Displaying One Session

08/21/2019 01:00 PM - 03:00 PM Emerald D
Time
01:00 PM - 03:00 PM
ANP - Advanced Nanophotonics Platform

WD3.1 - CONTROL OF LIGHT-MATTER INTERACTION IN 2D MATERIALS

Presentation Type
Invited Submission
Date
08/21/2019
Time
01:00 PM - 03:00 PM
Room
Emerald D
Duration
30 Minutes
Lecture Time
01:00 PM - 01:30 PM

Abstract

Abstract

In this talk we will present our recent work on strong light matter coupling and its control in 2D transition metal dichalcogenides (TMDs). We will also briefly discuss strain activated single photon emitters in hexagonal boron nitride and integration with photonic resonators.
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ANP - Advanced Nanophotonics Platform

WD3.2 - Ballistic Metamaterials

Presentation Type
Invited Submission
Date
08/21/2019
Time
01:00 PM - 03:00 PM
Room
Emerald D
Duration
30 Minutes
Lecture Time
01:30 PM - 02:00 PM

Abstract

Abstract

Ballistic metamaterials, metal-dielectric composites with the unit cell size smaller than electron mean free path, represent a new class of composite media with many unique properties, such as hyperbolic response above the plasma frequency.
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ANP - Advanced Nanophotonics Platform

WD3.3 - Machine-Learning-Assisted Photonic Design and Applications

Presentation Type
Invited Submission
Date
08/21/2019
Time
01:00 PM - 03:00 PM
Room
Emerald D
Duration
30 Minutes
Lecture Time
02:00 PM - 02:30 PM

Abstract

Abstract

We merge topology optimization with artificial-intelligence-assisted algorithms and integrate machine-learning based analysis with photonic design and quantum optical measurements. By implementing deep-learning assisted topology optimization we advance metasurface design for energy applications. We also apply neural network-based technique for real-time quantum measurements.

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WD3.4 - LEVERAGING CRYSTAL ANISOTROPY FOR INFRARED NANO-OPTICS

Presentation Type
Invited Submission
Date
08/21/2019
Time
01:00 PM - 03:00 PM
Room
Emerald D
Duration
30 Minutes
Lecture Time
02:30 PM - 03:00 PM

Abstract

Abstract

This talk will address the potential for leveraging such large crystal anisotropy for realizing reconfigurable planar metasurfaces, flat and compact IR components and actively tunable and modulated IR optics.

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