Ning Wang, Jia-Min Kang, Wen-Long Lu, Shao-Min Wang, You-Jia Wang, Hai-Ou Li, Gang Cao, Bao-Chuan Wang, Guo-Ping Guo
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Scaling up quantum dots to two-dimensional (2D) arrays is a crucial step for
advancing semiconductor quantum computation. However, maintaining excellent
tunability of quantum dot parameters, including both nearest-neighbor and
next-nearest-neighbor couplings, during 2D scaling is challenging, particularly
for silicon quantum dots due to their relatively small size. Here, we present a
highly controllable and interconnected 2D quantum dot array in planar silicon,
demonstrating independent control over electron fillings and the tunnel
couplings of nearest-neighbor dots. More importantly, we also demonstrate the
wide tuning of tunnel couplings between next-nearest-neighbor dots,which plays
a crucial role in 2D quantum dot arrays. This excellent tunability enables us
to alter the coupling configuration of the array as needed. These results open
up the possibility of utilizing silicon quantum dot arrays as versatile
platforms for quantum computing and quantum simulation.