Litcius/Paper detail

Super-compact universal quantum logic gates with inverse-designed elements

Lu He, Dongning Liu, Jing‐Xing Gao, Weixuan Zhang, Weixuan Zhang, Huizhen Zhang, Xue Feng, Yidong Huang, Kaiyu Cui, Fang Liu, Wei Zhang, Wei Zhang, Xiangdong Zhang

2023Science Advances27 citationsDOIOpen Access PDF

Abstract

Integrated quantum photonic circuit is a promising platform for the realization of quantum information processing in the future. To achieve the large-scale quantum photonic circuits, the applied quantum logic gates should be as small as possible for the high-density integration on chips. Here, we report the implementation of super-compact universal quantum logic gates on silicon chips by the method of inverse design. In particular, the fabricated controlled-NOT gate and Hadamard gate are both nearly a vacuum wavelength, being the smallest optical quantum gates reported up to now. We further design the quantum circuit by cascading these fundamental gates to perform arbitrary quantum processing, where the corresponding size is about several orders smaller than that of previous quantum photonic circuits. Our study paves the way for the realization of large-scale quantum photonic chips with integrated sources and can have important applications in the field of quantum information processes.

Topics & Concepts

Quantum gateQuantum circuitQuantum networkQuantum informationQuantum error correctionLogic gateQuantum computerComputer scienceQuantum technologyPhysicsQuantum sensorElectronic engineeringQuantumOptoelectronicsOpen quantum systemQuantum mechanicsAlgorithmEngineeringQuantum Information and CryptographyNeural Networks and Reservoir ComputingQuantum Computing Algorithms and Architecture