在量子处理单元上净化量子比特的量子热力学方法

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY

AVS quantum science Pub Date : 2022-01-31 DOI:10.1116/5.0091121

Andrea Solfanelli, Alessandro Santini, M. Campisi

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引用次数: 10

摘要

我们报告了一种量子热力学方法，可以在配备(几乎)相同量子比特的量子处理单元(QPU)上纯化量子比特。我们的出发点是一个三量子位设计，它模拟了众所周知的两个量子位交换引擎。与标准冰箱类似，这种方法将允许我们以加热另外两个量子位为代价冷却一个量子位。其最小的修改导致更实用的三个量子位设计，允许增强制冷任务，例如以降低其他两个量子位的纯度为代价增加一个量子位的纯度。该方法基于合理设计的量子电路的应用，因此可以在任何门型量子计算机上运行。我们在一个公开可用的超导量子比特QPU上实现了它，并观察到净化能力低至200 mK。我们确定栅极噪声是量子计算实际应用的主要障碍。

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Quantum thermodynamic methods to purify a qubit on a quantum processing unit

We report on a quantum thermodynamic method to purify a qubit on a quantum processing unit (QPU) equipped with (nearly) identical qubits. Our starting point is a three qubit design that emulates the well-known two qubit swap engine. Similar to standard fridges, the method would allow us to cool down a qubit at the expense of heating two other qubits. A minimal modification thereof leads to a more practical three qubit design that allows for enhanced refrigeration tasks, such as increasing the purity of one qubit at the expense of decreasing the purity of the other two. The method is based on the application of properly designed quantum circuits and can therefore be run on any gate model quantum computer. We implement it on a publicly available superconducting qubit based QPU and observe a purification capability down to 200 mK. We identify gate noise as the main obstacle toward practical application for quantum computing.

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来源期刊

AVS quantum science

CiteScore

9.90

自引率

0.00%

发文量