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[Non-Permanents Only] Experimental Study of Salt Liquid (Electrolyte) for Energy Application // Self-Sustained Velocity Waves and Pattern Emergence in Tissues - Julien ALLEGRE (LIPhy) & Genesis MARQUEZ (LIPhy)

Séminaire

Le 12 janvier 2024

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Julien ALLEGRE (LIPhy) & Genesis MARQUEZ (LIPhy)

Julien ALLEGRE (LIPhy)

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Experimental Study of Salt Liquid (Electrolyte) for Energy Application

Electrolytes have a major role to play in the energy transition (storage: supercapacitors, batteries, fuel cells; harvesting: osmotic energy). In order to develop technologies with boosted performances, it is necessary to reach a fundamental understanding of the physics of electrolytes under nanoconfinement (in nanoporous electrodes or membranes).

Two physical phenomena are absolutely central in these applications: the accumulation of counter-ions on charged surfaces (electrical double layer), and the generation of hydrodynamic, electric or ionic fluxes by pressure, potential or concentration gradients (electrokinetic couplings).

In a first part, I'll go over those two concepts with you. Then I will show you the experimental setup I'm using right now and will continue to use as I work toward my PhD.


 

Genesis MARQUEZ VIVAS (LIPhy)

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Self-Sustained Velocity Waves and Pattern Emergence in Tissues

Supra-cellular organization is crucial to establish and maintain the structure, function and homeostasis of biological tissues. Several recent works reported that wave-like patterns of the velocity spontaneously appear in colonies of epithelial cells. Strikingly, supra-cellular waves are characterized by precise wavelength and period. As a PhD student, I investigate whether supra-cellular waves induce a transcriptomic divergence between the cells situated in the wave nodes and those in the antinodes.
 

Date

Le 12 janvier 2024
Complément date

17:00

Localisation

Complément lieu

LIPhy, salle de conférence

Publié le 11 janvier 2024

Mis à jour le 23 août 2024