0000000000219052

AUTHOR

Jean-guy Caputo

showing 2 related works from this author

Fractal Grid – towards the future smart grid

2017

International audience; In the last two decades, electricity grids have faced many challenges that they were not designed to handle. These include integrating weather-dependent renewables, distributed generators, storage units and other advanced components, as well as taking into account active demand. These challenges, together with the ageing of infrastructures, make it more difficult to deliver cost-effective, reliable power. To overcome these issues requires creating new network architectures. The research project Fractal Grid proposes fractality as a core concept to model, analyze and design smart grids in their evolution up to 2030 and beyond. This paper presents the project, its meth…

Engineering0211 other engineering and technologiesSmart grid02 engineering and technologycomputer.software_genre7. Clean energy01 natural sciences[SPI.ENERG] Engineering Sciences [physics]/domain_spi.energFractal[ SPI.NRJ ] Engineering Sciences [physics]/Electric powerElectricity[SPI.ENERG]Engineering Sciences [physics]/domain_spi.energ0103 physical sciences021108 energy010306 general physics[ SPI.ENERG ] Engineering Sciences [physics]/domain_spi.energNetwork architecturebusiness.industryManagement science[SPI.NRJ]Engineering Sciences [physics]/Electric powerGeneral MedicineGridRenewable energySmart gridGrid computing13. Climate actionFractal gridSystems engineeringElectricitybusinesscomputer[SPI.NRJ] Engineering Sciences [physics]/Electric powerCIRED - Open Access Proceedings Journal
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Electromagnetically induced switching of ferroelectric thin films

2007

We analyze the interaction of an electromagnetic spike (one cycle) with a thin layer of ferroelectric medium with two equilibrium states. The model is the set of Maxwell equations coupled to the undamped Landau-Khalatnikov equation, where we do not assume slowly varying envelopes. From linear-scattering theory, we show that low-amplitude pulses can be completely reflected by the medium. Large-amplitude pulses can switch the ferroelectric. Using numerical simulations and analysis, we study this switching for long and short pulses, estimate the switching times, and provide useful information for experiments.

010302 applied physicsPhysicsCondensed matter physicsScatteringNumerical analysisThin layerFOS: Physical sciencesPattern Formation and Solitons (nlin.PS)Condensed Matter Physics01 natural sciencesFerroelectricityNonlinear Sciences - Pattern Formation and SolitonsElectronic Optical and Magnetic Materialssymbols.namesakeAmplitudeMaxwell's equations0103 physical sciencessymbolsFerroelectric thin filmsThin film010306 general physicsComputingMilieux_MISCELLANEOUS
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