R. Rumpf (US) University of Texas at El Paso
University of Texas at El Paso

Author Of 2 Presentations

 Conference Calendar
OMPEES - Optical Metamaterials, Plasmonics and Engineered Electromagnectic Structures

TuA4.2 - Electromagnetic and Photonic Applications of Spatially-Variant Lattices

Presentation Type
Invited Submission
Authors
Date
08/20/2019
Time
03:30 PM - 05:30 PM
Room
Sandpiper A/B
Duration
30 Minutes
Lecture Time
04:00 PM - 04:30 PM

Abstract

Abstract

Spatially-variant lattices (SVLs) are periodic structures that are bent, twisted, or otherwise functionally-graded in a manner that minimizes deformations to the unit cells. SVLs have been shown to unlock new physical mechanisms and provide extraordinary control over fields and waves.
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MMAP - Materials and Manufacturing for Advanced Photonics

TuD3.3 - ROUTES TO NANOPHOTONIC DEVICES FOR MICRON-SCALE BEAM STEERING IN 3D

Presentation Type
Invited Submission
Authors
Date
08/20/2019
Time
01:15 PM - 03:15 PM
Room
Emerald D
Duration
30 Minutes
Lecture Time
02:15 PM - 02:45 PM

Abstract

Abstract

Self-collimating spatially-variant lattices (SVLs) are integrated photonic devices that can be designed to steer optical beams in 3D within micron-scale volumes. SVLs can be fabricated by multi-photon lithography, and new routes to these and related devices are being explored based on modified Bessel beams.

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Presenter Of 1 Presentation

 Conference Calendar
OMPEES - Optical Metamaterials, Plasmonics and Engineered Electromagnectic Structures

TuA4.2 - Electromagnetic and Photonic Applications of Spatially-Variant Lattices

Presentation Type
Invited Submission
Authors
Date
08/20/2019
Time
03:30 PM - 05:30 PM
Room
Sandpiper A/B
Duration
30 Minutes
Lecture Time
04:00 PM - 04:30 PM

Abstract

Abstract

Spatially-variant lattices (SVLs) are periodic structures that are bent, twisted, or otherwise functionally-graded in a manner that minimizes deformations to the unit cells. SVLs have been shown to unlock new physical mechanisms and provide extraordinary control over fields and waves.
Collapse