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Entanglement diversion and quantum teleportation of entangled coherent states 总被引:2,自引:0,他引:2 下载免费PDF全文
The proposals on entanglement diversion and quantum teleportation of
entangled coherent states are presented.In these proposals, the entanglement between two coherent states, $|\alpha\rangle$ and $|-\alpha\rangle$, with the same amplitude but a phase difference
of $\pi$ is utilized as a quantum channel. The processes of the entanglement diversion and the teleportation are achieved by using the 50/50 symmetric beam splitters, the phase shifters and the photodetectors with the help of classical information. 相似文献
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We propose a method to probabilistically implement a nonlocal operation, $%
\exp {[}\i\xi U_{A}U_{B}{]}$, between two distant qutrits $A$ and $B$, where $%
\xi \in [0,2\pi ]$ and $U_{A}$, $U_{B}$ are local unitary and Hermitian
operations for qutrits $A$ and $B$ respectively. The consumptions of
resource for one performance of the method are a single non-maximally
entangled qutrit state and 1-trit classical communication. For a given $\xi $%
, the successful probability of the method depends on the forms of both
entanglement resource and Bob's partial-measurement basis. We systematically
discuss the optimal successful probabilities and their corresponding
conditions for three cases: adjustable entanglement resource, adjustable
partial-measurement basis, adjustable entanglement resource and
partial-measurement basis. It is straightforward to generalize the method
for producing nonlocal unitary operations between any two $N$-level systems. 相似文献
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过去的实验表明,掺杂物的类型对高压烧结多晶体金刚石的耐热性有显著的影响。但同种类型掺杂物含量的影响规律还不清楚,因此我们进行了钛、硅掺杂量对高压烧结多晶体金刚石耐热性影响的研究. 一、实验技术与方法 实验用的设备、压力、温度和样品装配等与文献[1]中一样. 本实验中钛、硅掺杂量分别以金刚石原料为100时的重量计算,钛的重量为0,5,9,15和硅的重量为0,3,9,15以及它们的组合. 二、实验结果和样品分析 实验结果列入表1中. 从表1中数据可见:(1)除了个别情况外(例如钛0硅15),都可以找到较佳的烧结工艺,使样品具有较高的磨耗比,但成团… 相似文献
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一、前言 目前,人造大颗粒金刚石的具体方法很多,其中以静态高压下用细粒金刚石和适量的某些非金刚石物质——掺杂物(通称为“粘结剂”)作原料烧结成大颗粒多晶体(通称为“聚晶体”)金刚石为较有成效的方法。这种方法在七十年代受到人们极大的关注。 由于控制这种烧结过程的因素很多,例如压力、温度、时间和掺杂物,还有原料的粒度、形状和表面状态,以及烧结时的气氛和气压等等,致使对这种金刚石的形成机制难以较深入的研究,这有碍于探索具有较高耐磨、耐热等综合性能的多晶体金刚石的有效途径。 相似文献
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