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光和物质的相互作用是物理学中一个基本研究领域. 电子是最早被发现组成物质的基本粒子, 因此电子与光场(光子)的相互作用很早就引起人们的研究兴趣. 电子分为束缚电子与自由电子. 束缚电子系统的跃迁会受到能级固定、选择定则等约束, 自由电子则不然. 近十多年来, 随着超快电子显微镜技术的发展, 人们提出并发展了用于描述量子自由电子(电子波包)和光场相互作用的理论—基于光子诱导近场电子显微成像过程, 成功展示了许多新奇量子效应以及新应用. 目前, 人们把光子诱导近场电子显微拓展量子光学中并展示了许多新奇现象, 包括自由电子和腔光子的纠缠、自由电子和自由电子的纠缠、自由电子量子比特、新奇光量子态制备等,从而开启了基于自由电子的“量子光学”时代. 本文首先概述了电子与光子的相互作用研究, 随后综述了光子诱导近场电子显微成像的理论、实验进展, 介绍了其应用场景. 最后,我们对基于自由电子的量子物理研究目前遇到的困难进行了总结, 并对未来发展进行了展望.
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关键词:
- 光子诱导近场电子显微成像/
- 自由电子/
- 量子光学/
- 时间分辨成像
The light-matter interaction is one of the fundamental research fields in physics. The electron is the first discovered elementary particle that makes up matter. Therefore, the interaction between electron and light field has long been the research interest of physicists. Electrons are divided into two kinds, i.e. bounded electrons and free electrons. The quantum transition of bounded electron system is constrained by the selection rules with the discrete energy levels, while the free electron systems are not. In the last decade, the experiments of photon-induced near-field electron microscopy (PINEM) have been demonstrated. The experimental setup of PINEM is based on ultrafast electron transmission microscopy (UTEM). The thoeritcal framworks have also been developed to describe the interaction between quantum free electrons and optical fields. Within macroscopic quantum electrodynamics, the concept of photon is extended to photonic quasi-particles. Solutions of maxwell's equations in medium that satisfy certain boundary conditions are called photonic quasiparticles, such as surface plasmon polaritons, phonon polaritons, or even magnetic field. The different dispersion relations of photonic quasi-particles produce abundant phenomena in the interaction between light and matter. The underlying information about the PINEM interaction can be inferred from the electron energy loss spectrum (EELS). It has been used for implementing the near-field imaging in its infancy. By now it is capable of not only realizing time-resolved dynamic imaging, reconstructing the dispersion relation of photonics crystal and its Bloch mode, but also measuring the mode lifetime directly. The PINEM has also been used to study free electron wavepacket reshaping, free electron comb, free electron attosecond pulse train, etc. Recently, this field has entered into the era of quantum optics, and people use PINEM to study novel phenomena in quantum optics, such as entanglement between free electrons and cavity photons, entanglement between free electrons and free electrons, free electron qubits, and preparation of novel light quantum states. In this paper, the theoretical and experimental development of free-electron quantum physics are reviewed. We have disscussed the application scenarios of quantum free electron system. The current difficulties and future development are envisaged.-
Keywords:
- photon-induced near field electron microscopy/
- free electron/
- quantum optics/
- time-resolved imaging
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