Quantum photonics using 2D materials

Two-dimensional (2D) Van der Waals materials have emerged as a very attractive class of optoelectronic material due to the unprecedented strength in its interaction with light. In this talk I will discuss approaches to realize quantum photonic devices by integrating these 2D materials with microcavities, and metamaterials. I will first discuss the formation of strongly coupled half-light half-matter quasiparticles (microcavity polaritons) [1] and their optical and electrical control [2, 3] in the 2D transition metal dichacogenide (TMD) systems. Prospects of realizing condensation and few photon nonlinear switches using Rydberg states in TMDs will also be discussed. Following this, I will discuss the broadband enhancement of light-matter interaction in these 2D materials using photonic hypercrystals [4, 5] and chiral metasurfaces. Finally, I will talk about room temperature single photon emission from hexagonal boron nitride [6] and the prospects of developing deterministic quantum emitters using them through strain engineering [7]. The realization of room temperature single photon emitters and few photon nonlinear switches using 2D materials presents an attractive direction for robust next generation quantum photonic technologies.
References
[1] X. Liu, et al., Nature Photonics 9, 30 (2015)
[2] Z. Sun et al., Nature Photonics 11, 491 (2017)
[3] B. Chakraborty et al., Nano Lett. 18, 6455 (2018)
[4] T. Galfsky, et al., Nano Lett. 16, 4940 (2015)
[5] T. Galfsky, et al. Proc. Natl. Acad. Sci. 114, 5125 (2017).
[6] Z. Shotan, et al., ACS Photonics 3, 2490 (2016)
[7] N. Proscia, et al. Optica 5, 1128 (2018)