Ultrafast quantum gates with fully quantized free-electron quantum optics
Yongcheng Ding
TL;DR
This paper introduces a new grating-based architecture for fully quantized free-electron quantum optics, enabling ultrafast quantum gates with potential applications in quantum computing and information processing.
Contribution
It presents a novel framework mapping photon-electron interactions onto Jaynes-Cummings models for ultrafast quantum gates without cavities.
Findings
Design of ultrafast single- and two-qubit gates
Mapping interactions onto Jaynes-Cummings models
Platform for quantum simulation and sensing
Abstract
Free-electron quantum optics provides a versatile platform for manipulating electrons at the quantum level with potential applications in quantum information technologies. We propose a grating-based architecture for fully quantized free-electron quantum optics, in which photon-electron interactions map onto Jaynes-Cummings and Tavis-Cummings models via Bloch-Floquet analysis. Within this framework, we design ultrafast single- and two-qubit gates with cavity-free flying electrons, enabling universal quantum computing in experimentally accessible setups. More broadly, this framework establishes a platform for probing free-electron quantum optics and advancing quantum technologies in simulation, sensing, and information processing.
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Taxonomy
TopicsQuantum and electron transport phenomena · Mechanical and Optical Resonators · Advanced Electron Microscopy Techniques and Applications