Dynamical and statistical properties of anyons in fractional quantum hall effect
The quantum Hall effect has been the prototypical example for many emerging fields of Physics, including the study of topological phases of matter, topological order, and topological insulators. The objects of interest in this thesis are anyons, which are elementary excitations in fractional quan...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
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Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/173206 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The quantum Hall effect has been the prototypical example for many emerging
fields of Physics, including the study of topological phases of matter, topological
order, and topological insulators. The objects of interest in this thesis are anyons,
which are elementary excitations in fractional quantum Hall (FQH) fluids. Anyons
are quasiparticles with fractional charge and fractional statistics. The latter prop-
erty makes it a subject of immense interest due to application in fault-tolerant
quantum computing. Here, we employ a perspective that anyons are the appro-
priate degree of freedom to describe the relevant physics of FQH systems. This is
because when a topological phase is assumed and the energy gap goes to infinity,
anyons (“quasiholes”) are the only possible elementary excitations, since they are
not energetically punished by the correspondng model Hamiltonian. With respect
to a realistic Hamiltonian, however, this choice of degree of freedom depends on
the exact effective interaction in the system. For example, while the Laughlin
state is the model state at filling factor n + 1/3 (where n is some integer), when
the effective electron-electron interaction is more long-ranged, the quasiholes of a
Gaffnian state may be excited and become the better degree of freedom to describe
physics in the same filling factor. This perspective results in a surprising observa-
tion that a Laughlin quasihole may fractionalize under certain conditions, leading
to a quasiparticle of charge e/6 that can potentially be detected in experiments.
Another important aspect of anyons is their intrinsic spin and the corresponding
spin-statistics relation, which must account for the fact that FQH anyons are not
point particles, but objects with finite sizes and intricate internal structures. Our
investigation leads to a rigorous derivation of the general spin-statistics relation
for anyons in Abelian FQH phases. Furthermore, we show it is possible to fully
capture the important features of the statistics by a conformal Hilbert space (CHS)
description. Our analysis provides the necessary tools to study such geometric
effects, which we use to investigate how disorder in a realistic system may affect
different experimental schemes for measuring anyon statistics. |
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