183 research outputs found
Subtle leakage of a Majorana mode into a quantum dot
We investigate quantum transport through a quantum dot connected to source
and drain leads and side-coupled to a topological superconducting nanowire
(Kitaev chain) sustaining Majorana end modes. Using a recursive Green's
function approach, we determine the local density of states (LDOS) of the
system and find that the end Majorana mode of the wire leaks into the dot thus
emerging as a unique dot level {\it pinned} to the Fermi energy
of the leads. Surprisingly, this resonance pinning, resembling in this sense a
"Kondo resonance", occurs even when the gate-controlled dot level
is far above or far below . The
calculated conductance of the dot exhibits an unambiguous signature for the
Majorana end mode of the wire: in essence, an off-resonance dot
[], which should have ,
shows instead a conductance over a wide range of , due to this
pinned dot mode. Interestingly, this pinning effect only occurs when the dot
level is coupled to a Majorana mode; ordinary fermionic modes (e.g., disorder)
in the wire simply split and broaden (if a continuum) the dot level. We discuss
experimental scenarios to probe Majorana modes in wires via these leaked/pinned
dot modes.Comment: 3 figures, 5 pages, published in Phys. Rev. B (Editors' suggestion
Helical edge states in multiple topological mass domains
The two-dimensional topological insulating phase has been experimentally
discovered in HgTe quantum wells (QWs). The low-energy physics of
two-dimensional topological insulators (TIs) is described by the
Bernevig-Hughes-Zhang (BHZ) model, where the realization of a topological or a
normal insulating phase depends on the Dirac mass being negative or positive,
respectively. We solve the BHZ model for a mass domain configuration, analyzing
the effects on the edge modes of a finite Dirac mass in the normal insulating
region (soft-wall boundary condition). We show that at a boundary between a TI
and a normal insulator (NI), the Dirac point of the edge states appearing at
the interface strongly depends on the ratio between the Dirac masses in the two
regions. We also consider the case of multiple boundaries such as NI/TI/NI,
TI/NI/TI and NI/TI/NI/TI.Comment: 11 pages, 15 figure
Helical edge states in multiple topological mass domains
The two-dimensional topological insulating phase has been experimentally
discovered in HgTe quantum wells (QWs). The low-energy physics of
two-dimensional topological insulators (TIs) is described by the
Bernevig-Hughes-Zhang (BHZ) model, where the realization of a topological or a
normal insulating phase depends on the Dirac mass being negative or positive,
respectively. We solve the BHZ model for a mass domain configuration, analyzing
the effects on the edge modes of a finite Dirac mass in the normal insulating
region (soft-wall boundary condition). We show that at a boundary between a TI
and a normal insulator (NI), the Dirac point of the edge states appearing at
the interface strongly depends on the ratio between the Dirac masses in the two
regions. We also consider the case of multiple boundaries such as NI/TI/NI,
TI/NI/TI and NI/TI/NI/TI.Comment: 11 pages, 15 figure
Scanning Tunneling Microscope Operating as a Spin-diode
We theoretically investigate spin-polarized transport in a system composed of
a ferromagnetic Scanning Tunneling Microscope (STM) tip coupled to an adsorbed
atom (adatom) on a host surface. Electrons can tunnel directly from the tip to
the surface or via the adatom. Since the tip is ferromagnetic and the host
surface (metal or semiconductor) is non-magnetic we obtain a spin-diode effect
when the adatom is in the regime of single occupancy. This effect leads to an
unpolarized current for direct bias (V > 0) and polarized current for reverse
(V < 0) bias voltages, if the tip is nearby the adatom. Within the
nonequilibrium Keldysh technique we analyze the interplay between the lateral
displacement of the tip and the intra adatom Coulomb interaction on the
spindiode effect. As the tip moves away from the adatom the spin-diode effect
vanishes and the currents become polarized for both V > 0 and V < 0. We also
find an imbalance between the up and down spin populations in the adatom, which
can be tuned by the tip position and the bias. Finally, due to the presence of
the adsorbate on the surface, we observe spin-resolved Friedel oscillations in
the current, which reflects the oscillations in the calculated LDOS of the
subsystem surface+adatom.Comment: 11 pages, 4 figures. Submitte
Ichneumonidae (Hymenoptera) capturados em armadilhas Malaise, em Rio Branco, AC.
A ordem Hymenoptera abriga espécies com hábitos parasitas ou predadores de outros insetos e, ainda, espécies polinizadoras de plantas. Constituem um grupo muito diversificado no que tange aos hábitos alimentares e comportamentais. As vespas parasitoides participam em mais de 50% das cadeias alimentares dos ambientes terrestres. A família Ichneumonidae é uma das maiores entre os Insecta, com aproximadamente 60.000 espécies descritas, sendo cerca de 17.000 na região Neotropical. Embora sua importância seja evidente, estudos da biodiversidade de parasitoides na região amazônica são escassos. Neste sentido, o objetivo deste levantamento foi aumentar o conhecimento sobre a fauna de Ichneumonidae no estado do Acre. Foram instaladas duas armadilhas Malaise (uma na bordadura e outra no interior) em um remanescente florestal, localizado no município de Rio Branco, AC. Semanalmente os frascos coletores, contendo álcool a 90%, eram recolhidos e trocados por novos. O material foi triado em laboratório e os parasitoides identificados em nível de subfamília, sob microscópio estereoscópio. A armadilha localizada na bordadura capturou 133 parasitoides de 13 subfamílias, enquanto a localizada no interior da mata capturou 210, de 15 subfamílias. As principais subfamílias foram Cryptinae e Cremastinae, correspondendo a aproximadamente 75% de todos os parasitoides capturados neste levantamento
Grain Surface Models and Data for Astrochemistry
AbstractThe cross-disciplinary field of astrochemistry exists to understand the formation, destruction, and survival of molecules in astrophysical environments. Molecules in space are synthesized via a large variety of gas-phase reactions, and reactions on dust-grain surfaces, where the surface acts as a catalyst. A broad consensus has been reached in the astrochemistry community on how to suitably treat gas-phase processes in models, and also on how to present the necessary reaction data in databases; however, no such consensus has yet been reached for grain-surface processes. A team of ∼25 experts covering observational, laboratory and theoretical (astro)chemistry met in summer of 2014 at the Lorentz Center in Leiden with the aim to provide solutions for this problem and to review the current state-of-the-art of grain surface models, both in terms of technical implementation into models as well as the most up-to-date information available from experiments and chemical computations. This review builds on the results of this workshop and gives an outlook for future directions
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