1) quantum phase
量子位相
1.
This work may be helpful for deeper understanding of physical origin and the meaning of quantum phase.
使用文献中给出的计算量子位相统计性质的方法计算了m取不同值时各领头相干态|α,m>的量子位相统计性质,揭示出了m和场强|α|这两个因素是怎样影响|α,m>的量子位相统计性质的,发现领头项相干态|α,m>在场强|α|2最接近m值时有最好的位相统计性质,从而加深了我们对相干态量子位相的性质和物理本质的理解。
2) quantum phase
量子相位
1.
Also show the quantum phase and coherence properties of the field are complementary in description of the optical quantum coherence.
同时 ,还证明了在描写光场的相干性方面 ,光场的量子相位与量子相干性是并协的 。
3) quantum phase gate
量子相位门
1.
A simple model for quantum computation is investigated and the criterion for 3-qubit quantum phase gates with maximal entanglement capacity is obtained using the criterion for 3-qubit maximal entangled states.
研究了3-qubit量子纯态性质与其单体约化密度矩阵之间的关系,给出判断3-qubit最大纠缠纯态和直积态的一种简便判据,并利用此判据研究了一种简单的量子计算模型,推导出该模型下3-qubit量子相位门的纠缠能力。
4) geometric phase shift
量子位相门
1.
We present a proposal for implementing two-qubit quantum phase gates through an unconventional geometric phase shift with 4-level systems in a cavity.
我们提出在腔中的四能级系统中,通过非寻常几何相移,实现2比特量子位相门。
5) quantum state phase
量子态位相
1.
By applying the invariant theory, this paper derives the quantum state phase of haromonic oscillator and its conclusion satisfies the gauge invariant naturaly.
本文应用了不变量理论求解谐振子系统的量子态位相,结果自然地满足规范不变性的要求。
6) conditional quantum phase gate
条件量子相位门
1.
One of the simplest scheme of two-qubit conditional quantum phase gate(CQPG)via a single-mode cavity and a single-Λtype three-level atom have been proposed.
利用单模场和一个Λ-型三能级原子实现二量子比特的条件量子相位门(CQPG),量子信息编码在单模场的FOCK态和及Λ-型三能级原子的2个亚稳态和上。
2.
Sleator et al have proved that any quantum unitary operation canbe decomposed into a serious of single qubit rotational operation and control-not(CNOT)gate operation; while a CNOT gate operation can also be decomposed into the operationof a single qubit rotations and a conditional quantum phase gate operation.
Sleator等人证明:任何幺正量子操作都可分解为一系列的单比特的旋转操作和控制非(CNOT)门的操作,而CNOT门的操作又可分解为单比特的旋转操作和条件量子相位门的操作。
补充资料:单量子阱(见量子阱)
单量子阱(见量子阱)
single quantum well
单且子阱sillgle quantum well见量子阱。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条