129 research outputs found
Quantum state transfer and time-dependent disorder in Quantum Chains
One of the most basic tasks required for Quantum Information Technology is
the ability to connect different components of a Quantum Computer by quantum
wires that obey the superposition principle. Since superpositions can be very
sensitive to noise this turns out to be already quite difficult. Recently, it
was suggested to use chains of permanently coupled spin-1/2 particles (quantum
chains) for this purpose. They have the advantage that no external control
along the wire is required during the transport of information, which makes it
possible to isolate the wire from sources of noise. We first give an
introduction to basic quantum state transfer and review existing advanced
schemes by other authors. We then show a new result that demonstrates the
stability of the scheme [1] against disorder that is approximately constant
during one application of the channel, but time-dependent with respect to
multiple applications.Comment: 9 pages, 6 figures, submitted to the proceedings of the 382. WEH
workshop "transrel" March 2007; added reference to experimental realizatio
A Protocol For Cooling and Controlling Composite Systems by Local Interactions
We discuss an explicit protocol which allows one to externally cool and
control a composite system by operating on a small subset of it. The scheme
permits to transfer arbitrary and unknown quantum states from a memory on the
network ("upload access") as well as the inverse ("download access"). In
particular it yields a method for cooling the system.Comment: 8 pages, 5 figures: in "Quantum Information and Many Body Quantum
Systems", proceedings, M. Ericsson and S. Montangero (eds.), Pisa, Edizioni
della Normale, p. 17 (2008
Quantum State Transfer with Spin Chains
The thesis covers various aspects of quantum state transfer in permanently
coupled spin systems.Comment: PhD thesis, December 2006, University College London, 142 page
Improved transfer of quantum information using a local memory
We demonstrate that the quantum communication between two parties can be
significantly improved if the receiver is allowed to store the received signals
in a quantum memory before decoding them. In the limit of an infinite memory,
the transfer is perfect. We prove that this scheme allows the transfer of
arbitrary multipartite states along Heisenberg chains of spin-1/2 particles
with random coupling strengths.Comment: 4 pages, 1 figure; added references to homogenization and asymptotic
completenes
Mediated Homogenization
Homogenization protocols model the quantum mechanical evolution of a system
to a fixed state independently from its initial configuration by repeatedly
coupling it with a collection of identical ancillas. Here we analyze these
protocols within the formalism of "relaxing" channels providing an easy to
check sufficient condition for homogenization. In this context we describe
mediated homogenization schemes where a network of connected qudits relaxes to
a fixed state by only partially interacting with a bath. We also study
configurations which allow us to introduce entanglement among the elements of
the network. Finally we analyze the effect of having competitive configurations
with two different baths and we prove the convergence to dynamical equilibrium
for Heisenberg chains.Comment: 6 pages, 6 figure
Conclusive and arbitrarily perfect quantum state transfer using parallel spin chain channels
We suggest a protocol for perfect quantum communication through spin chain
channels. By combining a dual-rail encoding with measurements only at the
receiving end, we can get conclusively perfect state transfer, whose
probability of success can be made arbitrarily close to unity. As an example of
such an amplitude delaying channel, we show how two parallel Heisenberg spin
chains can be used as quantum wires. Perfect state transfer with a probability
of failure lower than P in a Heisenberg chain of N spin-1/2 particles can be
achieved in a timescale of the order of N^1.7|ln(P)|. We demonstrate that our
scheme is more robust to decoherence and non-optimal timing than any scheme
using single spin chains.Comment: 6 pages, 4 figures ; expanded version inluding discussion of
transmission tim
Controlling quantum state transfer in spin chain with the confined field
As a demonstration of the spectrum-parity matching condition (SPMC) for
quantum state transfer, we investigate the propagation of single-magnon state
in the Heisenberg chain in the confined external tangent magnetic field
analytically and numerically. It shows that the initial Gaussian wave packet
can be retrieved at the counterpart location near-perfectly over a longer
distance if the dispersion relation of the system meets the SPMC approximately.Comment: 9 pages, 8 figure
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