the
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evolution of a quantum system \cite{misra1977, facchi2008}. This
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effect was already considered by von Neumann and it has been
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successfully observed in a variety of systems \cite{itano1990,
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nagels1997, kwiat1999, balzer2000, streed2006, hosten2006,
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bernu2008}. The generalisation of this effect to measurements with
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multidimensional projections leads to quantum Zeno dynamics where
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unitary evolution is uninhibited within this degenerate subspace,
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i.e. the Zeno subspace \cite{facchi2008, raimond2010, raimond2012,
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signoles2014}. Here, by combining quantum optical measurements with
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the complex Hilbert space of a many-body quantum gas we go beyond
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conventional quantum Zeno dynamics. By considering the case of
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measurement near, but not in, the projective limit the system is still
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confined to a Zeno subspace, but intermediate transitions are allowed
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via virtual Raman-like processes. In a lattice system, like the
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Bose-Hubbard model we can use global measurement to engineer these
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dynamics to be highly nonlocal leading to the generation of long-range
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correlations and entanglement. Furthermore, we show that this
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behaviour can be approximated by a non-Hermitian Hamiltonian thus
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extending the notion of quantum Zeno dynamics into the realm of
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non-Hermitian quantum mechanics joining the two
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paradigms. Non-Hermitian systems themself exhibit a range of
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interesting phenomena ranging from localisation \cite{hatano1996,
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refael2006} and $\mathcal{PT}$ symmetry \cite{bender1998,
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giorgi2010, zhang2013} to spatial order \cite{otterbach2014} and
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novel phase transitions \cite{lee2014prx, lee2014prl}.
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Just like for the nondestructive measurements we also consider
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measurement backaction due to coupling to the interference terms
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between the lattice sites. This effectively amounts to coupling to the
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phase observables of the system. As this is the conjugate variable of
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density, this allows to enter a new regime of quantum control using
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measurement backaction. Whilst such interference measurements have
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been previously proposed for BECs in double-wells \cite{cirac1996,
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castin1997, ruostekoski1997}, the extension to a lattice system is
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not straightforward, but we will show it is possible to achieve with
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our propsed setup by a careful optical arrangement. Within this
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context we demonstrate a novel type of projection which occurs even
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when there is significant competition with the Hamiltonian
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dynamics. This projection is fundamentally different to the standard
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formulation of the Copenhagen postulate projection or the quantum Zeno
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effect \cite{misra1977, facchi2008} thus providing an extension of the
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measurement postulate to dynamical systems subject to weak
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measurement.
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Finally, the cavity field that builds up from the scattered photons
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can also create a quantum optical potential which will modify the
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Hamiltonian in a way that depends on the state of the atoms that
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scatterd the light. This can lead to new quantum phases due to new
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types of long-range interactions being mediated by the global quantum
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optical fields \cite{caballero2015, caballero2015njp, caballero2016,
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caballero2016a}. However, this aspect of quantum optics of quantum
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gases is beyond the scope of this thesis.
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@ -20,9 +20,9 @@ the system in different parameter regimes, such as nondestructive
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measurement in free space or quantum measurement backaction in a
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measurement in free space or quantum measurement backaction in a
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cavity. Another interesting direction for this field of research are
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cavity. Another interesting direction for this field of research are
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quantum optical lattices where the trapping potential is treated
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quantum optical lattices where the trapping potential is treated
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quantum mechanically. However this is beyond the scope of this work.
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quantum mechanically \cite{caballero2015, caballero2015njp,
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caballero2016, caballero2016a}. However this is beyond the scope of
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\mynote{insert our paper citations here}
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this work.
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We consider $N$ two-level atoms in an optical lattice with $M$
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We consider $N$ two-level atoms in an optical lattice with $M$
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sites. For simplicity we will restrict our attention to spinless
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sites. For simplicity we will restrict our attention to spinless
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@ -41,23 +41,21 @@ lattice with a low filling factor (e.g.~a system with one atom per
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site which will exhibit the Mott insulator to superfluid quantum phase
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site which will exhibit the Mott insulator to superfluid quantum phase
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transition).
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transition).
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\mynote{extra fermion citations, Piazza? Look up Gabi's AF paper.}
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An optical lattice can be formed with classical light beams that form
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standing waves. Depending on the detuning with respect to the atomic
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As we have seen in the previous section, an optical lattice can be
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resonance, the nodes or antinodes form the lattice sites in which
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formed with classical light beams that form standing waves. Depending
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atoms accumulate. As shown in Fig. \ref{fig:LatticeDiagram} the
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on the detuning with respect to the atomic resonance, the nodes or
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trapped bosons (green) are illuminated with a coherent probe beam
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antinodes form the lattice sites in which atoms accumulate. As shown
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(red) and scatter light into a different mode (blue) which is then
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in Fig. \ref{fig:LatticeDiagram} the trapped bosons (green) are
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measured with a detector. The most straightforward measurement is to
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illuminated with a coherent probe beam (red) and scatter light into a
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simply count the number of photons with a photodetector, but it is
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different mode (blue) which is then measured with a detector. The most
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also possible to perform a quadrature measurement by using a homodyne
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straightforward measurement is to simply count the number of photons
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detection scheme. The experiment can be performed in free space where
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with a photodetector, but it is also possible to perform a quadrature
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light can scatter in any direction. The atoms can also be placed
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measurement by using a homodyne detection scheme. The experiment can
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inside a cavity which has the advantage of being able to enhance light
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be performed in free space where light can scatter in any
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scattering in a particular direction. Furthermore, cavities allow for
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direction. The atoms can also be placed inside a cavity which has the
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the formation of a fully quantum potential in contrast to the
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advantage of being able to enhance light scattering in a particular
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classical lattice trap.
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direction. Furthermore, cavities allow for the formation of a fully
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quantum potential in contrast to the classical lattice trap.
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\begin{figure}[htbp!]
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\begin{figure}[htbp!]
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\centering
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\centering
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Binary file not shown.
@ -9,3 +9,111 @@
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\else
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\else
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\graphicspath{{Chapter7/Figs/Vector/}{Chapter7/Figs/}}
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\graphicspath{{Chapter7/Figs/Vector/}{Chapter7/Figs/}}
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\fi
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\fi
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||||||
|
|
||||||
|
Quantum optics of quantum gases explores the ultimate quantum regime
|
||||||
|
of light-matter interactions where both the optical and matter fields
|
||||||
|
are fully quantised. It provides a very rich system in which new
|
||||||
|
phenomena can be observed, engineered, and controlled beyond what
|
||||||
|
would be possible in condensed matter. Combined with rapid and
|
||||||
|
promising experimental progress in this field the theoretical
|
||||||
|
proposals have the potential of directing the research in the
|
||||||
|
foreseeable future \cite{baumann2010, wolke2012, schmidt2014,
|
||||||
|
klinder2015, landig2016}.
|
||||||
|
|
||||||
|
In this thesis we focused on the coupling between global quantised
|
||||||
|
optical fields and an ultracold bosonic quantum gas. By considering
|
||||||
|
global fields as opposed to localised light-matter interactions we
|
||||||
|
were able to introduce several nonlocal properties to the Hamiltonian
|
||||||
|
in a controllable manner which would otherwise be impossible to
|
||||||
|
implement. We showed how this can be useful in the context of
|
||||||
|
nondestructive probing by showing that it can easily distinguish
|
||||||
|
between a highly delocalised quantum state such as a superfluid and
|
||||||
|
insulating states such as the Mott insulator and the Bose glass phases
|
||||||
|
which is currently a challenge \cite{derrico2014}. Furthermore, we
|
||||||
|
have seen how the correlation length, which would be inaccessible in
|
||||||
|
localised measurements, was immediately visible in our scheme and lead
|
||||||
|
to an angular scattering pattern that was far richer than it was for
|
||||||
|
the classical case. This is best highlighted by the fact that it would
|
||||||
|
be visible even when classically no light would scatter coherently at
|
||||||
|
all.
|
||||||
|
|
||||||
|
More interestingly, the global nature of the measurement was also
|
||||||
|
capable of creating such long-range correlations itself when we
|
||||||
|
considered measurement backaction. This was most visible when we saw
|
||||||
|
how weak measurement was capable of driving global macroscopic
|
||||||
|
multimode oscillations between different spatial modes, such as odd
|
||||||
|
and even sites, across the whole lattice which could be used for
|
||||||
|
quantum information and metrology. Such dynamical states show spatial
|
||||||
|
density-density correlations with nontrivial periods and long-range
|
||||||
|
coherence, thus having supersolid properties, but as an essentially
|
||||||
|
dynamical version. Furthermore, the tunability of the optical
|
||||||
|
arrangement meant that we had extreme flexibility in choosing our
|
||||||
|
observables, effectively tailoring the long-range entanglement and
|
||||||
|
correlations in the system. We have also shown how global measurement
|
||||||
|
when combined with both atomic tunnelling and interactions leads to
|
||||||
|
highly nontrivial dynamics in which backaction can either compete or
|
||||||
|
cooperate with on-site repulsion in squeezing the atomic variables.
|
||||||
|
|
||||||
|
In the limit of strong measurement when quantum Zeno dynamics occurs
|
||||||
|
we showed that these nonlocal spatial modes created by the global
|
||||||
|
measurement lead to long-range correlated tunnelling events whilst
|
||||||
|
suppressing any other dynamics between different spatial modes of the
|
||||||
|
measurement. Such globally paired tunneling due to a fundamentally
|
||||||
|
novel phenomenon can enrich physics of long-range correlated systems
|
||||||
|
beyond relatively shortrange interactions expected from standard
|
||||||
|
dipole-dipole interactions \cite{sowinski2012, omjyoti2015}. These
|
||||||
|
nonlocal high-order processes entangle regions of the optical lattice
|
||||||
|
that are disconnected by the measurement. Using different detection
|
||||||
|
schemes, we showed how to tailor density-density correlations between
|
||||||
|
distant lattice sites. Quantum optical engineering of nonlocal
|
||||||
|
coupling to environment, combined with quantum measurement, can allow
|
||||||
|
the design of nontrivial system-bath interactions, enabling new links
|
||||||
|
to quantum simulations \cite{stannigel2013} and thermodynamics
|
||||||
|
\cite{erez2008}. Interestingly, these dynamics also provide a link to
|
||||||
|
non-Hermitian quantum mechanics as this regime of measurement can be
|
||||||
|
accurately described with a non-Hermitian Hamiltonian. Furthermore, we
|
||||||
|
show that this allows for a rather novel type of competition between
|
||||||
|
measurement and tunnelling where both processes actually cooperate to
|
||||||
|
produce a steady state in which tunnelling is suppressed by
|
||||||
|
destructive matter-wave interference.
|
||||||
|
|
||||||
|
A unique feature of our global measurement scheme meant that we could
|
||||||
|
couple directly to the phase observables of the system by coupling to
|
||||||
|
the interference between the lattice sites, which represents the
|
||||||
|
shortest meaningful distance in an optical lattice, rather than their
|
||||||
|
on-site density. This defines most processes in optical lattices. For
|
||||||
|
example, matter-field phase changes may happen not only due to
|
||||||
|
external gradients, but also due to intriguing effects such quantum
|
||||||
|
jumps leading to phase flips at neighbouring sites and sudden
|
||||||
|
cancellation of tunneling \cite{vukics2007}, which should be
|
||||||
|
accessible by this method. Furthremore, in mean-field one can measure
|
||||||
|
the matter-field amplitude (which is also the order parameter),
|
||||||
|
quadratures and their squeezing. This can link atom optics to areas
|
||||||
|
where quantum optics has already made progress, e.g., quantum imaging
|
||||||
|
\cite{golubev2010, kolobov1999}, using an optical lattice as an array
|
||||||
|
of multimode nonclassical matter- field sources with a high degree of
|
||||||
|
entanglement for quantum information processing. We have also shown
|
||||||
|
how this scheme of coupling to phase observables can be used in the
|
||||||
|
context of quantum measurement backaction to achieve a new degree of
|
||||||
|
control. We used this result to show a generalisation of weak
|
||||||
|
measurement on dynamical systems by showing that there is now a new
|
||||||
|
class of projections available even when the measurement is not a
|
||||||
|
compatible observable of the Hamiltonian. This an interesting result
|
||||||
|
as the projections themselves are unlike those postulated by the
|
||||||
|
Copenhagen interpretation, those present in quantum Zeno dynamic, or
|
||||||
|
even those possible to engineer using dissipative methods.
|
||||||
|
|
||||||
|
In this thesis we have covered significant areas of the broad field
|
||||||
|
that is quantum optics of quantum gases, but there is much more that
|
||||||
|
has been left untouched. Here, we have only considered spinless
|
||||||
|
bosons, but the theory can also been extended to fermions
|
||||||
|
\cite{atoms2015, mazzucchi2016, mazzucchi2016af} and
|
||||||
|
molecules \cite{LP2013} and potentially even photonic circuits
|
||||||
|
\cite{mazzucchi2016njp}. Furthermore, the question of quantum
|
||||||
|
measurement and its properties has been a subject of heated debate
|
||||||
|
since the very origins of quantum theory yet it is still as mysterious
|
||||||
|
as it was at the beginning of the $20^\mathrm{th}$ century. However,
|
||||||
|
this work has hopefully demonstrated that coupling quantised light
|
||||||
|
fields to many-body systems provides a very rich playground for
|
||||||
|
exploring new quantum mechanical phenomena beyond what would otherwise
|
||||||
|
be possible in other fields.
|
||||||
|
@ -2,6 +2,15 @@
|
|||||||
%% Books, theses, reference material
|
%% Books, theses, reference material
|
||||||
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
|
||||||
|
|
||||||
|
@book{carmichael,
|
||||||
|
title={An open systems approach to quantum optics: lectures
|
||||||
|
presented at the Universit{\'e} Libre de Bruxelles,
|
||||||
|
October 28 to November 4, 1991},
|
||||||
|
author={Carmichael, Howard},
|
||||||
|
volume={18},
|
||||||
|
year={2009},
|
||||||
|
publisher={Springer Science \& Business Media}
|
||||||
|
}
|
||||||
@book{foot,
|
@book{foot,
|
||||||
author = {Foot, C. J.},
|
author = {Foot, C. J.},
|
||||||
title = {{Atomic Physics}},
|
title = {{Atomic Physics}},
|
||||||
@ -243,8 +252,10 @@ year = {2010}
|
|||||||
publisher={IOP Publishing}
|
publisher={IOP Publishing}
|
||||||
}
|
}
|
||||||
@article{caballero2016,
|
@article{caballero2016,
|
||||||
title = {Quantum simulators based on the global collective light-matter interaction},
|
title = {Quantum simulators based on the global collective
|
||||||
author = {Caballero-Benitez, Santiago F. and Mazzucchi, Gabriel and Mekhov, Igor B.},
|
light-matter interaction},
|
||||||
|
author = {Caballero-Benitez, Santiago F. and Mazzucchi, Gabriel and
|
||||||
|
Mekhov, Igor B.},
|
||||||
journal = {Phys. Rev. A},
|
journal = {Phys. Rev. A},
|
||||||
volume = {93},
|
volume = {93},
|
||||||
issue = {6},
|
issue = {6},
|
||||||
@ -1225,3 +1236,513 @@ doi = {10.1103/PhysRevA.87.043613},
|
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year={1981},
|
year={1981},
|
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publisher={APS}
|
publisher={APS}
|
||||||
}
|
}
|
||||||
|
@article{anderson1995,
|
||||||
|
title={Observation of Bose-Einstein Condensation in a Dilute Atomic
|
||||||
|
Vapor},
|
||||||
|
author={Anderson, MH and Ensher, JR and Matthews, MR and Wieman, CE
|
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|
and Cornell, EA},
|
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|
journal={science},
|
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|
volume={269},
|
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|
pages={14},
|
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|
year={1995}
|
||||||
|
}
|
||||||
|
@article{bradley1995,
|
||||||
|
title={Evidence of Bose-Einstein condensation in an atomic gas with
|
||||||
|
attractive interactions},
|
||||||
|
author={Bradley, Cl C and Sackett, CA and Tollett, JJ and Hulet,
|
||||||
|
Randall G},
|
||||||
|
journal={Physical Review Letters},
|
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volume={75},
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number={9},
|
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|
pages={1687},
|
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|
year={1995},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{davis1995,
|
||||||
|
title={Bose-Einstein condensation in a gas of sodium atoms},
|
||||||
|
author={Davis, Kendall B and Mewes, M-O and Andrews, Michael R and
|
||||||
|
Van Druten, NJ and Durfee, DS and Kurn, DM and
|
||||||
|
Ketterle, Wolfgang},
|
||||||
|
journal={Physical review letters},
|
||||||
|
volume={75},
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|
number={22},
|
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|
pages={3969},
|
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|
year={1995},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{bloch2008,
|
||||||
|
title={Many-body physics with ultracold gases},
|
||||||
|
author={Bloch, Immanuel and Dalibard, Jean and Zwerger, Wilhelm},
|
||||||
|
journal={Reviews of Modern Physics},
|
||||||
|
volume={80},
|
||||||
|
number={3},
|
||||||
|
pages={885},
|
||||||
|
year={2008},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{lewenstein2007,
|
||||||
|
title={Ultracold atomic gases in optical lattices: mimicking
|
||||||
|
condensed matter physics and beyond},
|
||||||
|
author={Lewenstein, Maciej and Sanpera, Anna and Ahufinger, Veronica
|
||||||
|
and Damski, Bogdan and Sen, Aditi and Sen, Ujjwal},
|
||||||
|
journal={Advances in Physics},
|
||||||
|
volume={56},
|
||||||
|
number={2},
|
||||||
|
pages={243--379},
|
||||||
|
year={2007},
|
||||||
|
publisher={Taylor \& Francis}
|
||||||
|
}
|
||||||
|
@article{andrews1997,
|
||||||
|
title={Observation of interference between two Bose condensates},
|
||||||
|
author={Andrews, MR and Townsend, CG and Miesner, H-J and Durfee, DS
|
||||||
|
and Kurn, DM and Ketterle, W},
|
||||||
|
journal={Science},
|
||||||
|
volume={275},
|
||||||
|
number={5300},
|
||||||
|
pages={637--641},
|
||||||
|
year={1997},
|
||||||
|
publisher={American Association for the Advancement of Science}
|
||||||
|
}
|
||||||
|
@article{bloch2000,
|
||||||
|
title={Measurement of the spatial coherence of a trapped Bose gas at
|
||||||
|
the phase transition},
|
||||||
|
author={Bloch, I and H{\"a}nsch, Th W and Esslinger, T},
|
||||||
|
journal={Nature},
|
||||||
|
volume={403},
|
||||||
|
number={6766},
|
||||||
|
pages={166--170},
|
||||||
|
year={2000},
|
||||||
|
publisher={Nature Publishing Group}
|
||||||
|
}
|
||||||
|
@article{matthews1999,
|
||||||
|
title={Vortices in a Bose-Einstein condensate},
|
||||||
|
author={Matthews, Michael Robin and Anderson, Brian P and Haljan, PC
|
||||||
|
and Hall, DS and Wieman, CE and Cornell, EA},
|
||||||
|
journal={Physical Review Letters},
|
||||||
|
volume={83},
|
||||||
|
number={13},
|
||||||
|
pages={2498},
|
||||||
|
year={1999},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{madison2000,
|
||||||
|
title={Vortex formation in a stirred Bose-Einstein condensate},
|
||||||
|
author={Madison, KW and Chevy, F and Wohlleben, W and Dalibard, J},
|
||||||
|
journal={Physical Review Letters},
|
||||||
|
volume={84},
|
||||||
|
number={5},
|
||||||
|
pages={806},
|
||||||
|
year={2000},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{abo2001,
|
||||||
|
title={Observation of vortex lattices in Bose-Einstein condensates},
|
||||||
|
author={Abo-Shaeer, JR and Raman, C and Vogels, JM and Ketterle, Wolfgang},
|
||||||
|
journal={Science},
|
||||||
|
volume={292},
|
||||||
|
number={5516},
|
||||||
|
pages={476--479},
|
||||||
|
year={2001},
|
||||||
|
publisher={American Association for the Advancement of Science}
|
||||||
|
}
|
||||||
|
@article{demarco1999,
|
||||||
|
title={Onset of Fermi degeneracy in a trapped atomic gas},
|
||||||
|
author={DeMarco, Brian and Jin, Deborah S},
|
||||||
|
journal={Science},
|
||||||
|
volume={285},
|
||||||
|
number={5434},
|
||||||
|
pages={1703--1706},
|
||||||
|
year={1999},
|
||||||
|
publisher={American Association for the Advancement of Science}
|
||||||
|
}
|
||||||
|
@article{schreck2001,
|
||||||
|
title={Quasipure Bose-Einstein condensate immersed in a Fermi sea},
|
||||||
|
author={Schreck, F and Khaykovich, Lev and Corwin, KL and Ferrari, G
|
||||||
|
and Bourdel, Thomas and Cubizolles, Julien and
|
||||||
|
Salomon, Christophe},
|
||||||
|
journal={Physical Review Letters},
|
||||||
|
volume={87},
|
||||||
|
number={8},
|
||||||
|
pages={080403},
|
||||||
|
year={2001},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{truscott2001,
|
||||||
|
title={Observation of Fermi pressure in a gas of trapped atoms},
|
||||||
|
author={Truscott, Andrew G and Strecker, Kevin E and McAlexander,
|
||||||
|
William I and Partridge, Guthrie B and Hulet,
|
||||||
|
Randall G},
|
||||||
|
journal={Science},
|
||||||
|
volume={291},
|
||||||
|
number={5513},
|
||||||
|
pages={2570--2572},
|
||||||
|
year={2001},
|
||||||
|
publisher={American Association for the Advancement of Science}
|
||||||
|
}
|
||||||
|
@article{dalfovo1999,
|
||||||
|
title={Theory of Bose-Einstein condensation in trapped gases},
|
||||||
|
author={Dalfovo, Franco and Giorgini, Stefano and Pitaevskii, Lev P
|
||||||
|
and Stringari, Sandro},
|
||||||
|
journal={Reviews of Modern Physics},
|
||||||
|
volume={71},
|
||||||
|
number={3},
|
||||||
|
pages={463},
|
||||||
|
year={1999},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{ritsch2013,
|
||||||
|
title={Cold atoms in cavity-generated dynamical optical potentials},
|
||||||
|
author={Ritsch, Helmut and Domokos, Peter and Brennecke, Ferdinand
|
||||||
|
and Esslinger, Tilman},
|
||||||
|
journal={Reviews of Modern Physics},
|
||||||
|
volume={85},
|
||||||
|
number={2},
|
||||||
|
pages={553},
|
||||||
|
year={2013},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{baumann2010,
|
||||||
|
title={Dicke quantum phase transition with a superfluid gas in an optical cavity},
|
||||||
|
author={Baumann, Kristian and Guerlin, Christine and Brennecke,
|
||||||
|
Ferdinand and Esslinger, Tilman},
|
||||||
|
journal={Nature},
|
||||||
|
volume={464},
|
||||||
|
number={7293},
|
||||||
|
pages={1301--1306},
|
||||||
|
year={2010},
|
||||||
|
publisher={Nature Publishing Group}
|
||||||
|
}
|
||||||
|
@article{wolke2012,
|
||||||
|
title={Cavity cooling below the recoil limit},
|
||||||
|
author={Wolke, Matthias and Klinner, Julian and Ke{\ss}ler, Hans and
|
||||||
|
Hemmerich, Andreas},
|
||||||
|
journal={Science},
|
||||||
|
volume={337},
|
||||||
|
number={6090},
|
||||||
|
pages={75--78},
|
||||||
|
year={2012},
|
||||||
|
publisher={American Association for the Advancement of Science}
|
||||||
|
}
|
||||||
|
@article{schmidt2014,
|
||||||
|
title={Dynamical Instability of a Bose-Einstein Condensate in an
|
||||||
|
Optical Ring Resonator},
|
||||||
|
author={Schmidt, D and Tomczyk, H and Slama, S and Zimmermann, C},
|
||||||
|
journal={Physical review letters},
|
||||||
|
volume={112},
|
||||||
|
number={11},
|
||||||
|
pages={115302},
|
||||||
|
year={2014},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{landig2016,
|
||||||
|
title={Quantum phases from competing short-and long-range
|
||||||
|
interactions in an optical lattice},
|
||||||
|
author={Landig, Renate and Hruby, Lorenz and Dogra, Nishant and
|
||||||
|
Landini, Manuele and Mottl, Rafael and Donner,
|
||||||
|
Tobias and Esslinger, Tilman},
|
||||||
|
journal={Nature},
|
||||||
|
year={2016},
|
||||||
|
publisher={Nature Publishing Group}
|
||||||
|
}
|
||||||
|
@article{klinder2015,
|
||||||
|
title={Observation of a superradiant Mott insulator in the Dicke-Hubbard model},
|
||||||
|
author={Klinder, Jens and Ke{\ss}ler, H and Bakhtiari, M Reza and
|
||||||
|
Thorwart, M and Hemmerich, A},
|
||||||
|
journal={Physical review letters},
|
||||||
|
volume={115},
|
||||||
|
number={23},
|
||||||
|
pages={230403},
|
||||||
|
year={2015},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{braginsky1977,
|
||||||
|
title={Topics in Theoretical and Experimental Gravitation Physics},
|
||||||
|
author={Braginsky, VB},
|
||||||
|
year={1977},
|
||||||
|
publisher={Plenum, New York}
|
||||||
|
}
|
||||||
|
@article{unruh1978,
|
||||||
|
title={Analysis of quantum-nondemolition measurement},
|
||||||
|
author={Unruh, WG},
|
||||||
|
journal={Physical Review D},
|
||||||
|
volume={18},
|
||||||
|
number={6},
|
||||||
|
pages={1764},
|
||||||
|
year={1978},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{brune1990,
|
||||||
|
title={Quantum nondemolition measurement of small photon numbers by
|
||||||
|
Rydberg-atom phase-sensitive detection},
|
||||||
|
author={Brune, M and Haroche, S and Lefevre, V and Raimond, JM and Zagury, N},
|
||||||
|
journal={Physical review letters},
|
||||||
|
volume={65},
|
||||||
|
number={8},
|
||||||
|
pages={976},
|
||||||
|
year={1990},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{roscilde2009,
|
||||||
|
title={Quantum polarization spectroscopy of correlations in attractive fermionic gases},
|
||||||
|
author={Roscilde, T and Rodriguez, M and Eckert, K and Romero-Isart,
|
||||||
|
O and Lewenstein, M and Polzik, E and Sanpera, A},
|
||||||
|
journal={New Journal of Physics},
|
||||||
|
volume={11},
|
||||||
|
number={5},
|
||||||
|
pages={055041},
|
||||||
|
year={2009},
|
||||||
|
publisher={IOP Publishing}
|
||||||
|
}
|
||||||
|
@article{eckert2008qnd,
|
||||||
|
title={Quantum non-demolition detection of strongly correlated systems},
|
||||||
|
author={Eckert, Kai and Romero-Isart, Oriol and Rodriguez, Mirta and
|
||||||
|
Lewenstein, Maciej and Polzik, Eugene S and Sanpera,
|
||||||
|
Anna},
|
||||||
|
journal={Nature Physics},
|
||||||
|
volume={4},
|
||||||
|
number={1},
|
||||||
|
pages={50--54},
|
||||||
|
year={2008},
|
||||||
|
publisher={Nature Publishing Group}
|
||||||
|
}
|
||||||
|
@article{hauke2013,
|
||||||
|
title={Quantum control of spin correlations in ultracold lattice gases},
|
||||||
|
author={Hauke, Philipp and Sewell, RJ and Mitchell, Morgan W and Lewenstein, Maciej},
|
||||||
|
journal={Physical Review A},
|
||||||
|
volume={87},
|
||||||
|
number={2},
|
||||||
|
pages={021601},
|
||||||
|
year={2013},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{carmichael1980,
|
||||||
|
title={Analytical and numerical results for the steady state in
|
||||||
|
cooperative resonance fluorescence},
|
||||||
|
author={Carmichael, HJ},
|
||||||
|
journal={Journal of Physics B: Atomic and Molecular Physics},
|
||||||
|
volume={13},
|
||||||
|
number={18},
|
||||||
|
pages={3551},
|
||||||
|
year={1980},
|
||||||
|
publisher={IOP Publishing}
|
||||||
|
}
|
||||||
|
@article{werner2005,
|
||||||
|
title={Phase diagram and critical exponents of a dissipative Ising
|
||||||
|
spin chain in a transverse magnetic field},
|
||||||
|
author={Werner, Philipp and V{\"o}lker, Klaus and Troyer, Matthias
|
||||||
|
and Chakravarty, Sudip},
|
||||||
|
journal={Physical review letters},
|
||||||
|
volume={94},
|
||||||
|
number={4},
|
||||||
|
pages={047201},
|
||||||
|
year={2005},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{capriotti2005,
|
||||||
|
title={Dissipation-driven phase transition in two-dimensional
|
||||||
|
Josephson arrays},
|
||||||
|
author={Capriotti, Luca and Cuccoli, Alessandro and Fubini, Andrea
|
||||||
|
and Tognetti, Valerio and Vaia, Ruggero},
|
||||||
|
journal={Physical review letters},
|
||||||
|
volume={94},
|
||||||
|
number={15},
|
||||||
|
pages={157001},
|
||||||
|
year={2005},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{morrison2008,
|
||||||
|
title={Dissipation-driven quantum phase transitions in collective spin systems},
|
||||||
|
author={Morrison, S and Parkins, AS},
|
||||||
|
journal={Journal of Physics B: Atomic, Molecular and Optical Physics},
|
||||||
|
volume={41},
|
||||||
|
number={19},
|
||||||
|
pages={195502},
|
||||||
|
year={2008},
|
||||||
|
publisher={IOP Publishing}
|
||||||
|
}
|
||||||
|
@article{eisert2010,
|
||||||
|
title={Noise-driven quantum criticality},
|
||||||
|
author={Eisert, J and Prosen, T},
|
||||||
|
journal={arXiv preprint arXiv:1012.5013},
|
||||||
|
year={2010}
|
||||||
|
}
|
||||||
|
@article{bhaseen2012,
|
||||||
|
title={Dynamics of nonequilibrium Dicke models},
|
||||||
|
author={Bhaseen, MJ and Mayoh, J and Simons, BD and Keeling, J},
|
||||||
|
journal={Physical Review A},
|
||||||
|
volume={85},
|
||||||
|
number={1},
|
||||||
|
pages={013817},
|
||||||
|
year={2012},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{diehl2010,
|
||||||
|
title={Dynamical phase transitions and instabilities in open atomic many-body systems},
|
||||||
|
author={Diehl, Sebastian and Tomadin, Andrea and Micheli, Andrea and
|
||||||
|
Fazio, Rosario and Zoller, Peter},
|
||||||
|
journal={Physical review letters},
|
||||||
|
volume={105},
|
||||||
|
number={1},
|
||||||
|
pages={015702},
|
||||||
|
year={2010},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{vznidarivc2011,
|
||||||
|
title={Solvable quantum nonequilibrium model exhibiting a phase
|
||||||
|
transition and a matrix product representation},
|
||||||
|
author={{\v{Z}}nidari{\v{c}}, Marko},
|
||||||
|
journal={Physical Review E},
|
||||||
|
volume={83},
|
||||||
|
number={1},
|
||||||
|
pages={011108},
|
||||||
|
year={2011},
|
||||||
|
publisher={APS}
|
||||||
|
}
|
||||||
|
@article{itano1990,
|
||||||
|
title = {Quantum Zeno effect},
|
||||||
|
author = {Itano, Wayne M. and Heinzen, D. J. and Bollinger,
|
||||||
|
J. J. and Wineland, D. J.},
|
||||||
|
journal = {Phys. Rev. A},
|
||||||
|
volume = {41},
|
||||||
|
issue = {5},
|
||||||
|
pages = {2295--2300},
|
||||||
|
numpages = {0},
|
||||||
|
year = {1990},
|
||||||
|
month = {Mar},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{nagels1997,
|
||||||
|
title = {Quantum Zeno Effect Induced by Collisions},
|
||||||
|
author = {Nagels, B. and Hermans, L. J. F. and Chapovsky, P. L.},
|
||||||
|
journal = {Phys. Rev. Lett.},
|
||||||
|
volume = {79},
|
||||||
|
issue = {17},
|
||||||
|
pages = {3097--3100},
|
||||||
|
numpages = {0},
|
||||||
|
year = {1997},
|
||||||
|
month = {Oct},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{kwiat1999,
|
||||||
|
title = {High-Efficiency Quantum Interrogation Measurements via the Quantum Zeno Effect},
|
||||||
|
author = {Kwiat, P. G. and White, A. G. and Mitchell, J. R. and
|
||||||
|
Nairz, O. and Weihs, G. and Weinfurter, H. and
|
||||||
|
Zeilinger, A.},
|
||||||
|
journal = {Phys. Rev. Lett.},
|
||||||
|
volume = {83},
|
||||||
|
issue = {23},
|
||||||
|
pages = {4725--4728},
|
||||||
|
numpages = {0},
|
||||||
|
year = {1999},
|
||||||
|
month = {Dec},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{balzer2000,
|
||||||
|
title = {The quantum Zeno effect – evolution of an atom impeded by measurement},
|
||||||
|
journal = {Optics Communications},
|
||||||
|
volume = {180},
|
||||||
|
number = {1–3},
|
||||||
|
pages = {115-120},
|
||||||
|
year = {2000},
|
||||||
|
author = {Chr. Balzer and R. Huesmann and W. Neuhauser and P.E. Toschek}
|
||||||
|
}
|
||||||
|
@article{streed2006,
|
||||||
|
title = {Continuous and Pulsed Quantum Zeno Effect},
|
||||||
|
author = {Streed, Erik W. and Mun, Jongchul and Boyd, Micah and
|
||||||
|
Campbell, Gretchen K. and Medley, Patrick and
|
||||||
|
Ketterle, Wolfgang and Pritchard, David E.},
|
||||||
|
journal = {Phys. Rev. Lett.},
|
||||||
|
volume = {97},
|
||||||
|
issue = {26},
|
||||||
|
pages = {260402},
|
||||||
|
numpages = {4},
|
||||||
|
year = {2006},
|
||||||
|
month = {Dec},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{hosten2006,
|
||||||
|
title = {Counterfactual quantum computation through quantum interrogation},
|
||||||
|
author = {Hosten, Onur and Rakher, Matthew T. and Barreiro, Julio
|
||||||
|
T. and Peters, Nicholas A. and Kwiat, Paul G.},
|
||||||
|
journal = {Nature},
|
||||||
|
volume = {439},
|
||||||
|
issue = {7079},
|
||||||
|
pages = {949-952},
|
||||||
|
numpages = {4},
|
||||||
|
year = {2006},
|
||||||
|
}
|
||||||
|
@article{bernu2008,
|
||||||
|
title = {Freezing Coherent Field Growth in a Cavity by the Quantum Zeno Effect},
|
||||||
|
author = {Bernu, J. and Del\'eglise, S. and Sayrin, C. and Kuhr,
|
||||||
|
S. and Dotsenko, I. and Brune, M. and Raimond,
|
||||||
|
J. M. and Haroche, S.},
|
||||||
|
journal = {Phys. Rev. Lett.},
|
||||||
|
volume = {101},
|
||||||
|
issue = {18},
|
||||||
|
pages = {180402},
|
||||||
|
numpages = {4},
|
||||||
|
year = {2008},
|
||||||
|
month = {Oct},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{hatano1996,
|
||||||
|
title = {Localization Transitions in Non-Hermitian Quantum Mechanics},
|
||||||
|
author = {Hatano, Naomichi and Nelson, David R.},
|
||||||
|
journal = {Phys. Rev. Lett.},
|
||||||
|
volume = {77},
|
||||||
|
issue = {3},
|
||||||
|
pages = {570--573},
|
||||||
|
numpages = {0},
|
||||||
|
year = {1996},
|
||||||
|
month = {Jul},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{refael2006,
|
||||||
|
title = {Transverse Meissner physics of planar superconductors with columnar pins},
|
||||||
|
author = {Refael, Gil and Hofstetter, Walter and Nelson, David R.},
|
||||||
|
journal = {Phys. Rev. B},
|
||||||
|
volume = {74},
|
||||||
|
issue = {17},
|
||||||
|
pages = {174520},
|
||||||
|
numpages = {20},
|
||||||
|
year = {2006},
|
||||||
|
month = {Nov},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{bender1998,
|
||||||
|
title = {Real Spectra in Non-Hermitian Hamiltonians Having $\mathcal{P}\mathcal{T}$ Symmetry},
|
||||||
|
author = {Bender, Carl M. and Boettcher, Stefan},
|
||||||
|
journal = {Phys. Rev. Lett.},
|
||||||
|
volume = {80},
|
||||||
|
issue = {24},
|
||||||
|
pages = {5243--5246},
|
||||||
|
numpages = {0},
|
||||||
|
year = {1998},
|
||||||
|
month = {Jun},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{giorgi2010,
|
||||||
|
title = {Spontaneous $\mathcal{P}\mathcal{T}$ symmetry breaking and quantum phase transitions in dimerized spin chains},
|
||||||
|
author = {Giorgi, Gian Luca},
|
||||||
|
journal = {Phys. Rev. B},
|
||||||
|
volume = {82},
|
||||||
|
issue = {5},
|
||||||
|
pages = {052404},
|
||||||
|
numpages = {4},
|
||||||
|
year = {2010},
|
||||||
|
month = {Aug},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@article{zhang2013,
|
||||||
|
title = {Non-Hermitian anisotropic $XY$ model with intrinsic
|
||||||
|
rotation-time-reversal symmetry},
|
||||||
|
author = {Zhang, X. Z. and Song, Z.},
|
||||||
|
journal = {Phys. Rev. A},
|
||||||
|
volume = {87},
|
||||||
|
issue = {1},
|
||||||
|
pages = {012114},
|
||||||
|
numpages = {7},
|
||||||
|
year = {2013},
|
||||||
|
month = {Jan},
|
||||||
|
publisher = {American Physical Society},
|
||||||
|
}
|
||||||
|
@ -1,7 +1,7 @@
|
|||||||
% ******************************* PhD Thesis Template **************************
|
% ******************************* PhD Thesis Template **************************
|
||||||
% Please have a look at the README.md file for info on how to use the template
|
% Please have a look at the README.md file for info on how to use the template
|
||||||
|
|
||||||
\documentclass[a4paper,12pt,times,numbered,print,chapter]{Classes/PhDThesisPSnPDF}
|
\documentclass[a4paper,12pt,times,numbered,print]{Classes/PhDThesisPSnPDF}
|
||||||
|
|
||||||
% ******************************************************************************
|
% ******************************************************************************
|
||||||
% ******************************* Class Options ********************************
|
% ******************************* Class Options ********************************
|
||||||
@ -101,7 +101,7 @@
|
|||||||
% To use choose `chapter' option in the document class
|
% To use choose `chapter' option in the document class
|
||||||
|
|
||||||
\ifdefineChapter
|
\ifdefineChapter
|
||||||
\includeonly{Chapter1/chapter1}
|
\includeonly{Abstract/Abstract}
|
||||||
\fi
|
\fi
|
||||||
|
|
||||||
% ******************************** Front Matter ********************************
|
% ******************************** Front Matter ********************************
|
||||||
|
Reference in New Issue
Block a user