背景电磁场中电子涡旋束狄拉克旋量的构造

Andre G. Campos, K. Hatsagortsyan, C. Keitel
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引用次数: 5

摘要

狄拉克方程是一个由四个偏微分方程组成的系统,它的精确解非常罕见。它们中的绝大多数是针对高度对称的固定系统的。此外,时间相关动力学的解也很少。鉴于高能电子束与各种量子系统相互作用在激光领域的应用越来越多,需要寻找狄拉克方程精确解的新方法。我们提出了一种用几何代数描述旋场及其驱动电磁场的新方法来建立狄拉克方程的解的方法。我们通过在电子的传播方向上发展具有明确定义的轨道角动量的狄拉克方程的几个平稳和非平稳解来说明这种方法。第一组解用贝塞尔函数描述自由电子束,以及均匀和非均匀磁场下的固定解。第二套解决方案是新的,涉及到平面电磁波与一般不均匀的纵向磁场相结合。此外,所开发的技术使我们能够推导出这种场构型中动力学的一般物理性质,并提供了由动力学引起的自洽电磁场的物理预测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Construction of Dirac spinors for electron vortex beams in background electromagnetic fields
Exact solutions of the Dirac equation, a system of four partial differential equations, are rare. The vast majority of them are for highly symmetric stationary systems. Moreover, only a handful of solutions for time dependent dynamics exists. Given the growing number of applications of high energy electron beams interacting with a variety of quantum systems in laser fields, novel methods for finding exact solutions to the Dirac equation are called for. We present a method for building up solutions to the Dirac equation employing a recently introduced approach for the description of spinorial fields and their driving electromagnetic fields in terms of geometric algebras. We illustrate the method by developing several stationary as well as non-stationary solutions of the Dirac equation with well defined orbital angular momentum along the electron's propagation direction. The first set of solutions describe free electron beams in terms of Bessel functions as well as stationary solutions for both a homogeneous and an inhomogeneous magnetic field. The second set of solutions are new and involve a plane electromagnetic wave combined with a generally inhomogeneous longitudinal magnetic field. Moreover, the developed technique allows us to derive general physical properties of the dynamics in such field configurations, as well as provides physical predictions on the self-consistent electromagnetic fields induced by the dynamics.
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