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1.
We propose a scheme for the preparation of one-dimensional and
two-dimensional cluster states by using hot trapped ions. The scheme
is based on the interaction between two ions and bichromatic
radiation. The vibrational mode in our protocol is only virtually
excited so that the system is insensitive to the thermal field. In
addition, we only use two levels of ions as qubits and the
successful probability may achieve 100%. 相似文献
2.
A general scheme of generating N00N states of virtually-excited 2N atoms is proposed. The two cavities are fibre-connected with N atoms in each cavity. Although we focus on the case of N=2, the system can be extended to a few atoms with N>2. It is found that all 2N atoms can be entangled in the form of N00N states if the atoms in the first cavity are initially in the excited states and atoms in the second cavity are all in the ground states. The feasibility of the scheme is carefully discussed, it shows that the N00N state with a few atoms can be generated with good fidelity and the scheme is feasible in experiment. 相似文献
3.
Scheme for the implementation of 1→3
optimal phase-covariant quantum cloning in ion-trap systems 下载免费PDF全文
This paper proposes a scheme for the implementation of 1→ 3 optimal phase-covariant quantum cloning with trapped ions. In the present protocol, the required time for the whole procedure is short due to the resonant interaction, which is important in view of decoherence. Furthermore, the scheme is feasible based on current technologies. 相似文献
4.
Implementing remote controlled-NOT gates and entanglement swapping via geometric phase gates in ion-trap systems 下载免费PDF全文
We propose a scheme for the implementation of remote controlled-NOT
gates and entanglement swapping via geometric phase gates in
ion-trap systems. The proposed scheme uses the two ground states of
the $\Lambda$-type ions as memory instead of the vibrational mode.
And the system is robust against the spontaneous radiation and the
dephasing. 相似文献
5.
A general scheme of generating NOON states of virtually-excited 2N atoms is proposed. The two cavities are fibre-connected with N atoms in each cavity. Although we focus on the case of N = 2, the system can be extended to a few atoms with N 〉2. It is found that all 2N atoms can be entangled in the form of NOON states if the atoms in the first cavity are initially in the excited states and atoms in the second cavity are all in the ground states. The feasibility of the scheme is carefully discussed, it shows that the NOON state with a few atoms can be generated with good fidelity and the scheme is feasible in experiment. 相似文献
6.
7.
We propose a scheme to implement the Deutsch-Jozsa algorithm by using Schroedinger cat states in cavity quantum electron-dynamics (QED). The scheme is based on the Raman interaction of a degenerate three-level A-type atom with a coherent state in a cavity. By using Schroedinger cat states, the atomic spontaneous emission can be minimized and the Hadamard transformation in our scheme is not needed. 相似文献
8.
Entanglement swapping without joint measurement via a Λ-type atom interacting with bimodal cavity field 下载免费PDF全文
This paper proposes a scheme for realizing entanglement swapping in cavity QED. The scheme is based on the resonant interaction of a two-mode cavity field with a ∧-type three-level atom. In contrast with the previously proposed schemes, the present scheme is ascendant, since the fidelity is 1.0 and the joint measurement isn't needed. And the scheme is experimentally feasible based on the current cavity QED technique. 相似文献
9.
Remote preparation of a Greenberger--Horne--Zeilinger state via a two-particle entangled state 总被引:2,自引:0,他引:2 下载免费PDF全文
We present two schemes for realizing the remote preparation of a
Greenberger--Horne--Zeilinger (GHZ) state. The first scheme is to remotely
prepare a general N-particle GHZ state with two steps. One is to prepare a qubit
state by using finite classical bits from sender to receiver via a
two-particle entangled state, and the other is that the receiver introduces
N - 1 additional particles and performs N - 1 controlled-not (C-Not)
operations. The second scheme is to remotely prepare an N-atom
GHZ state via
a two-atom entangled state in cavity quantum electrodynamics (QED). The two
schemes require only a two-particle entangled state used as a quantum
channel, so we reduce the requirement for entanglement. 相似文献
10.
This paper describes the interaction between two spatial modes of the optical fields with a single atom trapped inner coupled double-cavity. Theoretical derivation and numerical simulation with the experimental available parameters show that photon-photon switching and π phase shift of single photons may be achieved with current experimental technology. As the probe and control fields are in different spatial modes, the system is superior for implementing cavity QED-based photonic quantum networks. 相似文献