MRI: Fundamental Studies of Filamentation Interaction

Joint Technology Office
High Energy Laser

Program Summary

A Multidisciplinary Research Initiative funded by the High Energy Laser – Joint Technology Office.

Filamentation of high-power femtosecond laser pulses in air has received much attention in the last decade. Yet many aspects of this phenomenon are still not well understood. Even the basic mechanism for stabilization of the filamentation in air has recently come into question in the latest theoretical studies. The nature of the carrier field, its extent and impact on the propagation and lifetime are not well understood. In particular we have little knowledge of the nature of the gaseous medium both during and following the propagation of the filament. Recent studies by some of our team have shown that molecular excitation effects in the filament gas may be playing a role. Unusual phenomena also seem to be associated with filaments made by UV laser beams; little white light is generated and other effects are unclear.

As we move into the realm of engineering matrices of filaments, with both spatially and temporally bundles of filaments propagating through the atmosphere, and with the innovations of Airy beam and Bessel bullet formation of filaments, we urgently need to resolve these fundamental scientific uncertainties on the basic formation of filaments. This is one of the two foci of this program. To this end we have teamed with experts in advanced modeling of filaments (Philip Sprangle, Navy Research Laboratory), molecular interactions in filaments (Tamar Seideman, Northwestern University), and UV filaments (Jean-Claude Diels, University of New Mexico). Our proposal therefore addresses the basic fundamental science of the interaction of the filament with air. We will study other gases, and gas combinations to elucidate the scientific mechanisms, but the overall objective is to obtain a firmer understanding of the interaction mechanisms and consequences of the filaments propagating through air.

A second focus of this proposal is to place the science of the interaction of filamented laser light with solid materials on a firmer basis. At UCF, we are the only American university to have a program of study in this area. At its basis is the study of laser-produced plasmas, a topic that we know well, has comprehensive diagnostics and modeling capabilities.

A Multidisciplinary Research Initiative funded by the High Energy Laser – Joint Technology Office.

Principal Investigator

Martin Richardson (University of Central Florida)

Co-Investigators

Matthieu Baudelet (University of Central Florida)

Tamar Seideman (Northwestern University)

Partners

Jean-Claude Diels (University of New Mexico)

National Laboratory Partners

Philip Sprangle (US Naval Research Laboratory)

Found 12935 publications.

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Books

2025

Bahaa E. A. Saleh. "Quantum Photonics Bimodes, Qubits, and Biphotons". Springer Cham

2024

Jean-Claude Diels, Martin C. Richardson and Ladan Arissan. "Light Filaments: Structures, challenges and applications". SciTech Publishing

2020

Jiun-Haw Lee, David N. Liu and Shin-Tson Wu. "Introduction to Flat Panel Displays, Second Edition". Wiley ISBN: 978-1-119-28227-3

2020

Jiun-Haw Lee, I-Chun Cheng, Hong Hua, and Shin-Tson Wu. "Introduction to Flat Panel Displays, 2nd Edition". Wiley

2020

Konstantin L. Vodopyanov. "Laser-based Mid-infrared Sources and Applications". Wiley

2019

Ivan Divliansky - editor. "Advances in high-power fiber and diode laser engineering". ISBN-13: 978-1-78561-751-5, 2019

2017

K.L. Vodopyanov, K. Schepler. "Nonlinear frequency generation and conversion: materials, devices, and applications XVI". Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XV, Proceedings of SPIE, 10088

2016

K.L. Vodopyanov, K. Scheppler. "Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XV". Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XV, Proceedings of SPIE, Volume 9731

2015

K.L. Vodopyanov. "Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XIV". Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XIV, Proceedings of SPIE, Volume 9347

2014

Deng-Ke Yang and Shin-Tson Wu. "Fundamentals of Liquid Crystal Devices (Second Edition)". Wiley

2014

Dengke Yang and Shin-Tson Wu. "Fundamentals of Liquid Crystal Devices, 2nd edition". Wiley

2014

Matthieu Baudelet (editor). "Laser spectroscopy for sensing: Fundamentals, techniques and applications". Matthieu Baudelet, “Laser spectroscopy for sensing: Fundamentals, techniques and applications”, Woodhead Publishing Ltd (2014)

2014

Konstantin L. Vodopyanov. "Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XIII". Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XIII, Proceedings of SPIE, Volume 8964

2013

Konstantin Vodopyanov, Yehoshua Kalisky. "Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XII". Konstantin L. Vodopyanov, Yehoshua Kalisky (ed.), "Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XII," Proceedings of SPIE, Volume 8604

2012

R. Driggers, M. Friedman, and J. Nichols. "Introduction to Infrared and Electro-Optical Systems: Second Edition". Artech House

2012

H. Ren and S. T. Wu. "Introduction to Adaptive Lenses". Wiley

2012

Konstantin L. Vodopyanov. "Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XI". Konstantin L. Vodopyanov (ed.), “Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications XI,” Proceedings of SPIE, Volume 8240, 2012

2012

S. Fathpour and B. Jalali, Editors. "Silicon Photonics for Telecommunications and Biomedicine". CRC Press (2012).

2011

Z. Chang. "Fundamentals of Attosecond Optics". CRC Press

2011

B. E. A. Saleh. "Introduction to Subsurface Imaging". Cambridge University Press

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