The isolation of stable atomically thin two-dimensional (2D) materials on arbitrary substrates has led to a revolution in solid-state device research. Various other 2D materials (including semiconductors) with varying properties have been isolated, raising the prospects for devices assembled by van der Waals forces. Particularly, these van der Waals bonded semiconductors exhibit strong excitonic resonances and large optical dielectric constants as compared to bulk 3D semiconductors.
In this webinar hosted by the Optics for Energy Technical Group, Deep Jariwala will focus on the subject of strong light-matter coupling in excitonic 2D semiconductors, namely chalcogenides of Mo and W. Visible spectrum band-gaps with strong excitonic absorption makes transition metal dichalcogenides (TMDCs) of molybdenum and tungsten as attractive candidates for investigating strong light-matter interaction formation of hybrid states. Prof. Jariwala will present his recent work on the fundamental physics of light trapping in multi-layer TMDCs when coupled to plasmonic substrates.
Next, Prof. Jariwala will show the extension of these results to halide perovskites and superlattices of excitonic chalcogenides. These hybrid multilayers offer a unique opportunity to tailor the light-dispersion in the strong-coupling regime. If time permits, Prof. Jariwala will also present his recent work on controlling light in magnetic semiconductors, broadband perfect absorbers using 2D semimetals, and scalable, localized quantum emitters from strained 2D semiconductors.
Subject Matter Level: Intermediate - Assumes basic knowledge of the topic
What You Will Learn:
• Novel optical materials that are two-dimensional in nature
• Physics of light-trapping and light-matter interactions in excitonic semiconductors
• New opportunities in light harvesting and light modulation using two-dimensional materials
Who Should Attend:
• Undergraduates, graduates, and postdocs