Tethered fleximags as artificial cilia

Avin Babataheri; Marcus Roper; Marc Fermigier; Olivia Du Roure

doi:10.1017/S002211201100005X

Tethered fleximags as artificial cilia

Avin Babataheri
, Marcus Roper
, Marc Fermigier
, Olivia Du Roure

Research output: Contribution to journal › Article › peer-review

Abstract

Flexible superparamagnetic filaments ('fleximags') are very slender elastic filaments, which can be driven by distributed magnetic torques to mimic closely the behaviour of biological flagella. Previously, fleximags have been used as a basis for artificial micro-swimmers capable of transporting small cargos Dreyfus et al. (Nature, vol. 437, 2005, p. 862). Here, we demonstrate how these filaments can be anchored to a wall to make carpets of artificial micro-magnetic cilia with tunable densities. We analyse the dynamics of an artificial cilium under both planar and three-dimensional beating patterns. We show that the dynamics are controlled by a single characteristic length scale varying with the inverse square root of the driving frequency, providing a mechanism to break the fore and aft symmetry and to generate net fluxes and forces. However, we show that an effective geometrical reciprocity in the filament dynamics creates intrinsic limitations upon the ability of the artificial flagellum to pump fluid when driven in two dimensions.

Original language	English
Pages (from-to)	5-13
Number of pages	9
Journal	Journal of Fluid Mechanics
Volume	678
DOIs	https://doi.org/10.1017/S002211201100005X
Publication status	Published - 10 Jul 2011
Externally published	Yes

Keywords

Low-Reynolds-number flows
MEMS/NEMS
swimming/flying

Access to Document

10.1017/S002211201100005X

Cite this

@article{c7813049f68146178fc51ce27d92cc08,

title = "Tethered fleximags as artificial cilia",

abstract = "Flexible superparamagnetic filaments ('fleximags') are very slender elastic filaments, which can be driven by distributed magnetic torques to mimic closely the behaviour of biological flagella. Previously, fleximags have been used as a basis for artificial micro-swimmers capable of transporting small cargos Dreyfus et al. (Nature, vol. 437, 2005, p. 862). Here, we demonstrate how these filaments can be anchored to a wall to make carpets of artificial micro-magnetic cilia with tunable densities. We analyse the dynamics of an artificial cilium under both planar and three-dimensional beating patterns. We show that the dynamics are controlled by a single characteristic length scale varying with the inverse square root of the driving frequency, providing a mechanism to break the fore and aft symmetry and to generate net fluxes and forces. However, we show that an effective geometrical reciprocity in the filament dynamics creates intrinsic limitations upon the ability of the artificial flagellum to pump fluid when driven in two dimensions.",

keywords = "Low-Reynolds-number flows, MEMS/NEMS, swimming/flying",

author = "Avin Babataheri and Marcus Roper and Marc Fermigier and \{Du Roure\}, Olivia",

year = "2011",

month = jul,

day = "10",

doi = "10.1017/S002211201100005X",

language = "English",

volume = "678",

pages = "5--13",

journal = "Journal of Fluid Mechanics",

issn = "0022-1120",

}

TY - JOUR

T1 - Tethered fleximags as artificial cilia

AU - Babataheri, Avin

AU - Roper, Marcus

AU - Fermigier, Marc

AU - Du Roure, Olivia

PY - 2011/7/10

Y1 - 2011/7/10

N2 - Flexible superparamagnetic filaments ('fleximags') are very slender elastic filaments, which can be driven by distributed magnetic torques to mimic closely the behaviour of biological flagella. Previously, fleximags have been used as a basis for artificial micro-swimmers capable of transporting small cargos Dreyfus et al. (Nature, vol. 437, 2005, p. 862). Here, we demonstrate how these filaments can be anchored to a wall to make carpets of artificial micro-magnetic cilia with tunable densities. We analyse the dynamics of an artificial cilium under both planar and three-dimensional beating patterns. We show that the dynamics are controlled by a single characteristic length scale varying with the inverse square root of the driving frequency, providing a mechanism to break the fore and aft symmetry and to generate net fluxes and forces. However, we show that an effective geometrical reciprocity in the filament dynamics creates intrinsic limitations upon the ability of the artificial flagellum to pump fluid when driven in two dimensions.

AB - Flexible superparamagnetic filaments ('fleximags') are very slender elastic filaments, which can be driven by distributed magnetic torques to mimic closely the behaviour of biological flagella. Previously, fleximags have been used as a basis for artificial micro-swimmers capable of transporting small cargos Dreyfus et al. (Nature, vol. 437, 2005, p. 862). Here, we demonstrate how these filaments can be anchored to a wall to make carpets of artificial micro-magnetic cilia with tunable densities. We analyse the dynamics of an artificial cilium under both planar and three-dimensional beating patterns. We show that the dynamics are controlled by a single characteristic length scale varying with the inverse square root of the driving frequency, providing a mechanism to break the fore and aft symmetry and to generate net fluxes and forces. However, we show that an effective geometrical reciprocity in the filament dynamics creates intrinsic limitations upon the ability of the artificial flagellum to pump fluid when driven in two dimensions.

KW - Low-Reynolds-number flows

KW - MEMS/NEMS

KW - swimming/flying

UR - https://www.scopus.com/pages/publications/79960147673

U2 - 10.1017/S002211201100005X

DO - 10.1017/S002211201100005X

M3 - Article

AN - SCOPUS:79960147673

SN - 0022-1120

VL - 678

SP - 5

EP - 13

JO - Journal of Fluid Mechanics

JF - Journal of Fluid Mechanics

ER -

Tethered fleximags as artificial cilia

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this