32,277 research outputs found
High threshold distributed quantum computing with three-qubit nodes
In the distributed quantum computing paradigm, well-controlled few-qubit
`nodes' are networked together by connections which are relatively noisy and
failure prone. A practical scheme must offer high tolerance to errors while
requiring only simple (i.e. few-qubit) nodes. Here we show that relatively
modest, three-qubit nodes can support advanced purification techniques and so
offer robust scalability: the infidelity in the entanglement channel may be
permitted to approach 10% if the infidelity in local operations is of order
0.1%. Our tolerance of network noise is therefore a order of magnitude beyond
prior schemes, and our architecture remains robust even in the presence of
considerable decoherence rates (memory errors). We compare the performance with
that of schemes involving nodes of lower and higher complexity. Ion traps, and
NV- centres in diamond, are two highly relevant emerging technologies.Comment: 5 figures, 12 pages in single column format. Revision has more
detailed comparison with prior scheme
Simple Pulses for Universal Quantum Computation with a Heisenberg ABAB Chain
Recently Levy has shown that quantum computation can be performed using an
ABAB.. chain of spin-1/2 systems with nearest-neighbor Heisenberg interactions.
Levy notes that all necessary elementary computational `gates' can be achieved
by using spin-resonance techniques involving modulating the spin-spin
interaction strength at high frequency. Here we note that, as an alternative to
that approach, it is possible to perform the elementary gates with simple,
non-oscillatory pulses.Comment: 3 pages including 2 fig
Multi-Qubit Gates in Arrays Coupled by 'Always On' Interactions
Recently there has been interest in the idea of quantum computing without
control of the physical interactions between component qubits. This is highly
appealing since the 'switching' of such interactions is a principal difficulty
in creating real devices. It has been established that one can employ 'always
on' interactions in a one-dimensional Heisenberg chain, provided that one can
tune the Zeeman energies of the individual (pseudo-)spins. It is important to
generalize this scheme to higher dimensional networks, since a real device
would probably be of that kind. Such generalisations have been proposed, but
only at the severe cost that the efficiency of qubit storage must *fall*. Here
we propose the use of multi-qubit gates within such higher-dimensional arrays,
finding a novel three-qubit gate that can in fact increase the efficiency
beyond the linear model. Thus we are able to propose higher dimensional
networks that can constitute a better embodiment of the 'always on' concept - a
substantial step toward bringing this novel concept to full fruition.Comment: 20 pages in preprint format, inc. 3 figures. This version has fixed
typos and printer-friendly figures, and is to appear in NJ
A Map of the Integrated Sachs-Wolfe Signal from Luminous Red Galaxies
We construct a map of the time derivative of the gravitational potential
traced by SDSS Luminous Red Galaxies. The potential decays on large scales due
to cosmic acceleration, leaving an imprint on cosmic microwave background (CMB)
radiation through the integrated Sachs-Wolfe (ISW) effect. With a template fit,
we directly measure this signature on the CMB at a 2-sigma confidence level.
The measurement is consistent with the cross-correlation statistic,
strengthening the claim that dark energy is indeed the cause of the
correlation. This new approach potentially simplifies the cosmological
interpretation. Our constructed linear ISW map shows no evidence for
degree-scale cold and hot spots associated with supervoid and supercluster
structures. This suggests that the linear ISW effect in a concordance
Lambda-CDM cosmology is insufficient to explain the strong CMB imprints from
these structures that we previously reported.Comment: 9 pages, 12 figures, accepted to ApJ. Updated discussion about
redshift cut
A comparative study of some models of incoherence at the mesoscopic scale
The pre-existing literature on phenomena at the mesoscopic scale is concerned
among other things with phase coherent transport. Phase coherent transport
dominates at very low temperatures. With increase in temperature, as the system
size becomes comparable to the inelastic mean free path phase incoherence sets
in. This incoherence further leads to dephasing, and as a consequence purely
quantum effects in electron transport give way to classical macroscopic
behavior. In this work we consider two distinct phenomenological models of
incoherent transport, the Coherent Absorption and Wave Attenuation models. We
reveal some physical problems in the Coherent Absorption model as opposed to
the Wave Attenuation model. We also compare our proposed model with experiments
in case of the much studied peak to valley ratios in resonant tunneling diodes,
magneto-conductance oscillations and Fano resonances in case of Aharonov-Bohm
rings.Comment: 20 pages, 9 figure
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