213 research outputs found
Quantum dynamics of bio-molecular systems in noisy environments
We discuss three different aspects of the quantum dynamics of bio-molecular
systems and more generally complex networks in the presence of strongly coupled
environments. Firstly, we make a case for the systematic study of fundamental
structural elements underlying the quantum dynamics of these systems, identify
such elements and explore the resulting interplay of quantum dynamics and
environmental decoherence. Secondly, we critically examine some existing
approaches to the numerical description of system-environment interaction in
the non-perturbative regime and present a promising new method that can
overcome some limitations of existing methods. Thirdly, we present an approach
towards deciding and quantifying the non-classicality of the action of the
environment and the observed system-dynamics. We stress the relevance of these
tools for strengthening the interplay between theoretical and experimental
research in this field.Comment: Proceedings of the 22nd Solvay Conference in Chemistry on "Quantum
Effects in Chemistry and Biology
Coherence and Decoherence in Biological Systems: Principles of Noise Assisted Transport and the Origin of Long-lived Coherences
The quantum dynamics of transport networks in the presence of noisy
environments have recently received renewed attention with the discovery of
long-lived coherences in different photosynthetic complexes. This experimental
evidence has raised two fundamental questions: Firstly, what are the mechanisms
supporting long-lived coherences and secondly, how can we assess the possible
functional role that the interplay of noise and quantum coherence might play in
the seemingly optimal operation of biological systems under natural conditions?
Here we review recent results, illuminate them at the hand of two paradigmatic
systems, the Fenna-Matthew-Olson (FMO) complex and the light harvesting complex
LHII, and present new progress on both questions. In particular we introduce
the concept of the phonon antennae and discuss the possible microscopic origin
or long-lived electronic coherences.Comment: Paper delivered at the Royal Society Discussion Meeting
"Quantum-coherent energy transfer: implications for biology and new energy
technologies", 27 - 28 April 2011 at The Kavli Royal Society International
Centre, Buckinghamshire, UK. Accepted for publication in Philosophical
Transactions of the Royal Society
Classical simulatability, entanglement breaking, and quantum computation thresholds
We investigate the amount of noise required to turn a universal quantum gate
set into one that can be efficiently modelled classically. This question is
useful for providing upper bounds on fault tolerant thresholds, and for
understanding the nature of the quantum/classical computational transition. We
refine some previously known upper bounds using two different strategies. The
first one involves the introduction of bi-entangling operations, a class of
classically simulatable machines that can generate at most bipartite
entanglement. Using this class we show that it is possible to sharpen
previously obtained upper bounds in certain cases. As an example, we show that
under depolarizing noise on the controlled-not gate, the previously known upper
bound of 74% can be sharpened to around 67%. Another interesting consequence is
that measurement based schemes cannot work using only 2-qubit non-degenerate
projections. In the second strand of the work we utilize the Gottesman-Knill
theorem on the classically efficient simulation of Clifford group operations.
The bounds attained for the pi/8 gate using this approach can be as low as 15%
for general single gate noise, and 30% for dephasing noise.Comment: 12 pages, 3 figures. v2: small typos changed, no change to result
Controlled and combined remote implementations of partially unknown quantum operations of multiqubits using GHZ states
We propose and prove protocols of controlled and combined remote
implementations of partially unknown quantum operations belonging to the
restricted sets [An Min Wang: PRA, \textbf{74}, 032317(2006)] using GHZ states.
We detailedly describe the protocols in the cases of one qubit, respectively,
with one controller and with two senders. Then we extend the protocols to the
cases of multiqubits with many controllers and two senders. Because our
protocols have to demand the controller(s)'s startup and authorization or two
senders together working and cooperations, the controlled and combined remote
implementations of quantum operations definitely can enhance the security of
remote quantum information processing and potentially have more applications.
Moreover, our protocol with two senders is helpful to farthest arrive at the
power of remote implementations of quantum operations in theory since the
different senders perhaps have different operational resources and different
operational rights in practice.Comment: 26 pages, the submitted versio
Scheme for remote implementation of partially unknown quantum operation of two qubits in cavity QED
By constructing the recovery operations of the protocol of remote
implementation of partially unknown quantum operation of two qubits [An Min
Wang: PRA, \textbf{74}, 032317(2006)], we present a scheme to implement it in
cavity QED. Long-lived Rydberg atoms are used as qubits, and the interaction
between the atoms and the field of cavity is a nonresonant one. Finally, we
analyze the experimental feasibility of this scheme.Comment: 7 pages, 2 figure
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