725 research outputs found
Topological defects in flat nanomagnets: the magnetostatic limit
We discuss elementary topological defects in soft magnetic nanoparticles in
the thin-film geometry. In the limit dominated by magnetostatic forces the
low-energy defects are vortices (winding number n = +1), cross ties (n = -1),
and edge defects with n = -1/2. We obtain topological constraints on the
possible composition of domain walls. The simplest domain wall in this regime
is composed of two -1/2 edge defects and a vortex, in accordance with
observations and numerics.Comment: 3 pages, eps figures. Proceedings of MMM 0
Carrier dynamics and coherent acoustic phonons in nitride heterostructures
We model generation and propagation of coherent acoustic phonons in
piezoelectric InGaN/GaN multi-quantum wells embedded in a \textit{pin} diode
structure and compute the time resolved reflectivity signal in simulated
pump-probe experiments. Carriers are created in the InGaN wells by ultrafast
pumping below the GaN band gap and the dynamics of the photoexcited carriers is
treated in a Boltzmann equation framework. Coherent acoustic phonons are
generated in the quantum well via both deformation potential electron-phonon
and piezoelectric electron-phonon interaction with photogenerated carriers,
with the latter mechanism being the dominant one. Coherent longitudinal
acoustic phonons propagate into the structure at the sound speed modifying the
optical properties and giving rise to a giant oscillatory differential
reflectivity signal. We demonstrate that coherent optical control of the
differential reflectivity can be achieved using a delayed control pulse.Comment: 14 pages, 11 figure
Classical Topological Order in Kagome Ice
We examine the onset of classical topological order in a nearest-neighbor
kagome ice model. Using Monte Carlo simulations, we characterize the
topological sectors of the groundstate using a non-local cut measure which
circumscribes the toroidal geometry of the simulation cell. We demonstrate that
simulations which employ global loop updates that are allowed to wind around
the periodic boundaries cause the topological sector to fluctuate, while
restricted local loop updates freeze the simulation into one topological
sector. The freezing into one topological sector can also be observed in the
susceptibility of the real magnetic spin vectors projected onto the kagome
plane. The ability of the susceptibility to distinguish between fluctuating and
non-fluctuating topological sectors should motivate its use as a local probe of
topological order in a variety of related model and experimental systems.Comment: 17 pages, 9 figure
Propagating Coherent Acoustic Phonon Wavepackets in InMnAs/GaSb
We observe pronounced oscillations in the differential reflectivity of a
ferromagnetic InMnAs/GaSb heterostructure using two-color pump-probe
spectroscopy. Although originally thought to be associated with the
ferromagnetism, our studies show that the oscillations instead result from
changes in the position and frequency-dependent dielectric function due to the
generation of coherent acoustic phonons in the ferromagnetic InMnAs layer and
their subsequent propagation into the GaSb. Our theory accurately predicts the
experimentally measured oscillation period and decay time as a function of
probe wavelength.Comment: 4 pages, 4 figure
Euler numbers of four-dimensional rotating black holes with the Euclidean signature
For a black hole's spacetime manifold in the Euclidean signature, its metric
is positive definite and therefore a Riemannian manifold. It can be regarded as
a gravitational instanton and a topological characteristic which is the Euler
number is associated. In this paper we derive a formula for the Euler numbers
of four-dimensional rotating black holes by the integral of the Euler density
on the spacetime manifolds of black holes. Using this formula, we obtain that
the Euler numbers of Kerr and Kerr-Newman black holes are 2. We also obtain
that the Euler number of the Kerr-Sen metric in the heterotic string theory
with one boost angle nonzero is 2 that is in accordence with its topology.Comment: 15 pages, Latex, arxiv-id for the refs. supplemente
Helimagnons in a chiral ground state of the pyrochlore antiferromagnets
The Goldstone mode in a helical magnetic phase, also known as the helimagnon,
is a propagating mode with a highly anisotropic dispersion relation. Here we
study theoretically the helimagnon excitations in a complex chiral ground state
of pyrochlore antiferromagnets such as spinel CdCr2O4 and itinerant magnet
YMn2. We show that the effective theory of the soft modes in the helical state
possesses a symmetry similar to that of smectic liquid crystals. We compute the
low-energy spin-wave spectrum based on a microscopic spin Hamiltonian and find
a dispersion relation characteristic of the helimagnons. By performing dynamics
simulations with realistic model parameters, we also obtain an overall
agreement between experiment and the numerical spin-wave spectrum. Our work
thus also clarifies the mechanisms that relive the magnetic frustration in
these compounds.Comment: 5 pages, 3 figure
Local and nonlocal solvable structures in ODEs reduction
Solvable structures, likewise solvable algebras of local symmetries, can be
used to integrate scalar ODEs by quadratures. Solvable structures, however, are
particularly suitable for the integration of ODEs with a lack of local
symmetries. In fact, under regularity assumptions, any given ODE always admits
solvable structures even though finding them in general could be a very
difficult task. In practice a noteworthy simplification may come by computing
solvable structures which are adapted to some admitted symmetry algebra. In
this paper we consider solvable structures adapted to local and nonlocal
symmetry algebras of any order (i.e., classical and higher). In particular we
introduce the notion of nonlocal solvable structure
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