Chiral spin textures in a frustrated kondo lattice model
Strongly correlated electron systems in which there exists a subtle interplay between spin and charge degrees of freedom give rise to many novel and exotic phases. In these spin-charge coupled systems the itinerant electrons and localized moments affect each other in a self-consistent way. The ma...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2017
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| Online Access: | http://hdl.handle.net/10356/69609 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Strongly correlated electron systems in which there exists a subtle interplay between spin and
charge degrees of freedom give rise to many novel and exotic phases. In these spin-charge coupled
systems the itinerant electrons and localized moments affect each other in a self-consistent way. The
magnetic interaction between the spins is mediated by the motion of electrons; on the other hand,
the transport of these electrons is affected by the underlying spin textures. These systems when
arranged on geometrically frustrated lattices stabilize topologically non-trivial chiral configurations of
localized spins that drive unconventional transport phenomenon such as topological or geometrical
Hall effect. The Shastry-Sutherland model with appropriate generalization is an excellent framework
to study the interplay between charge and spin degrees of freedom on a frustrated geometry.
Furthermore, such a model is directly relevant in understanding the transport of rare earth
tetraborides – a family of metallic quantum magnets with underlying magnetic Shastry-Sutherland
lattice. We investigate Shastry-Sutherland Kondo lattice model (SS-KLM) extensively in different
parameter regimes for the ground state phases with unique topological properties using a suite of
numerical methods. To reduce finite-size effects we have implemented two approximate methods
truncated polynomial expansion method and traveling cluster approximation – the CPU time for
both these methods scales linearly with the system size making it possible to explore larger lattice
sizes. We present results for integer quantum Hall effect on Shastry-Sutherland lattice in the
presence of longitudinal magnetic field. The strong frustration results in decreasing the width of
plateaus in Hall conductivity while strong disorder leads to the disappearance of higher plateaus.
The rise in temperature smooths out the steps in Hall conductivity making longitudinal conductivity
non-zero over the whole range of Fermi energy. We establish the existence of several non-coplanar
ground states in the phase diagram of SS-KLM using variational ansatz at T = 0. The previously
unknown canted-Flux state is shown to be stabilized over wide range of parametric space in the
presence of Dzyaloshinskii-Moriya interaction. Using unbiased Monte Carlo method we show that
this complex ground state can be generated dynamically starting from random spin configurations
even at non-zero but a finite value of temperature at half filling of itinerant electrons. Moreover, the
non-coplanarity of such topologically non-trivial spin textures can be tuned using magnetic field. We
also demonstrate that non-coplanar ground states are stabilized for n e = 1/4 and 3/4 against
thermal fluctuations. Tuning the strength of frustration is shown to drive the system from canted
Flux state through different intermediate topologically non-trivial states to topologically trivial anti
ferromagnetic ground state. We show that the ground states with different topological character can
be stabilized with the help of magnetic field. Our results are crucial in understanding the emergence
of complex spin textures in metallic magnets and will be important in explaining the magnetic and
electronic properties of the rare earth tetraboride family of frustrated metallic magnets. |
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