Collective Behaviour without Collective Order in Wild Swarms of Midges

Attanasi, Alessandro; Cavagna, Andrea; Castello, Lorenzo Del; Giardina, Irene; Melillo, Stefania; Parisi, Leonardo; Pohl, Oliver; Rossaro, Bruno; Shen, Edward; Silvestri, Edmondo; Viale, Massimiliano

doi:10.1371/journal.pcbi.1003697

Cited by 209 publications

(299 citation statements)

References 48 publications

(92 reference statements)

Supporting

Mentioning

280

Contrasting

Order By: Relevance

“…These active components can be subcellular (such as microtubules powered by molecular motors, and actomyosin networks [2,3]), synthetic (e.g., self-propelled colloids [4] or interacting microrobots), or, alternatively, living organisms [5][6][7][8], such as birds, fish [9], microorganisms [10,11], or insects [12]. Hybrid systems composed of motile rod-shaped bacteria placed in nontoxic liquid crystals have also been realized recently [13].…”

Section: Introductionmentioning

confidence: 99%

Geometry of thresholdless active flow in nematic microfluidics

2017

View full text Add to dashboard Cite

Active nematics are orientationally ordered but apolar fluids composed of interacting constituents individually powered by an internal source of energy. When activity exceeds a system-size-dependent threshold, spatially uniform active apolar fluids undergo a hydrodynamic instability leading to spontaneous macroscopic fluid flow. Here we show that a special class of spatially nonuniform configurations of such active apolar fluids display laminar (i.e., time-independent) flow even for arbitrarily small activity. We also show that two-dimensional active nematics confined on a surface of nonvanishing Gaussian curvature must necessarily experience a nonvanishing active force. This general conclusion follows from a key result of differential geometry: Geodesics must converge or diverge on surfaces with nonzero Gaussian curvature. We derive the conditions under which such curvatureinduced active forces generate thresholdless flow for two-dimensional curved shells. We then extend our analysis to bulk systems and show how to induce thresholdless active flow by controlling the curvature of confining surfaces, external fields, or both. The resulting laminar flow fields are determined analytically in three experimentally realizable configurations that exemplify this general phenomenon: (i) toroidal shells with planar alignment, (ii) a cylinder with nonplanar boundary conditions, and (iii) a Frederiks cell that functions like a pump without moving parts. Our work suggests a robust design strategy for active microfluidic chips and could be tested with the recently discovered living liquid crystals.

show abstract

Section: Introductionmentioning

confidence: 99%

Geometry of thresholdless active flow in nematic microfluidics

2017

View full text Add to dashboard Cite

show abstract

“…Research on arthropod swarms (e.g. midges, Attanasi et al, 2014;acari, Mailleux et al, 2011;ants, Sasaki et al, 2013;bees, Seeley et al, 2012), fish schools (Ward et al, 2011), bird flocks (Ballerini et al, 2008), mammal troops (Strandburg-Peshkin et al, 2015) and human crowds (Moussaïd et al, 2011) shows how consensus decisions are typically reached via mechanisms of quorum sensing and networks of feedback loops that disproportionately amplify or reduce the responses of individuals to social stimuli (Camazine et al, 2001;Couzin, 2009;Sumpter, 2010). Through transfer and collective processing of social information, grouped individuals can make faster and/or more accurate decisions than isolated conspecifics, an emergent property of collective decisions known as 'swarm intelligence' (Krause et al, 2010;Sumpter and Pratt, 2009).…”

Section: Introductionmentioning

confidence: 99%

Collective selection of food patches in Drosophila

Lihoreau

Clarke

Buhl

et al. 2016

Journal of Experimental Biology

View full text Add to dashboard Cite

The fruit fly Drosophila melanogaster has emerged as a model organism for research on social interactions. Although recent studies have described how individuals interact on foods for nutrition and reproduction, the complex dynamics by which groups initially develop and disperse have received little attention. Here we investigated the dynamics of collective foraging decisions by D. melanogaster and their variation with group size and composition. Groups of adults and larvae facing a choice between two identical, nutritionally balanced food patches distributed themselves asymmetrically, thereby exploiting one patch more than the other. The speed of the collective decisions increased with group size, as a result of flies joining foods faster. However, smaller groups exhibited more pronounced distribution asymmetries than larger ones. Using computer simulations, we show how these non-linear phenomena can emerge from social attraction towards occupied food patches, whose effects add up or compete depending on group size. Our results open new opportunities for exploring complex dynamics of nutrient selection in simple and genetically tractable groups.

show abstract

“…So far, only a handful of quantitative datasets have been gathered for large animal groups (19-21). Most of them have focused on elementary cases where the prevailing biological imperative seems to be group cohesion, either to gain protection from potential predators, such as for the spontaneous collective motion exhibited by starling flocks (19,22) and some fish schools (23-25), or for reproductive purposes, as in swarms of midges (21,26).One important and, so far, often neglected aspect of collective motion is the existence of individual-level behavioral shifts, which, in turn, may trigger a transition at the collective level. For instance, in many species of fish, groups regularly alternate between a swarming state, in which fish simply aggregate with a low level of polarization, and a schooling state, in which individuals are aligned and move in the same direction (27,28).…”

mentioning

confidence: 99%

mentioning

confidence: 99%

“…Deciphering these interactions, their relation with the patterns emerging at the collective level, and their connections with the physiological and ecological constraints peculiar to each group-living species is crucial to understanding the evolution of collective phenomena in biological systems (16)(17)(18). So far, only a handful of quantitative datasets have been gathered for large animal groups (19)(20)(21). Most of them have focused on elementary cases where the prevailing biological imperative seems to be group cohesion, either to gain protection from potential predators, such as for the spontaneous collective motion exhibited by starling flocks (19,22) and some fish schools (23)(24)(25), or for reproductive purposes, as in swarms of midges (21,26).…”

mentioning

confidence: 99%

See 1 more Smart Citation

Intermittent collective dynamics emerge from conflicting imperatives in sheep herds

Ginelli

Peruani

Pillot

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

138

136

View full text Add to dashboard Cite

Among the many fascinating examples of collective behavior exhibited by animal groups, some species are known to alternate slow group dispersion in space with rapid aggregation phenomena induced by a sudden behavioral shift at the individual level. We study this phenomenon quantitatively in large groups of grazing Merino sheep under controlled experimental conditions. Our analysis reveals strongly intermittent collective dynamics consisting of fast, avalanche-like regrouping events distributed on all experimentally accessible scales. As a proof of principle, we introduce an agent-based model with individual behavioral shifts, which we show to account faithfully for all collective properties observed. This offers, in turn, an insight on the individual stimulus/ response functions that can generate such intermittent behavior. In particular, the intensity of sheep allelomimetic behavior plays a key role in the group's ability to increase the per capita grazing surface while minimizing the time needed to regroup into a tightly packed configuration. We conclude that the emergent behavior reported probably arises from the necessity to balance two conflicting imperatives: (i) the exploration of foraging space by individuals and (ii) the protection from predators offered by being part of large, cohesive groups. We discuss our results in the context of the current debate about criticality in biology.sheep herds | collective behavior | self-organization | computational modeling | Allelomimetism T he social interactions and behavioral mechanisms involved in the coordination of collective movements in animal groups largely determine the animals' ability to display adapted responses when they face challenges, such as finding, efficiently, food sources (1-4) or safe resting places (5-7) or avoiding predators (8-13). Thus, the diversity of collective motion patterns observed in groupliving species reflects the multiple forms of interactions individuals use for coordinating their behavioral actions (14,15). Deciphering these interactions, their relation with the patterns emerging at the collective level, and their connections with the physiological and ecological constraints peculiar to each group-living species is crucial to understanding the evolution of collective phenomena in biological systems (16-18). So far, only a handful of quantitative datasets have been gathered for large animal groups (19-21). Most of them have focused on elementary cases where the prevailing biological imperative seems to be group cohesion, either to gain protection from potential predators, such as for the spontaneous collective motion exhibited by starling flocks (19,22) and some fish schools (23-25), or for reproductive purposes, as in swarms of midges (21,26).One important and, so far, often neglected aspect of collective motion is the existence of individual-level behavioral shifts, which, in turn, may trigger a transition at the collective level. For instance, in many species of fish, groups regularly alternate between a swarming state, in wh...

show abstract

Collective Behaviour without Collective Order in Wild Swarms of Midges

Cited by 209 publications

References 48 publications

Geometry of thresholdless active flow in nematic microfluidics

Geometry of thresholdless active flow in nematic microfluidics

Collective selection of food patches in Drosophila

Intermittent collective dynamics emerge from conflicting imperatives in sheep herds

Contact Info

Product

Resources

About