In other words, they've created a form of quantum memory.
换句话说,他们已经制造出了一种量子记忆体。
Quantum memory may topple Heisenberg's uncertainty principle.
量子存储器可能颠覆海森堡的不确定性原理。
Unlike a diamond itself, this quantum memory isn't forever.
钻石恒久远,量子存储却不是永恒的。
Now let's reset the quantum memory, and run Deutches algorithm.
现在让我们重置量子内存并运行deutsch算法。
Of course the ability to peek at quantum memory is only possible because QCL is a simulator.
当然,因为qcl是一个模拟器,所以只是有可能能窥到量子内存。
Awschalom's diamond quantum memory could also be useful for building large quantum networks.
Awschalom的钻石量子存储也可用于建立大型量子网络。
Unlike a diamond itself, this quantum memory isn't forever. But it lasts for a very long time by quantum standards.
量子记忆并非像钻石一样长久,但是它会以量子的规格存在很长的一段时间。
In theory, there should be a measurement of the quantum memory that would yield the same result as the measurement done on the particle.
理论而言,通过测量量子存储器应该会产生和实际测量粒子相同的结果。
A quantum memory may be all scientists need to beat the limit of Heisenberg's uncertainty principle, according to a paper published in Nature Physics.
根据一篇刊登在自然物理上的文章报道,量子存储器将会成为所有企图击溃海森堡不确定原理的科学家的必备品。
Once they were entangled and separated, an observer would make a measurement of one of the particle's properties, and then tell the keeper of the quantum memory which variable they measured.
只要他们一缠绕或一分离,一个观察器将对粒子的其中一项属性进行测量,并将测量的结果反馈给量子存储器的管理器。
The computers of tomorrow could be quantum not classical, using the quantum world's strange properties to vastly increase memory and speed up information processing.
在未来世界,量子计算机可能会取代当代的电脑,借助于量子世界中的诸多奇性,未来计算机的容量将急剧膨胀,其信息处理的速度也会突飞猛进。
Researchers at the University of California, Santa Barbara, have become the first to combine a quantum processor with memory that can be used to store instructions and data.
加利福尼亚大学的研究人员SantaBarbara成为了第一个将量子处理器和存储器组合起来的人,这使(量子计算机)具有了储存指令和数据的能力。
The only quantum computing system available to buy—priced at $10 million—lacks memory and works like a pre-von Neumann computer.
现在能买到的量子计算系统——标价1000万美元——缺乏存储功能,它的工作类似于前诺依曼计算机。
It is shown that the two states('0' and '1') of single-electron ring memory, which has a cyclic array of quantum dots, can be implemented by input voltage controlling the charges on the islands.
研究表明,单电子环形存储器单元电路利用量子点环状电路结构形式,由外接输入电压控制各岛上的电荷,能够得到存储器的“0”和“1”状态。
Quantum search algorithm has the primary characteristics of high par all el searching, unstructured searching, and gigantic memory.
量子查找算法的主要特点是查找的高度并行性、非结构化查找和巨大的信息存储容量。
Molecular-based magnetic materials can be used as the magnetic quantum device memory or building blocks.
分子基磁性材料可以用作量子设备的磁性记忆或构建模块。
Traditionally, the quantum decoherence process is mathematically solved by using Markov approximation. That is, the environment has no memory effect on the system.
传统的刻画量子退相干的方法都是采取了马尔科夫近似,即认为环境对系统不存在记忆效应。
One of the main difficulties of quantum computation is that decoherence destroys the information in a quantum computer memory cell.
量子计算机存储单元的相干脱散,破坏量子态中的信息,是量子计算机难以实现的主要原因之一。
The application prospects of magnetic nanowires for magnetic recording, giant magnetoresistance, quantum disk and magnetic memory were discussed.
阐述了一维磁纳米线在磁记录、巨磁电阻、量子磁盘及高密度存储等领域的应用前景。
More preferably, the device structure contains a memory cell having three quantum Wells that can be arranged and constructed to define two different memory states.
更优选地,该器件结构包含存储单元,该存储单元具有三个量子阱,该三个量子阱被设置和构造成限定两种不同的存储状态。
The charge storage characteristic of Ge/Si double-layer quantum-dots floating-gate nano-memory was investigated.
设计了一种新型的存储器结构单元———锗/硅双层量子点阵列浮栅结构纳米存储器。
The charge storage characteristic of Ge/Si double-layer quantum-dots floating-gate nano-memory was investigated.
设计了一种新型的存储器结构单元———锗/硅双层量子点阵列浮栅结构纳米存储器。
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