Coherent Control with Modified Vacuum Fields

Strong light-matter coupling: from self-hybridized polaritons to Casimir self-assembly

14 Aug 2024, 09:30

30m

Albano Building 3

Invited Talk Wednesday Morning

Speaker

Prof. Timur Shegai (Chalmers University of Technology)

Description

Timur O. Shegai

Department of Physics, Chalmers University of Technology, Gothenburg, 412 96, Sweden

Email: timurs@chalmers.se

Abstract:

Strong light-matter interactions are at the core of many electromagnetic phenomena. In this talk, I will give an overview of several nanophotonic systems which support polaritons – hybrid states of light and matter, as well as try to demonstrate their potential usefulness in applications. I will start with transition metal dichalcogenides (TMDs) and specifically discuss one-dimensional edges in these two-dimensional materials [1-2]. I will also discuss the concept of self-hybridization, a scenario in which both light and matter subparts in a polaritonic system are supported by one and the same (nano)structured material [3]. I will demonstrate such self-hybridization in TMD nanostructures [1-2] and levitating water droplets [4]. The latter is interesting, due to abundance of such water droplets in natural systems, including mists, fogs, and clouds. Furthermore, I will show that Fabry-Pérot resonators, one of the most important workhorses of nanophotonics, can spontaneously form in an aqueous solution of gold nanoflakes [5-7]. This effect is possible due to the intricate balance between attractive Casimir-Lifshitz forces and repulsive electrostatic forces acting between the flakes. There is a hope that this technology is going to be useful for future developments in self-assembly and polaritonics, as well as help develop a unified view of Casimir and strong light-matter coupling phenomena.

ACKNOWLEDGEMENT
This work was supported by Swedish Research Council (grant no. 2022-03347), Knut and Allice Wallenberg foundation (grant no. 2019.0140), Vinnova 2D-Tech competence center (ref. 2019-00068), and Olle Engkvists foundation (grant no. 211-0063).

REFERENCES
[1] Nat. Commun., 11, 4604, (2020)
[2] Laser & Photonics Rev., 17, 2200057, (2023)
[3] J. Chem. Phys., 154, 024701, (2021)
[4] Phys. Rev. Lett., 132, 193804, (2024)
[5] Nature, 597, 214-219, (2021)
[6] Nat. Phys., 19, 271-278, (2023)
[7] Sci. Adv., 10, eadn1825, (2024)