Your search keyword '"Sun, Daxiong"' showing total 2 results

1. A C-Band Cryogenic GaAs MMIC Low-Noise Amplifier for Quantum Applications

Author

Guo, Zechen, Sun, Daxiong, Huang, Peisheng, Sun, Xuandong, Yuan, Yuefeng, Zhang, Jiawei, Huang, Wenhui, Liang, Yongqi, Qiu, Jiawei, Zhang, Jiajian, Chu, Ji, Guo, Weijie, Jiang, Ji, Niu, Jingjing, Ren, Wenhui, Tao, Ziyu, Linpeng, Xiayu, Zhong, Youpeng, and Yu, Dapeng

Subjects

Quantum Physics

Abstract

Large-scale superconducting quantum computers require massive numbers of high-performance cryogenic low-noise amplifiers (cryo-LNA) for qubit readout. Here we present a C-Band monolithic microwave integrated circuit (MMIC) cryo-LNA for this purpose. This cryo-LNA is based on 150 nm GaAs pseudomorphic high electron mobility transistor (pHEMT) process and implemented with a three-stage cascaded architecture, where the first stage adopts careful impedance match to optimize the noise and return loss. The integration of negative feedback loops adopted in the second and third-stage enhances the overall stability. Moreover, the pHEMT-self bias and current multiplexing circuitry structure facilitate the reduction of power consumption and require only single bias line. Operating at an ambient temperature of 3.6 K and consuming 15 mW, the cryo-LNA demonstrates good performance in the C-band, reaching a 5 K equivalent noise temperature and an average gain of 40 dB. We further benchmark this cryo-LNA with superconducting qubits, achieving an average single-shot dispersive readout fidelity of 98.3% without assistance from a quantum-limited parametric amplifier. The development of GaAs cryo-LNA diversifies technical support necessary for large-scale quantum applications.

Published

2024

2. M2CS: A Microwave Measurement and Control System for Large-scale Superconducting Quantum Processors

Author

Zhang, Jiawei, Sun, Xuandong, Guo, Zechen, Yuan, Yuefeng, Zhang, Yubin, Chu, Ji, Huang, Wenhui, Liang, Yongqi, Qiu, Jiawei, Sun, Daxiong, Tao, Ziyu, Zhang, Jiajian, Guo, Weijie, Jiang, Ji, Linpeng, Xiayu, Liu, Yang, Ren, Wenhui, Niu, Jingjing, Zhong, Youpeng, and Yu, Dapeng

Subjects

Quantum Physics

Abstract

As superconducting quantum computing continues to advance at an unprecedented pace, there is a compelling demand for the innovation of specialized electronic instruments that act as crucial conduits between quantum processors and host computers. Here, we introduce a Microwave Measurement and Control System (M2CS) dedicated for large-scale superconducting quantum processors. M2CS features a compact modular design that balances overall performance, scalability, and flexibility. Electronic tests of M2CS show key metrics comparable to commercial instruments. Benchmark tests on transmon superconducting qubits further show qubit coherence and gate fidelities comparable to state-of-the-art results, confirming M2CS's capability to meet the stringent requirements of quantum experiments run on intermediate-scale quantum processors. The system's compact and scalable design offers significant room for further enhancements that could accommodate the measurement and control requirements of over 1000 qubits, and can also be adopted to other quantum computing platforms such as trapped ions and silicon quantum dots. The M2CS architecture may also be applied to wider range of scenarios, such as microwave kinetic inductance detectors, as well as phased array radar systems.

Published

2024