介绍了量子态叠加原理和量子不可克隆定理。
Tthe principle of quantum superposition and quantum non-cloning theorem have been introduced.
目的研究四态叠加多模泛函叠加态光场的高次振幅压缩特性。
Aim To study the higher-power amplitude squeezing properties of the four-state superposition multimode functional superposition state light field.
本文利用态叠加原理移去压缩光场态中的真空态,研究了真空态与压缩的关系。
Using the principle of state superposition, we study the relationship between shiping and vacuum state by means of removing vacuum state from squeezed states.
利用态叠加原理将两个不同的自旋相干态叠加,得到的薛定谔猫态具有相干的非经典特性。
The superpositions that built with two different spin coherent states exhibit nonclassical properties, and the antibunching effect is one of the nonclassical effects of this kind of states.
讨论了量子力学里态叠加原理的物理含义,并评论了国内外流行的几种教材中的一些不同讲法。
The physical meaning of the superposition principle in quantum mechanics is discussed. Various statements of this principle in a few textbooks are commented.
本文对态叠加原理的物理实质进行了讨论。又重点地介绍了态叠加原理在结构化学上三个方面的应用。
The physical essence of principle of superposition is discussed, and its applications in structural chemistry are presented in this paper.
在实现信息处理的过程中,量子态叠加原理、量子纠缠和量子退相干等基本原理和基本概念应当充分考虑。
Some fundamental principles, such as the principle of quantum state superposition, quantum entangled state and quantum decoherence etc.
目的研究任意多态叠加多模叠加态光场的广义非线性等幂次差压缩特性,从理论上导出该光场呈现高次差压缩的条件。
Aim To find out the squeezing conditions theoretically and the properties of equal-power nonlinear difference squeezing in multimode radiation field with any amount of states superposing studied.
叠加态正是像量子计算机这样的设备的基础。
Superposition is exactly what underlies the power of things like quantum computers.
据说,薛定谔构造这个实验是想嘲讽量子物理的新兴理论,但从那以后,物理学家们发现了许多量子世界的叠加态案例。
Schrodinger's is said to have devised the experiment to ridicule the emerging theories of quantum physics; but since then physicists have found many examples of superposition in the quantum world.
这后来被称为叠加态。
然后我们证明这个叠加态是可以被调控的,即电子可以在制造叠加态的一个精确的时间之后辐射出光子。
We then demonstrated that the superposition state could be controlled so that the electrons emit a burst of light at a well-defined time after the superposition was created.
量子世界的一个小小的令人惊奇的是一种被称作叠加态的状态。在这种状态下,一个粒子可以同时占据着两种状态。
One of the marvelous little wrinkles of the quantum world is a condition known as superposition, in which a particle can occupy two states at the same time.
物理学家们已经成功使光量子、电子和原子,甚至整个分子达到叠加态并进行相关测量。
Physicists have already put photons, electrons, atoms and even entire molecules into such a state and measured the outcome.
在我们的案例中,我们将宏观光束置于量子叠加态,这种状态极脆弱易被破坏,而后将光束从一处传送至另一处。
So in our case what we've done is take a macroscopic beam of light and put it into a quantum superposition, which is extremely fragile, and teleported that from one place to another.
这种“回波”脉冲的特性可以告诉我们系统处于何种叠加态上。
The characteristics of this "echo" pulse tell us about the superposition we have made. Credit: ucl.
比如人,人能同时在两个地方,处于一种叠加的状态,这种状态,潘建伟将它解释为量子叠加态。
For example, people can at the same time in two places, in a superposition of the state, this state, Pan Jianwei will be interpreted as quantum superposition state.
作者利用热场动力学方法(TFD),提出了具有有限温度的热叠加态。
By making use of thermo field dynamics (TFD), we construct the thermal superposition states in finite temperature.
提出用单个量子位的叠加态进行量子编码。
The quantum encoding is put forward by using superposition state of single qubit.
应用统计诠释和叠加原理的推论,任意波函数可按它们的共同本征态展开。
Applying the corollary of the statistic definition and overlap principle, arbitrary wave function may be expanded in terms of its completeness eigenstates.
文章作者解释了如何通过量子隧穿实现宏观量子相干(即薛定谔猫态的相干叠加)和量子态位相干涉。
We explain how to realize macroscopic quantum coherence, namely the superposition of Schrdinger cat states and quantum phase interference by means of quantum tunneling.
本文讨论了这种位移叠加态的量子统计性质及其与位移算符的关系。
We discuss the quantum statistical properties of these states and relate these properties to the displacement operator.
分别对几种叠加态——真空态与相干态的叠加态、奇相干态、偶相干态以及奇、偶相干态分别与真空态的叠加态的压缩性质进行讨论。
A discussion is made about the squeezing properties of several superpositions, the vacuum state with coherent state or odd and even coherent state.
你们可以看到两个轨道,靠在一起相长叠加,这就是为什么中间的电子态密度增加了。
The reason that there is increased electron density here is you can see that these two orbitals come together and constructively interfere.
你们可以看到两个轨道,靠在一起相长叠加,这就是为什么中间的电子态密度增加了。
The reason that there is increased electron density here is you can see that these two orbitals come together and constructively interfere.
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