Light-matter interactions within the Ehrenfest–Maxwell–Pauli–Kohn–Sham framework: fundamentals, implementation, and nano-optical applications

IF 35 1区物理与天体物理 Q1 PHYSICS, CONDENSED MATTER

Advances in Physics Pub Date : 2018-12-12 DOI:10.1080/00018732.2019.1695875

R. Jestädt, M. Ruggenthaler, Micael J. T. Oliveira, Á. Rubio, H. Appel

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引用次数: 49

Abstract

In recent years significant experimental advances in nano-scale fabrication techniques and in available light sources have opened the possibility to study a vast set of novel light-matter interaction scenarios, including strong coupling cases. In many situations nowadays, classical electromagnetic modeling is insufficient as quantum effects, both in matter and light, start to play an important role. Instead, a fully self-consistent and microscopic coupling of light and matter becomes necessary. We provide here a critical review of current approaches for electromagnetic modeling, highlighting their limitations. We show how to overcome these limitations by introducing the theoretical foundations and the implementation details of a density-functional approach for coupled photons, electrons, and effective nuclei in non-relativistic quantum electrodynamics. Starting point of the formalism is a generalization of the Pauli–Fierz field theory for which we establish a one-to-one correspondence between external fields and internal variables. Based on this correspondence, we introduce a Kohn-Sham construction which provides a computationally feasible approach for ab-initio light-matter interactions. In the mean-field limit, the formalism reduces to coupled Ehrenfest–Maxwell–Pauli–Kohn–Sham equations. We present an implementation of the approach in the real-space real-time code Octopus using the Riemann–Silberstein formulation of classical electrodynamics to rewrite Maxwell's equations in Schrödinger form. This allows us to use existing very efficient time-evolution algorithms developed for quantum-mechanical systems also for Maxwell's equations. We show how to couple the time-evolution of the electromagnetic fields self-consistently with the quantum time-evolution of the electrons and nuclei. This approach is ideally suited for applications in nano-optics, nano-plasmonics, (photo) electrocatalysis, light-matter coupling in 2D materials, cases where laser pulses carry orbital angular momentum, or light-tailored chemical reactions in optical cavities just to name but a few.

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Ehrenfest-Maxwell-Pauli-Kohn-Sham框架中的光-物质相互作用:基础，实现和纳米光学应用

近年来，纳米级制造技术和可用光源的重大实验进展为研究大量新的光物质相互作用场景（包括强耦合情况）开辟了可能性。在当今的许多情况下，经典的电磁建模是不够的，因为量子效应，无论是在物质还是光中，都开始发挥重要作用。相反，光和物质的完全自洽和微观耦合变得必要。我们在这里对当前的电磁建模方法进行了批判性的回顾，强调了它们的局限性。我们通过介绍非相对论量子电动力学中耦合光子、电子和有效核的密度泛函方法的理论基础和实现细节，展示了如何克服这些限制。形式主义的起点是泡利-菲尔兹场论的推广，为此我们在外部场和内部变量之间建立了一对一的对应关系。基于这种对应关系，我们引入了一种Kohn-Sham结构，它为从头计算轻物质相互作用提供了一种计算上可行的方法。在平均场极限中，形式化简化为耦合的Ehrenfest–Maxwell–Pauli–Kohn–Sham方程。我们在真实空间实时代码Octopus中介绍了该方法的实现，该代码使用经典电动力学的黎曼-西尔伯斯坦公式将麦克斯韦方程改写为薛定谔形式。这使我们能够使用为量子力学系统开发的现有非常有效的时间演化算法，也可以用于麦克斯韦方程。我们展示了如何将电磁场的时间演化与电子和原子核的量子时间演化自洽耦合。这种方法非常适合应用于纳米光学、纳米等离子体、（光）电催化、2D材料中的光-物质耦合、激光脉冲携带轨道角动量的情况，或光腔中的光定制化学反应，仅举几例。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advances in Physics 物理-物理：凝聚态物理

CiteScore

67.60

自引率

0.00%

发文量

期刊介绍： Advances in Physics publishes authoritative critical reviews by experts on topics of interest and importance to condensed matter physicists. It is intended for motivated readers with a basic knowledge of the journal’s field and aims to draw out the salient points of a reviewed subject from the perspective of the author. The journal''s scope includes condensed matter physics and statistical mechanics: broadly defined to include the overlap with quantum information, cold atoms, soft matter physics and biophysics. Readership: Physicists, materials scientists and physical chemists in universities, industry and research institutes.