184 research outputs found
Observer dependent entanglement
Understanding the observer-dependent nature of quantum entanglement has been
a central question in relativistic quantum information. In this paper we will
review key results on relativistic entanglement in flat and curved spacetime
and discuss recent work which shows that motion and gravity have observable
effects on entanglement between localized systems.Comment: Ivette Fuentes previously published as Ivette Fuentes-Guridi and
Ivette Fuentes-Schulle
A geometric view of quantum cellular automata
Nielsen, et al. [1, 2] proposed a view of quantum computation where
determining optimal algorithms is equivalent to extremizing a geodesic length
or cost functional. This view of optimization is highly suggestive of an action
principle of the space of N-qubits interacting via local operations. The cost
or action functional is given by the cost of evolution operators on local qubit
operations leading to causal dynamics, as in Blute et. al. [3] Here we propose
a view of information geometry for quantum algorithms where the inherent causal
structure determines topology and information distances [4, 5] set the local
geometry. This naturally leads to geometric characterization of hypersurfaces
in a quantum cellular automaton. While in standard quantum circuit
representations the connections between individual qubits, i.e. the topology,
for hypersurfaces will be dynamic, quantum cellular automata have readily
identifiable static hypersurface topologies determined via the quantum update
rules. We demonstrate construction of quantum cellular automata geometry and
discuss the utility of this approach for tracking entanglement and algorithm
optimization.Comment: 13 pages, 6 figures. Conference Proceedings at SPIE Defense, Security
and Sensing, Baltimore, MD 201
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