2,232 research outputs found
Operational multipartite entanglement classes for symmetric photonic qubit states
We present experimental schemes that allow to study the entanglement classes
of all symmetric states in multiqubit photonic systems. In addition to
comparing the presented schemes in efficiency, we will highlight the relation
between the entanglement properties of symmetric Dicke states and a recently
proposed entanglement scheme for atoms. In analogy to the latter, we obtain a
one-to-one correspondence between well-defined sets of experimental parameters
and multiqubit entanglement classes inside the symmetric subspace of the
photonic system.Comment: 5 pages, 1 figur
Entangled-State Cycles of Atomic Collective-Spin States
We study quantum trajectories of collective atomic spin states of
effective two-level atoms driven with laser and cavity fields. We show that
interesting ``entangled-state cycles'' arise probabilistically when the (Raman)
transition rates between the two atomic levels are set equal. For odd (even)
, there are () possible cycles. During each cycle the
-qubit state switches, with each cavity photon emission, between the states
, where is a Dicke state in a rotated
collective basis. The quantum number (), which distinguishes the
particular cycle, is determined by the photon counting record and varies
randomly from one trajectory to the next. For even it is also possible,
under the same conditions, to prepare probabilistically (but in steady state)
the Dicke state , i.e., an -qubit state with excitations,
which is of particular interest in the context of multipartite entanglement.Comment: 10 pages, 9 figure
Realization of a Knill-Laflamme-Milburn C-NOT gate -a photonic quantum circuit combining effective optical nonlinearities
Quantum information science addresses how uniquely quantum mechanical
phenomena such as superposition and entanglement can enhance communication,
information processing and precision measurement. Photons are appealing for
their low noise, light-speed transmission and ease of manipulation using
conventional optical components. However, the lack of highly efficient optical
Kerr nonlinearities at single photon level was a major obstacle. In a
breakthrough, Knill, Laflamme and Milburn (KLM) showed that such an efficient
nonlinearity can be achieved using only linear optical elements, auxiliary
photons, and measurement. They proposed a heralded controlled-NOT (CNOT) gate
for scalable quantum computation using a photonic quantum circuit to combine
two such nonlinear elements. Here we experimentally demonstrate a KLM CNOT
gate. We developed a stable architecture to realize the required four-photon
network of nested multiple interferometers based on a displaced-Sagnac
interferometer and several partially polarizing beamsplitters. This result
confirms the first step in the KLM `recipe' for all-optical quantum
computation, and should be useful for on-demand entanglement generation and
purification. Optical quantum circuits combining giant optical nonlinearities
may find wide applications across telecommunications and sensing.Comment: 6pages, 3figure
Teleportation-based realization of an optical quantum two-qubit entangling gate
In recent years, there has been heightened interest in quantum teleportation,
which allows for the transfer of unknown quantum states over arbitrary
distances. Quantum teleportation not only serves as an essential ingredient in
long-distance quantum communication, but also provides enabling technologies
for practical quantum computation. Of particular interest is the scheme
proposed by Gottesman and Chuang [Nature \textbf{402}, 390 (1999)], showing
that quantum gates can be implemented by teleporting qubits with the help of
some special entangled states. Therefore, the construction of a quantum
computer can be simply based on some multi-particle entangled states, Bell
state measurements and single-qubit operations. The feasibility of this scheme
relaxes experimental constraints on realizing universal quantum computation.
Using two different methods we demonstrate the smallest non-trivial module in
such a scheme---a teleportation-based quantum entangling gate for two different
photonic qubits. One uses a high-fidelity six-photon interferometer to realize
controlled-NOT gates and the other uses four-photon hyper-entanglement to
realize controlled-Phase gates. The results clearly demonstrate the working
principles and the entangling capability of the gates. Our experiment
represents an important step towards the realization of practical quantum
computers and could lead to many further applications in linear optics quantum
information processing.Comment: 10 pages, 6 figure
Optically Levitating Dielectrics in the Quantum Regime: Theory and Protocols
We provide a general quantum theory to describe the coupling of light with
the motion of a dielectric object inside a high finesse optical cavity. In
particular, we derive the total Hamiltonian of the system as well as a master
equation describing the state of the center of mass mode of the dielectric and
the cavity field mode. In addition, a quantum theory of elasticity is used in
order to study the coupling of the center of mass motion with internal
vibrational excitations of the dielectric. This general theory is applied to
the recent proposal of using an optically levitating nanodielectric as a cavity
optomechanical system [Romero-Isart et al. NJP 12, 033015 (2010), Chang et al.
PNAS 107, 1005 (2010)]. On this basis, we also design a light-mechanics
interface to prepare non-Gaussian states of the mechanical motion, such as
quantum superpositions of Fock states. Finally, we introduce a direct
mechanical tomography scheme to probe these genuine quantum states by time of
flight experiments.Comment: 27 pages, revtex 2 columns, 8 figure
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