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Author |
Guerin, A.; Gravelle, S.; Dumais, J. |
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Title |
Forces behind plant cell division |
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Year |
2016 |
Publication |
Proceedings Of The National Academy Of Sciences Of The United States Of America |
Abbreviated Journal |
Proc. Natl. Acad. Sci. U. S. A. |
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Volume |
113 |
Issue |
32 |
Pages |
8891-8893 |
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Address |
[Guerin, Adrien; Gravelle, Simon; Dumais, Jacques] Univ Adolfo Ibanez, Fac Ingn Ciencias, Vina Del Mar 2562307, Chile, Email: jacques.dumais@uai.cl |
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Publisher |
Natl Acad Sciences |
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English |
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ISSN |
0027-8424 |
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Notes |
WOS:000381293300032 |
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Call Number |
UAI @ eduardo.moreno @ |
Serial |
664 |
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Author |
Gravelle, S.; Dumais, J. |
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Title |
A multi-scale model for fluid transport through a bio-inspired passive valve |
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Year |
2020 |
Publication |
Journal Of Chemical Physics |
Abbreviated Journal |
J. Chem. Phys. |
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Volume |
152 |
Issue |
1 |
Pages |
10 pp |
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Abstract |
Tillandsia landbeckii is a rootless plant thriving in the hyper-arid Atacama Desert of Chile. These plants use unique cellulose-based microscopic structures called trichomes to collect fresh water from coastal fog. The trichomes rely on a passive mechanism to maintain an asymmetrical transport of water: they allow for the fast absorption of liquid water deposited by sporadic fog events while preventing evaporation during extended drought periods. Inspired by the trichome's design, we study fluid transport through a micrometric valve. Combining Grand Canonical Monte Carlo with Non-Equilibrium Molecular Dynamics simulations, we first analyze the adsorption and transport of a fluid through a single nanopore at different chemical potentials. We then scale up the atomic results using a lattice approach, and simulate the transport at the micrometric scale. Results obtained for a model Lennard-Jones fluid and TIP4P/2005 water were compared, allowing us to identify the key physical parameters for achieving a passive hydraulic valve. Our results show that the difference in transport properties of water vapor and liquid water within the cellulose layer is the basis for the ability of the Tillandsia trichome to function as a water valve. Finally, we predict a critical pore dimension above which the cellulose layer can form an efficient valve. |
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Address |
[Gravelle, Simon; Dumais, Jacques] Univ Adolfo Ibanez, Fac Ingn & Ciencias, Vina Del Mar, Chile, Email: simon.gravelle@live.fr |
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Publisher |
Amer Inst Physics |
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English |
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0021-9606 |
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Notes |
WOS:000505578700020 |
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Call Number |
UAI @ eduardo.moreno @ |
Serial |
1083 |
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Author |
Raux, P.S.; Gravelle, S.; Dumais, J. |
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Title |
Design of a unidirectional water valve in Tillandsia |
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Year |
2020 |
Publication |
Nature Communications |
Abbreviated Journal |
Nat. Commun. |
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Volume |
11 |
Issue |
1 |
Pages |
7 pp |
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Abstract |
The bromeliad Tillandsia landbeckii thrives in the Atacama desert of Chile using the fog captured by specialized leaf trichomes to satisfy its water needs. However, it is still unclear how the trichome of T. landbeckii and other Tillandsia species is able to absorb fine water droplets during intermittent fog events while also preventing evaporation when the plant is exposed to the desert's hyperarid conditions. Here, we explain how a 5800-fold asymmetry in water conductance arises from a clever juxtaposition of a thick hygroscopic wall and a semipermeable membrane. While absorption is achieved by osmosis of liquid water, evaporation under dry external conditions shifts the liquid-gas interface forcing water to diffuse through the thick trichome wall in the vapor phase. We confirm this mechanism by fabricating artificial composite membranes mimicking the trichome structure. The reliance on intrinsic material properties instead of moving parts makes the trichome a promising basis for the development of microfluidics valves. |
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Address |
[Raux, Pascal S.; Gravelle, Simon; Dumais, Jacques] Univ Adolfo Ibanez, Fac Ingn & Ciencias, Vina Del Mar, Chile, Email: jacques.dumais@uai.cl |
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Nature Publishing Group |
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English |
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ISSN |
2041-1723 |
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Notes |
WOS:000512537400017 |
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Call Number |
UAI @ eduardo.moreno @ |
Serial |
1101 |
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Author |
Kamal, C.; Gravelle, S.; Botto, L. |
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Title |
Hydrodynamic slip can align thin nanoplatelets in shear flow |
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Year |
2020 |
Publication |
Nature Communications |
Abbreviated Journal |
Nat. Commun. |
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Volume |
11 |
Issue |
1 |
Pages |
10 pp |
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Abstract |
The large-scale processing of nanomaterials such as graphene and MoS2 relies on understanding the flow behaviour of nanometrically-thin platelets suspended in liquids. Here we show, by combining non-equilibrium molecular dynamics and continuum simulations, that rigid nanoplatelets can attain a stable orientation for sufficiently strong flows. Such a stable orientation is in contradiction with the rotational motion predicted by classical colloidal hydrodynamics. This surprising effect is due to hydrodynamic slip at the liquid-solid interface and occurs when the slip length is larger than the platelet thickness; a slip length of a few nanometers may be sufficient to observe alignment. The predictions we developed by examining pure and surface-modified graphene is applicable to different solvent/2D material combinations. The emergence of a fixed orientation in a direction nearly parallel to the flow implies a slip-dependent change in several macroscopic transport properties, with potential impact on applications ranging from functional inks to nanocomposites. Current theories predict that a plate-like particle rotates continuously in a shear flow. Kamal et al. instead show that even nanometric hydrodynamic slip may induce a thin plate-like particle to adopt a stable orientation, and discuss implications of this effect for flow processing of 2D nanomaterials. |
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Address |
[Kamal, Catherine; Gravelle, Simon; Botto, Lorenzo] Queen Mary Univ London, Sch Engn & Mat Sci, London, England, Email: l.botto@tudelft.nl |
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Nature Publishing Group |
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English |
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ISSN |
2041-1723 |
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Notes |
WOS:000536569900023 |
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Call Number |
UAI @ eduardo.moreno @ |
Serial |
1195 |
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Permanent link to this record |