Space-based application of the CAN laser to LIDAR and orbital debris remediation

M. N. Quinn; V. Jukna; T. Ebisuzaki; I. Dicaire; R. Soulard; L. Summerer; A. Couairon; G. Mourou

doi:10.1140/epjst/e2015-02577-5

Space-based application of the CAN laser to LIDAR and orbital debris remediation

M. N. Quinn
, V. Jukna
, T. Ebisuzaki
, I. Dicaire
, R. Soulard
, L. Summerer
, A. Couairon
, G. Mourou

Ecole Polytechnique, IZEST
Université Paris-Saclay
Riken
ESTEC - European Space Research and Technology Centre
Centre Collégial de Transfert de Technologie Optech

Research output: Contribution to journal › Article › peer-review

Abstract

Development of pulsed lasers for space-based science missions entail many additional challenges compared to terrestrial experiments. For systems requiring short pulses ≪1 ns with energies >100 mJ and fast repetition rates >10 kHz there are currently few if no laser architectures capable of operating with high electrical efficiency >20% and have good system stability. The emergence of a mulit-channel fiber-based Coherent-Amplifying-Network or CAN laser potentially enables such capability for space based missions. Here in this article we present an analysis of two such missions scaling up in pulse energy from ≈100 mJ for a supercontinuum LIDAR application utilising atmospheric filamentation to the higher energy demands needed for space debris remediation requiring ≈10 J pulses. This scalability of the CAN laser provides pathways for development of the core science and technology where many new novel space applications can be made possible.

Original language	English
Pages (from-to)	2645-2655
Number of pages	11
Journal	European Physical Journal: Special Topics
Volume	224
Issue number	13
DOIs	https://doi.org/10.1140/epjst/e2015-02577-5
Publication status	Published - 1 Oct 2015
Externally published	Yes

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Cite this

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title = "Space-based application of the CAN laser to LIDAR and orbital debris remediation",

abstract = "Development of pulsed lasers for space-based science missions entail many additional challenges compared to terrestrial experiments. For systems requiring short pulses ≪1 ns with energies >100 mJ and fast repetition rates >10 kHz there are currently few if no laser architectures capable of operating with high electrical efficiency >20\% and have good system stability. The emergence of a mulit-channel fiber-based Coherent-Amplifying-Network or CAN laser potentially enables such capability for space based missions. Here in this article we present an analysis of two such missions scaling up in pulse energy from ≈100 mJ for a supercontinuum LIDAR application utilising atmospheric filamentation to the higher energy demands needed for space debris remediation requiring ≈10 J pulses. This scalability of the CAN laser provides pathways for development of the core science and technology where many new novel space applications can be made possible.",

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AU - Quinn, M. N.

AU - Jukna, V.

AU - Ebisuzaki, T.

AU - Dicaire, I.

AU - Soulard, R.

AU - Summerer, L.

AU - Couairon, A.

AU - Mourou, G.

PY - 2015/10/1

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AB - Development of pulsed lasers for space-based science missions entail many additional challenges compared to terrestrial experiments. For systems requiring short pulses ≪1 ns with energies >100 mJ and fast repetition rates >10 kHz there are currently few if no laser architectures capable of operating with high electrical efficiency >20% and have good system stability. The emergence of a mulit-channel fiber-based Coherent-Amplifying-Network or CAN laser potentially enables such capability for space based missions. Here in this article we present an analysis of two such missions scaling up in pulse energy from ≈100 mJ for a supercontinuum LIDAR application utilising atmospheric filamentation to the higher energy demands needed for space debris remediation requiring ≈10 J pulses. This scalability of the CAN laser provides pathways for development of the core science and technology where many new novel space applications can be made possible.

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Space-based application of the CAN laser to LIDAR and orbital debris remediation

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