Litcius/Paper detail

Chirality logic gates

Yi Zhang, Yadong Wang, Yunyun Dai, Xueyin Bai, Xuerong Hu, Luojun Du, Hai Hu, Xiaoxia Yang, Diao Li, Qing Dai, Tawfique Hasan, Zhipei Sun

2022Science Advances71 citationsDOIOpen Access PDF

Abstract

The ever-growing demand for faster and more efficient data transfer and processing has brought optical computation strategies to the forefront of research in next-generation computing. Here, we report a universal computing approach with the chirality degree of freedom. By exploiting the crystal symmetry-enabled well-known chiral selection rules, we demonstrate the viability of the concept in bulk silica crystals and atomically thin semiconductors and create ultrafast (<100-fs) all-optical chirality logic gates (XNOR, NOR, AND, XOR, OR, and NAND) and a half adder. We also validate the unique advantages of chirality gates by realizing multiple gates with simultaneous operation in a single device and electrical control. Our first demonstrations of logic gates using chiral selection rules suggest that optical chirality could provide a powerful degree of freedom for future optical computing.

Topics & Concepts

XNOR gateChirality (physics)Logic gateNAND gateOptical computingComputer scienceComputationNanotechnologyTopology (electrical circuits)PhysicsMaterials scienceOpticsEngineeringQuantum mechanicsElectrical engineeringAlgorithmSymmetry breakingSpontaneous symmetry breakingNambu–Jona-Lasinio modelPhotonic and Optical DevicesNeural Networks and Reservoir Computing2D Materials and Applications
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