14 research outputs found
Coherent transport in linear arrays of quantum dots: the effects of period doubling and of quasi-periodicity
We evaluate the phase-coherent transport of electrons along linear structures
of varying length, which are made from two types of potential wells set in
either a periodic or a Fibonacci quasi-periodic sequence. The array is
described by a tight-binding Hamiltonian and is reduced to an effective dimer
by means of a decimation-renormalization method, extended to allow for
connection to external metallic leads, and the transmission coefficient is
evaluated in a T-matrix scattering approach. Parallel behaviors are found for
the energy dependence of the density of electron states and of the
transmittivity of the array. In particular, we explicitly show that on
increasing its length the periodic array undergoes a metal-insulator transition
near single occupancy per dot, whereas prominent pseudo-gaps emerge away from
the band center in the Fibonacci-ordered array.Comment: 11 pages, 7 figure
Theory of coherent transport by an ultra-cold atomic Fermi gas through linear arrays of potential wells
Growing interest is being given to transport of ultra-cold atomic gases
through optical lattices generated by the interference of laser beams. In this
connection we evaluate the phase-coherent transport of a spin-polarized gas of
fermionic atoms along linear structures made from potential wells set in four
alternative types of sequence. These are periodic chains of either identical
wells or pairs of different wells, and chains of pairs of wells arranged in
either a Fibonacci quasi-periodic sequence or a random sequence. The
transmission coefficient of fermionic matter is evaluated in a T-matrix
scattering approach by describing each array through a tight-binding
Hamiltonian and by reducing it to an effective dimer by means of a
decimation/renormalization method. The results are discussed in comparison with
those pertaining to transport by Fermi-surface electrons coupled to an outgoing
lead and by an atomic Bose-Einstein condensate. Main attention is given to (i)
Bloch oscillations and their mapping into alternating-current flow through a
Josephson junction; (ii) interference patterns that arise on period doubling
and their analogy with beam splitting in optical interferometry; (iii)
localization by quasi-periodic disorder inside a Fibonacci-ordered structure of
double wells; and (iv) Anderson localization in a random structure of double
wells.Comment: 14 pages, 4 figure
Environment-Induced Decoherence and the Transition From Quantum to Classical
We study dynamics of quantum open systems, paying special attention to those
aspects of their evolution which are relevant to the transition from quantum to
classical. We begin with a discussion of the conditional dynamics of simple
systems. The resulting models are straightforward but suffice to illustrate
basic physical ideas behind quantum measurements and decoherence. To discuss
decoherence and environment-induced superselection einselection in a more
general setting, we sketch perturbative as well as exact derivations of several
master equations valid for various systems. Using these equations we study
einselection employing the general strategy of the predictability sieve.
Assumptions that are usually made in the discussion of decoherence are
critically reexamined along with the ``standard lore'' to which they lead.
Restoration of quantum-classical correspondence in systems that are classically
chaotic is discussed. The dynamical second law -it is shown- can be traced to
the same phenomena that allow for the restoration of the correspondence
principle in decohering chaotic systems (where it is otherwise lost on a very
short time-scale). Quantum error correction is discussed as an example of an
anti-decoherence strategy. Implications of decoherence and einselection for the
interpretation of quantum theory are briefly pointed out.Comment: 80 pages, 7 figures included, Lectures given by both authors at the
72nd Les Houches Summer School on "Coherent Matter Waves", July-August 199
Thermal transport in one-dimensional spin gap systems
We study thermal transport in one dimensional spin systems both in the
presence and absence of impurities. In the absence of disorder, all these spin
systems display a temperature dependent Drude peak in the thermal conductivity.
In gapless systems, the low temperature Drude weight is proportional to
temperature and to the central charge which characterizes the conformal field
theory that describes the system at low energies. On the other hand, the low
temperature Drude weight of spin gap systems shows an activated behavior
modulated by a power law. For temperatures higher than the spin gap, one
recovers the linear T behavior akin to gapless systems. For temperatures larger
than the exchange coupling, the Drude weight decays as 1/T^2. We argue that
this behavior is a generic feature of quasi one dimensional spin gap systems
with a relativistic-like low energy dispersion. We also consider the effect of
a magnetic field on the Drude weight with emphasis on the
commensurate-incommensurate transition induced by it. We then study the effect
of nonmagnetic impurities on the thermal conductivity of the dimerized XY chain
and the spin-1/2 two leg ladder. Impurities destroy the Drude peak and the
thermal conductivity exhibits a purely activated behavior at low temperature,
with an activation gap renormalized by disorder. The relevance of these results
for experiments is briefly discussed.Comment: 13 pages, 6 eps figures, RevTeX
From prescriptive programming of solid-state devices to orchestrated self-organisation of informed matter
Achieving real-time response to complex, ambiguous, high-bandwidth data is impractical with conventional programming. Only the narrow class of compressible input-output maps can be specified with feasibly sized programs. Present computing concepts enforce formalisms that are arbitrary from the perspective of the physics underlying their implementation. Efficient physical realizations are embarrassed by the need to implement the rigidly specified instructions requisite for programmable systems. The conventional paradigm of erecting strong constraints and potential barriers that narrowly prescribe structure and precisely control system state needs to be complemented with a new approach that relinquishes detailed control and reckons with autonomous building blocks. Brittle prescriptive control will need to be replaced with resilient self-organisation to approach the robustness and efficiency afforded by natural systems. Structure-function self-consistency will be key to the spontaneous generation of functional architectures that can harness novel molecular and nano materials in an effective way for increased computational power
Chemical detection of sex and condition in the crayfish Orconectes virilis
Individual crayfish ( Orconectes virilis ) were tested for responses to water containing conspecific individuals of several sex-status categories. Isolated males did not react to “self” water but did show aggressive postures while isolated, nonself male water was introduced. Males' responses to female water was different from responses to male water. Water from aggressing males elicited fewer agonistic postures and more “neutral” postures. Females showed little difference in response to waters from different categories of conspecifics.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/44870/1/10886_2004_Article_BF00988201.pd