1. Quantum supremacy using a programmable superconducting processor
2. Demonstration of quantum volume 64 on a superconducting quantum computing system
3. Y. Wu
,
W.S. Bao
,
S. Cao
,
F. Chen
,
M.C. Chen
,
X. Chen
,
T.H. Chung
,
H. Deng
,
Y. Du
,
D. Fan
,
M. Gong
,
C. Guo
,
C. Guo
,
S. Guo
,
L. Han
,
L. Hong
,
H.L. Huang
,
Y.H. Huo
,
L. Li
,
N. Li
,
S. Li
,
Y. Li
,
F. Liang
,
C. Lin
,
J. Lin
,
H. Qian
,
D. Qiao
,
H. Rong
,
H. Su
,
L. Sun
,
L. Wang
,
S. Wang
,
D. Wu
,
Y. Xu
,
K. Yan
,
W. Yang
,
Y. Yang
,
Y. Ye
,
J. Yin
,
C. Ying
,
J. Yu
,
C. Zha
,
C. Zhang
,
H. Zhang
,
K. Zhang
,
Y. Zhang
,
H. Zhao
,
Y. Zhao
,
L. Zhou
,
Q. Zhu
,
C.Y. Lu
,
C.Z. Peng
,
X. Zhu
, and
J.W. Pan
, “
Strong quantum computational advantage using a superconducting quantum processor,” arXiv:2106.14734 (2021).
4. Evidence of a Nonequilibrium Distribution of Quasiparticles in the Microwave Response of a Superconducting Aluminum Resonator
5. Minimizing quasiparticle generation from stray infrared light in superconducting quantum circuits