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Author
Date
2019-11Type
- Doctoral Thesis
ETH Bibliography
yes
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Abstract
Quantum optics, the study of light at the level of its building blocks,
has been one of the frontiers of science. The arena of quantum optics
has been fruitful for investigations of a wide range of interesting questions,
from those on the fundamental structures in driven dissipative
systems to those on applications of quantum information processing
and quantum communication.
The first part of this thesis is concerned with one of the holy grails
of quantum optics: an efficient transfer of energy (coupling) between
single photons and matter degrees of freedom. From a certain point
of view, the problem of efficient coupling is purely geometrical. The
efficiency of coupling between an atom and light is difficult because
it is difficult to shape the wavefunction of a single photon such
that it overlaps perfectly with the matter degree of freedom (emitter).
The first contribution of this thesis is addressing this issue by considering
an emitter which perfectly matches the single photon plane-wave.
Moreover, luckily, such an emitter is already realized in nature in the
form of a two-dimensional crystal. We show that a new generation
of two-dimensional semiconductors, transition metal dichalcogenide
(TMD) monolayers, have especially favorable characteristics for allowing
highly efficient coupling between photons and matter degrees
of freedom.
One of the most important goals in realizing an efficient coupling
between photons and matter degrees of freedom is that unlike photons,
matter excitations interact with each other. Hence, if we would
like to have photons which act as if they interact, one possible way
is to first convert them into matter excitations, and then transfer the
correlations due matter interactions back to photons. As the second
contribution of this thesis, we demonstrate that TMD monolayers placed
within a cavity can help us create photons which avoid each other
as if they interact. The effect can be simply understood as the TMD
monolayer acting as a filter for photons, such that it only allows the
passage of one photon at a time.
Besides being the fundamental building block of light, photons also
serve as mediators of interactions between charged particles. In a
sense, two positive charges repel each other because there is always
a photon which lets them know that they are close to one another.
On the other hand, systems of many interacting particles behave in
a completely different way then when they are alone. It may even be
argued that all physical phenomena at some level emerge from the
behavior of many interacting constituents. Given this point of view,
it is crucial to find ways to control photons in order to control the
interactions that they mediate between matter degrees of freedom.
As the third contribution of this thesis, we analyze an experimental
scheme where the control of photonic degrees of freedom can allow
an experimentalist to modify the strength and range of interactions
between matter. In particular, we propose squeezed photon states as
a resource to control such interactions.
The second part of this thesis is concerned with the emergent phenomena
arising in a system of many interacting particles. In particular,
the fourth contribution of this thesis considers the combination
of two fascinating phenomena which emerges such condensed matter
systems: superconductivity and geometric effects in lattice band
structures. Separately, both superconductivity and the non-trivial geometrical
effects in lattice systems are well-established subfields of condensed
matter physics. Yet only more recently, the combination of
these two phenomena were investigated in the context of topological
superconductors, as well as other superconducting states which emerge
on top of band structures with non-trivial geometry. In our study,
we attempt at clarifying one of the ways that the non-trivial geometry
associated with the lattice band structure may affect the dynamics of
an emergent superconducting state. Surprisingly, our analysis shows
that one of the most robust characteristics of the superconductor, vortices
enclosing a quantum of magnetic flux, can be modified due to
geometrical effects. Show more
Permanent link
https://doi.org/10.3929/ethz-b-000376888Publication status
publishedExternal links
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Publisher
ETH ZurichOrganisational unit
03636 - Imamoglu, Atac / Imamoglu, Atac
08714 - Gruppe Huber
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ETH Bibliography
yes
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