Nonidentical Coupling-based N-atom W Entanglement
2011-01-15ZHANGYingqiao
ZHANG Ying-qiao
(Department of Physics,College of Science,Yanbian University,Yanji 133002,China)
Nonidentical Coupling-based N-atom W Entanglement
ZHANG Ying-qiao
(Department of Physics,College of Science,Yanbian University,Yanji 133002,China)
Based on the nonidentical coupling of N atoms with a single-mode cavity,a scheme for generation of an N-atom W state is proposed in cavity QED.Under the condition of the large-detuned interactionΔ≫gj,the influence of cavity decay is negligible.Such multiple-qubit entanglement will have wide applications to largescale quantum communication and quantum computation.
N-atom W state;three-level atom;cavity QED
1 Introduction
Quantum entanglement is an important physical resource in quantum communication[1-3]and quantum computation.So far,a lot of schemes[4-11]have been proposed to generate entanglements based on various of physical systems both in theory and experiment.Most of these schemes are focused on generation of two-qubit or three-qubit entanglements.For example,Turchette et al[6]have produced the deterministic entangled states of two trapped ions.In this scheme,the two qubits are constituted by the internal states of two trapped ions in both the Bell-like singlet and triplet states.Reina et al[7]have prepared the maximally entangled Bell and Greenberger-Horne-Zeilinger states by optically driven the coupled quantum dots.An alternative scheme[8]to generate three-qubit W state via nonlinear optical state truncation using quantum scissors is proposed.Using atom interferometric techniques,the generation of Bell,NOON and W states of an electromagnetic field in high-Q cavities are also proposed[9].
However,multiple-qubit entanglements are often required to a large-scale quantum information processing.Therefore,the generation of multiple-qubit enanglements have attracted increasingly attentions.For example,an experimental demonstration of five-photon entanglement[10]was provided by generating a four-photon entangled state with two entangled photon pairs and then combining itwith a single-photon state.Based on rf SQUID,a simple scheme was presented to generate the N-qubit W states by adiabatic passage[11].
Based on the nonidentical coupling of the three three-level atoms with a resonant single-mode vacuum cavity field[12]and the large-detuning interaction of two identical two-level atoms with a singlemode cavity field[13]in cavity QED,as well as the combination of the coherent dynamics of the above two schemes[14],we propose a scheme for generation of an N-atom W state.Though it is a generalization of the previous three-atom W state scheme[15],it is universal to multiple-qubit case.
This paper is organized as follows:In Sec.Ⅱ we describe the coupling dynamics of N atoms interaction with a single-mode cavity.In Sec.Ⅲ we describe the generation of an N-atom W state.Conclusion is given in Sec.Ⅳ.
2 Coupling Dynamics of N Atoms Interaction with a Single-mode Cavity
We consider that N three-level atoms simultaneously interact with a single-mode cavity field.Each atom has one excited state|e〉and two ground states|g〉and|r〉.In our scheme,the state|r〉is not involved in the interaction with the cavity mode.In the rotating-wave approximation,the interaction Hamiltonian in the interaction picture can be written as(assumingħ=1)
where S+j=|e〉j〈g|,S-j=|g〉j〈e|(j=1,2,…,N).a†and a are the creation and annihilation operators of the single-mode cavity,respectively.gjis the coupling constant of the j th atom to the cavity mode.Δ=ω0-ωwithω0andωbeing the atomic transition frequency and cavity frequency,respectively.In the case ofΔ≫gj,there is no energy exchange between the atomic system and the cavity,the effective Hamiltonian is
whereλj=g2j/Δandλjk=gjgk/Δ.The first two terms denote the photon-number dependent Stark shifts,and the third term denotes the cavity mode-induced dipole coupling among the N atoms.Assuming that the coupling constant for the first atom with the cavity is g1and the coupling constants for the other atoms with the cavity are g =gj(j=2,3,…,N).If the cavity field is in the vacuum state initially,the effective Hamiltonian becomes
whereλ1=g21/Δand g2/Δ.
3 Generation of an N-atom W State
We assume that the N atoms are in the state〉,initially.The state evolution is
where
If the interaction time satisfy t= (2k+1)π/[(N-1)l+1]λ1(k is an integer)and the parameters that related to nonidentical atom-cavity coupling satisfywe obtain
Therefore we have generated an N-atom W state
4 Conclusion
In conclusion,we have proposed an universal scheme for generation of an N-atom W state based on the nonidentical coupling of N atoms with a single-mode cavity.Under the large-detuned interaction of the N atoms with the single-mode cavity(Δ≫gj),the influence of cavity decay is negligible.Such multiple-qubit entanglements are often required to a large-scale quantum communication and quantum computation.
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1004-4353(2011)03-0242-03
基于非全同耦合的N- 原子W纠缠态
张英俏
(延边大学理学院 物理系,吉林 延吉133002)
在腔QED中利用N个原子与一个单模腔的非全同耦合提出一个制备N原子W纠缠 态的方案.在大失谐相互作用Δ≫gj的条件下,腔衰减的影响可以忽略.此类多比特纠缠态可广泛应用于级联量子通讯和量子计算中.
N原子W态;三能级原子;腔QED
2011 -05 -14
张英俏(1978—),女,理学博士,讲师,研究方向为量子信息学.
0365;4250
A
