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(44) Production(s) de PITARD E.
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Role of spatial heterogeneity in the collective dynamics of cilia beating in a minimal one-dimensional model
Auteur(s): Dey S., Massiera G., Pitard E.
(Article) Publié:
Physical Review E: Statistical, Nonlinear, And Soft Matter Physics, vol. 97 p.012403 (2018)
Texte intégral en Openaccess :
Ref HAL: hal-01735760_v1
DOI: 10.1103/PhysRevE.97.012403
WoS: WOS:000423129000005
Exporter : BibTex | endNote
2 Citations
Résumé: Cilia are elastic hairlike protuberances of the cell membrane found in various unicellular organisms and in several tissues of most living organisms. In some tissues such as the airway tissues of the lung, the coordinated beating of cilia induce a fluid flow of crucial importance as it allows the continuous cleaning of our bronchia, known as mucociliary clearance. While most of the models addressing the question of collective dynamics and metachronal wave consider homogeneous carpets of cilia, experimental observations rather show that cilia clusters are heterogeneously distributed over the tissue surface. The purpose of this paper is to investigate the role of spatial heterogeneity on the coherent beating of cilia using a very simple one dimensional model for cilia known as the rower model. We systematically study systems consisting of a few rowers to hundreds of rowers and we investigate the conditions for the emergence of collective beating. When considering a small number of rowers, a phase drift occurs, hence a bifurcation in beating frequency is observed as the distance between rowers clusters is changed. In the case of many rowers, a distribution of frequencies is observed. We found in particular the pattern of the patchy structure that shows the best robustness in collective beating behavior, as the density of cilia is varied over a wide range.
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Collective behavior in a minimal model of cilia beating: synchronization, phase-locking and entrainment
Auteur(s): Pitard E.
(Affiches/Poster)
Gordon Research Conference on Complex Active & Adaptive Material Systems (Ventura CA, US), 2017-01-29
Ref HAL: hal-01939679_v1
Exporter : BibTex | endNote
Résumé: Collective behavior in a minimal model of cilia beating: synchronization, phase-locking and entrainment
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Activity statistics in a colloidal glass former: experimental evidence for a dynamical transition
Auteur(s): Abou Bérengère, Colin Rémy, Lecomte Vivien, Pitard E., van Wijland Frédéric
(Article) Publié:
The Journal Of Chemical Physics, vol. 148 p.164502 (2018)
Texte intégral en Openaccess :
Ref HAL: hal-01517340_v1
Ref Arxiv: 1705.00855
DOI: 10.1063/1.5006924
WoS: 000431291900023
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
5 Citations
Résumé: In a dense colloidal suspension at a volume fraction slightly lower than that of its glass transition, we follow the trajectories of an assembly of tracers over a large time window. We define a local activity, which quantifies the local tendency of the system to rearrange. We determine the statistics of the time and space integrated activity, and we argue that it develops a low activity tail that comes on a par with the onset of glassy behavior and heterogeneous dynamics. These rare events may be interpreted as the reflection of an underlying dynamic phase transition.
Commentaires: 10 pages, 15 figures
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Dynamique lente et effet rescue dans un modèle multiéchelle de métapopulations
Auteur(s): Pitard E.
(Séminaires)
CEFE (Montpellier, FR), 2016-04-14 |
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Long-Distance Rescue and Slow Extinction Dynamics Govern Multiscale Metapopulations
Auteur(s): Huth G., Haegeman Bart, Pitard E., Munoz François
(Article) Publié:
American Naturalist, vol. 186 p.460-469 (2015)
Ref HAL: hal-01254432_v1
DOI: 10.1086/682947
WoS: 000362840100006
Exporter : BibTex | endNote
6 Citations
Résumé: Rare long-distance dispersal is known to be critical for species dynamics, but how the interplay between short- and long-distance colonization influences regional persistence in a fragmented habitat remains poorly understood. We propose a metapopulation model that combines local colonization within habitat islands and long-distance colonization between islands. We study how regional occupancy dynamics are affected by the multiscale colonization process. We find that the island size distribution (ISD) is a key driver of the long-term occupancy dynamics. When the ISD is heterogeneous—that is, when the size of islands is variable—we show that extinction dynamics become very slow. We demonstrate that this behavior is unrelated to the well-known extinction debt near the critical extinction threshold. Hence, this finding questions the equivalence between extinction debt and critical transitions in the context of metapopulation collapse. Furthermore, we show that long-distance colonization can rescue small islands from extinction and sustain a steady regional occupancy. These results provide novel theoretical and practical insights into extinction dynamics and persistence in fragmented habitats and are thus relevant for the design of conservation strategies.
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Out-of-equilibrium models of transport with
dynamical local constraints
Auteur(s): Pitard E.
(Séminaires)
University of California at Berkeley, Chemistry Department (Berkeley, US), 2014-02-18 |
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Correlated percolation models of structured habitat in ecology
Auteur(s): Huh Geraldine, Lesne Annick, Munoz Francois, Pitard E.
(Article) Publié:
Physica A: Statistical Mechanics And Its Applications, vol. 416 p.290-308 (2014)
Texte intégral en Openaccess :
Ref HAL: hal-01201639_v1
Ref Arxiv: 1410.0208
DOI: 10.1016/j.physa.2014.08.006
WoS: WOS:000345725300029
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
7 Citations
Résumé: Percolation offers acknowledged models of random media when the relevant medium characteristics can be described as a binary feature. However, when considering habitat modeling in ecology, a natural constraint comes from nearest-neighbor correlations between the suitable/unsuitable states of the spatial units forming the habitat. Such constraints are also relevant in the physics of aggregation where underlying processes may lead to a form of correlated percolation. However, in ecology, the processes leading to habitat correlations are in general not known or very complex. As proposed by Hiebeler [Ecology {\bf 81}, 1629 (2000)], these correlations can be captured in a lattice model by an observable aggregation parameter $q$, supplementing the density $p$ of suitable sites. We investigate this model as an instance of correlated percolation. We analyze the phase diagram of the percolation transition and compute the cluster size distribution, the pair-connectedness function $C(r)$ and the correlation function $g(r)$. We find that while $g(r)$ displays a power-law decrease associated with long-range correlations in a wide domain of parameter values, critical properties are compatible with the universality class of uncorrelated percolation. We contrast the correlation structures obtained respectively for the correlated percolation model and for the Ising model, and show that the diversity of habitat configurations generated by the Hiebeler model is richer than the archetypal Ising model. We also find that emergent structural properties are peculiar to the implemented algorithm, leading to questioning the notion of a well-defined model of aggregated habitat. We conclude that the choice of model and algorithm have strong consequences on what insights ecological studies can get using such models of species habitat.
Commentaires: . Réf Journal: Physica A, 416, 290 (2014)
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