Wideband coherent microwave conversion via magnon nonlinearity in a hybrid quantum system

Jiahao Wu, Jiacheng Liu, Zheyu Ren, Man Yin Leung, Wai Kuen Leung, Kin On Ho, Xiangrong Wang, Qiming Shao, Sen Yang
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Abstract

Frequency conversion is a widely realized physical process in nonlinear systems of optics and electronics. As an emerging nonlinear platform, spintronic devices have the potential to achieve stronger frequency conversion. Here, we demonstrated a microwave frequency conversion method in a hybrid quantum system, integrating nitrogen-vacancy centers in diamond with magnetic thin film CoFeB. We achieve a conversion bandwidth ranging from 0.1 to 12 GHz, presenting an up to 25th order frequency conversion and further display the application of this method for frequency detection and qubits coherent control. Distinct from traditional frequency conversion techniques based on nonlinear electric response, our approach employs nonlinear magnetic response in spintronic devices. The nonlinearity, originating from the symmetry breaking such as domain walls in magnetic films, presents that our method can be adapted to hybrid systems of other spintronic devices and spin qubits, expanding the application scope of spintronic devices and providing a promising on-chip platform for coupling quantum systems.

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通过混合量子系统中的磁子非线性实现宽带相干微波转换
频率转换是光学和电子学非线性系统中广泛实现的物理过程。作为一种新兴的非线性平台,自旋电子器件具有实现更强频率转换的潜力。在这里,我们展示了一种混合量子系统中的微波频率转换方法,它将金刚石中的氮空位中心与磁性薄膜 CoFeB 集成在一起。我们实现了 0.1 至 12 GHz 的转换带宽,呈现了高达 25 阶的频率转换,并进一步展示了这种方法在频率检测和量子比特相干控制方面的应用。与基于非线性电响应的传统频率转换技术不同,我们的方法采用了自旋电子器件中的非线性磁响应。这种非线性源于磁性薄膜中的畴壁等对称性破缺,表明我们的方法可适用于其他自旋电子器件和自旋量子比特的混合系统,从而扩大了自旋电子器件的应用范围,并为耦合量子系统提供了一个前景广阔的片上平台。
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