344 research outputs found
Topological semimetal in a fermionic optical lattice
Optical lattices play a versatile role in advancing our understanding of
correlated quantum matter. The recent implementation of orbital degrees of
freedom in chequerboard and hexagonal optical lattices opens up a new thrust
towards discovering novel quantum states of matter, which have no prior analogs
in solid state electronic materials. Here, we demonstrate that an exotic
topological semimetal emerges as a parity-protected gapless state in the
orbital bands of a two-dimensional fermionic optical lattice. The new quantum
state is characterized by a parabolic band-degeneracy point with Berry flux
, in sharp contrast to the flux of Dirac points as in graphene. We
prove that the appearance of this topological liquid is universal for all
lattices with D point group symmetry as long as orbitals with opposite
parities hybridize strongly with each other and the band degeneracy is
protected by odd parity. Turning on inter-particle repulsive interactions, the
system undergoes a phase transition to a topological insulator whose
experimental signature includes chiral gapless domain-wall modes, reminiscent
of quantum Hall edge states.Comment: 6 pages, 3 figures and Supplementary Informatio
Exoplanet phase curves: observations and theory
Phase curves are the best technique to probe the three dimensional structure
of exoplanets' atmospheres. In this chapter we first review current exoplanets
phase curve observations and the particular challenges they face. We then
describe the different physical mechanisms shaping the atmospheric phase curves
of highly irradiated tidally locked exoplanets. Finally, we discuss the
potential for future missions to further advance our understanding of these new
worlds.Comment: Fig.5 has been updated. Table 1 and corresponding figures have been
updated with new values for WASP-103b and WASP-18b. Contains a table
sumarizing phase curve observation
Quantum Computing
Quantum mechanics---the theory describing the fundamental workings of
nature---is famously counterintuitive: it predicts that a particle can be in
two places at the same time, and that two remote particles can be inextricably
and instantaneously linked. These predictions have been the topic of intense
metaphysical debate ever since the theory's inception early last century.
However, supreme predictive power combined with direct experimental observation
of some of these unusual phenomena leave little doubt as to its fundamental
correctness. In fact, without quantum mechanics we could not explain the
workings of a laser, nor indeed how a fridge magnet operates. Over the last
several decades quantum information science has emerged to seek answers to the
question: can we gain some advantage by storing, transmitting and processing
information encoded in systems that exhibit these unique quantum properties?
Today it is understood that the answer is yes. Many research groups around the
world are working towards one of the most ambitious goals humankind has ever
embarked upon: a quantum computer that promises to exponentially improve
computational power for particular tasks. A number of physical systems,
spanning much of modern physics, are being developed for this task---ranging
from single particles of light to superconducting circuits---and it is not yet
clear which, if any, will ultimately prove successful. Here we describe the
latest developments for each of the leading approaches and explain what the
major challenges are for the future.Comment: 26 pages, 7 figures, 291 references. Early draft of Nature 464, 45-53
(4 March 2010). Published version is more up-to-date and has several
corrections, but is half the length with far fewer reference
Electron spin coherence exceeding seconds in high purity silicon
Silicon is undoubtedly one of the most promising semiconductor materials for
spin-based information processing devices. Its highly advanced fabrication
technology facilitates the transition from individual devices to large-scale
processors, and the availability of an isotopically-purified Si form
with no magnetic nuclei overcomes what is a main source of spin decoherence in
many other materials. Nevertheless, the coherence lifetimes of electron spins
in the solid state have typically remained several orders of magnitude lower
than what can be achieved in isolated high-vacuum systems such as trapped ions.
Here we examine electron spin coherence of donors in very pure Si
material, with a residual Si concentration of less than 50 ppm and donor
densities of per cm. We elucidate three separate mechanisms
for spin decoherence, active at different temperatures, and extract a coherence
lifetime up to 2 seconds. In this regime, we find the electron spin is
sensitive to interactions with other donor electron spins separated by ~200 nm.
We apply a magnetic field gradient in order to suppress such interactions and
obtain an extrapolated electron spin of 10 seconds at 1.8 K. These
coherence lifetimes are without peer in the solid state by several orders of
magnitude and comparable with high-vacuum qubits, making electron spins of
donors in silicon ideal components of a quantum computer, or quantum memories
for systems such as superconducting qubits.Comment: 18 pages, 4 figures, supplementary informatio
The primary therapy chosen for patients with localized prostate cancer between the university hospital and its affiliated hospitals in Nara Uro-oncological research group registration
<p>Abstract</p> <p>Background</p> <p>We investigated the differences between the preferential primary therapy conceived by the primary doctors and the primary therapy actually conducted for prostate cancer patients in Nara, Japan.</p> <p>Methods</p> <p>The distribution of primary therapy and clinical characteristics of 2303 prostate cancer patients - diagnosed between 2004 and 2006 at Nara Medical University and its 23 affiliated hospitals - were assessed. Moreover, the preferential primary therapy for the patients at each clinical stage (cT1-T3bN0M0) conceived by the primary doctors was investigated and compared to the actual therapy.</p> <p>Results</p> <p>Of all patients, 51% received primary androgen deprivation therapy (PADT), 30% underwent radical prostatectomy (RP), and 14% received radiation therapy (RT). The preferential primary therapy for cT1-2N0M0 was RP (92%) while 38% of the patients actually received PADT (RP: 40%). For cT3aN0M0, the preferential primary therapy was both RP and external beam radiation therapy (EBRT) while 58% of the patients actually received PADT (RP: 16%, EBRT: 24%). For cT3bN0M0, the most preferential primary therapy was EBRT (46%) while 67% of the patients actually received PADT (EBRT: 21%). This trend was more notable in the affiliated hospitals than in the University hospital. The hospitals with lower volume of RP per year significantly conducted PADT compared with those with higher volume of RP.</p> <p>Conclusions</p> <p>PADT was commonly used to treat localized prostate cancer as well as locally advanced prostate cancer in Japan. There was a definite discrepancy between the preferential primary therapy conceived by the primary doctors and the actual therapy provided to the patients.</p
Dynamics of a Quantum Phase Transition and Relaxation to a Steady State
We review recent theoretical work on two closely related issues: excitation
of an isolated quantum condensed matter system driven adiabatically across a
continuous quantum phase transition or a gapless phase, and apparent relaxation
of an excited system after a sudden quench of a parameter in its Hamiltonian.
Accordingly the review is divided into two parts. The first part revolves
around a quantum version of the Kibble-Zurek mechanism including also phenomena
that go beyond this simple paradigm. What they have in common is that
excitation of a gapless many-body system scales with a power of the driving
rate. The second part attempts a systematic presentation of recent results and
conjectures on apparent relaxation of a pure state of an isolated quantum
many-body system after its excitation by a sudden quench. This research is
motivated in part by recent experimental developments in the physics of
ultracold atoms with potential applications in the adiabatic quantum state
preparation and quantum computation.Comment: 117 pages; review accepted in Advances in Physic
Optical switching of nuclear spin–spin couplings in semiconductors
Two-qubit operation is an essential part of quantum computation. However, solid-state nuclear magnetic resonance quantum computing has not been able to fully implement this functionality, because it requires a switchable inter-qubit coupling that controls the time evolutions of entanglements. Nuclear dipolar coupling is beneficial in that it is present whenever nuclear–spin qubits are close to each other, while it complicates two-qubit operation because the qubits must remain decoupled to prevent unwanted couplings. Here we introduce optically controllable internuclear coupling in semiconductors. The coupling strength can be adjusted externally through light power and even allows on/off switching. This feature provides a simple way of switching inter-qubit couplings in semiconductor-based quantum computers. In addition, its long reach compared with nuclear dipolar couplings allows a variety of options for arranging qubits, as they need not be next to each other to secure couplings
A spin-orbit coupled Bose-Einstein condensate
Spin-orbit (SO) coupling -- the interaction between a quantum particle's spin
and its momentum -- is ubiquitous in nature, from atoms to solids. In condensed
matter systems, SO coupling is crucial for the spin-Hall effect and topological
insulators, which are of extensive interest; it contributes to the electronic
properties of materials such as GaAs, and is important for spintronic devices.
Ultracold atoms, quantum many-body systems under precise experimental control,
would seem to be an ideal platform to study these fascinating SO coupled
systems. While an atom's intrinsic SO coupling affects its electronic
structure, it does not lead to coupling between the spin and the center-of-mass
motion of the atom. Here, we engineer SO coupling (with equal Rashba and
Dresselhaus strengths) in a neutral atomic Bose-Einstein condensate by dressing
two atomic spin states with a pair of lasers. Not only is this the first SO
coupling realized in ultracold atomic gases, it is also the first ever for
bosons. Furthermore, in the presence of the laser coupling, the interactions
between the two dressed atomic spin states are modified, driving a quantum
phase transition from a spatially spin-mixed state (lasers off) to a phase
separated state (above a critical laser intensity). The location of this
transition is in quantitative agreement with our theory. This SO coupling --
equally applicable for bosons and fermions -- sets the stage to realize
topological insulators in fermionic neutral atom systems.Comment: 25 pages, 4 figure
The Spin Structure of the Nucleon
We present an overview of recent experimental and theoretical advances in our
understanding of the spin structure of protons and neutrons.Comment: 84 pages, 29 figure
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