Displaying One Session

08/21/2019 01:00 PM - 03:00 PM Emerald E
Time
01:00 PM - 03:00 PM
NPNMAP - Novel Phenomena and New Materials for Advanced Photonics

WE3.1 - CRYSTAL GROWTH AND CHARACTERIZATION OF CHIRAL MAGNETS

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

Abstract

Abstract

Chirality characterizes the broken mirror symmetry in a material. The entanglement of chirality and magnetism could induce novel phase transitions, and is essential for realizing new functions for applications. In this talk, I will discuss the crystal growth and physical properties of several chiral magnets.

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NPNMAP - Novel Phenomena and New Materials for Advanced Photonics

WE3.2 - DIAMOND QUANTUM PHOTONICS

Presentation Type
Invited Submission
Date
08/21/2019
Time
01:00 PM - 03:00 PM
Room
Emerald E
Duration
30 Minutes
Lecture Time
01:30 PM - 02:00 PM
NPNMAP - Novel Phenomena and New Materials for Advanced Photonics

WE3.3 - QUANTUM PHOTONIC INTEGRATED CIRCUITS WITH SEMICONDUCTOR QUANTUM DOTS

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

Abstract

Abstract

The recent advances in the development of efficient and scalable photonic integrated quantum hardware, based on semiconductor quantum dots in Gallium Arsenide, are reported. I will present novel approaches to on-chip optical routing based on nanomechanical systems and to single-photon generation in nanophotonic waveguides.

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ANP - Advanced Nanophotonics Platform

WE3.4 - SILICON PHOTONIC ENABLED RESIDUE NUMBER SYSTEM ADDER AND MULTIPLIER

Presentation Type
Contributed Submission
Date
08/21/2019
Time
01:00 PM - 03:00 PM
Room
Emerald E
Duration
15 Minutes
Lecture Time
02:30 PM - 02:45 PM

Abstract

Abstract

Here we show a nanophotonic RNS arithmetic implementation by spatially shifting the input waveguides relative to a crossbar routers’ outputs, where the moduli are represented by the number of waveguides. This highly parallelizable in-the-network kernel processes information at 10’s of ps suitable for real-time computing.

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NPNMAP - Novel Phenomena and New Materials for Advanced Photonics

WE3.5 - NONLINEAR NANOPHOTONIC MEDIA FOR ARTIFICIAL NEURAL COMPUTING

Abstract

Abstract

We show optical waves passing through a nanophotonic medium can perform artificial neural computing. Such a medium exploits sub-wavelength linear and nonlinear scatterers to realize complex input-output mapping far beyond the capabilities of traditional nanophotonic devices.

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