Through experiments, we idealize a plant leaf as a flexible, thin, rectangular plate clamped at the midpoint and positioned perpendicular to an airflow. Flexibility of the structure is considered as an advantage at moderate flow speed because it allows drag reduction by elastic reconfiguration, but it can also be at the origin of several flow-induced vibration phenomena at higher flow speeds. A wind tunnel campaign is conducted to identify the limitation to elastic reconfiguration that dynamic instability imposes. Here, we show by increasing the flow speed that the flexibility permits a considerable drag reduction by reconfiguration, compared to the rigid case. However, beyond the stability limit, vibrations occur and limit the reconfiguration. This limit is represented by two dimensionless numbers: the mass number and the Cauchy number. Our results reveal the existence of a critical Cauchy number below which static reconfiguration with drag reduction is possible and above which a dynamic instability with important fluctuating loads is present. The critical dimensionless velocity is dependent on the mass number. Flexibility is related to the critical reduced velocity and allows defining an optimal flexibility for the structure that leads to a drag reduction by reconfiguration while avoiding dynamic instability. Furthermore, experiments show that our flexible structure can exhibit two vibration modes: symmetric and anti-symmetric, depending on its mass number. Because the system we consider is bluff yet aligned with the flow, it is unclear whether the vibrations are due to a flutter instability or vortex-induced vibration or a combination of both phenomena.

1.
S.
Vogel
,
Life in Moving Fluids: The Physical Biology of Flow-Revised and Expanded
, 2nd ed. (
Princeton University Press
,
2020
).
2.
F.
Gosselin
,
E.
de Langre
, and
B. A.
Machado-Almeida
, “
Drag reduction of flexible plates by reconfiguration
,”
J. Fluid Mech.
650
,
319
341
(
2010
).
3.
S.
Alben
,
M.
Shelley
, and
J.
Zhang
, “
Drag reduction through self-similar bending of a flexible body
,”
Nature
420
(
6915
),
479
481
(
2002
).
4.
S.
Vogel
, “
Drag and flexibility in sessile organisms
,”
Am. Zool.
24
(
1
),
37
44
(
1984
).
5.
E.
de Langre
, “
Effects of wind on plants
,”
Annu. Rev. Fluid Mech.
40
,
141
168
(
2008
).
6.
D. L.
Harder
,
O.
Speck
,
C. L.
Hurd
, and
T.
Speck
, “
Reconfiguration as a prerequisite for survival in highly unstable flow-dominated habitats
,”
J. Plant Growth Regul.
23
,
98
107
(
2004
).
7.
S.
Vogel
, “
Drag and reconfiguration of broad leaves in high winds
,”
J. Exp. Bot.
40
(
8
),
941
948
(
1989
).
8.
T.
Leclercq
,
N.
Peake
, and
E.
de Langre
, “
Does flutter prevent drag reduction by reconfiguration?
,”
Proc. R Soc. A
474
(
2209
),
20170678
(
2018
).
9.
C.
Eloy
,
C.
Souilliez
, and
L.
Schouveiler
, “
Flutter of a rectangular plate
,”
J. Fluids Struct.
23
(
6
),
904
919
(
2007
).
10.
C.
Eloy
,
R.
Lagrange
,
C.
Souilliez
, and
L.
Schouveiler
, “
Aeroelastic instability of cantilevered flexible plates in uniform flow
,”
J. Fluid Mech.
611
,
97
106
(
2008
).
11.
G.
Foggi Rota
,
M.
Koseki
,
R.
Agrawal
,
S.
Olivieri
, and
M. E.
Rosti
, “
Forced and natural dynamics of a clamped flexible fiber in wall turbulence
,”
Phys. Rev. Fluids
9
(
1
),
L012601
(
2024
).
12.
D.
Kim
,
J.
Cossé
,
C.
Huertas Cerdeira
, and
M.
Gharib
, “
Flapping dynamics of an inverted flag
,”
J. Fluid Mech.
736
,
R1
(
2013
).
13.
M.
Tavallaeinejad
,
M. P.
Païdoussis
,
M. F.
Salinas
,
M.
Legrand
,
M.
Kheiri
, and
R. M.
Botez
, “
Flapping of heavy inverted flags: A fluid-elastic instability
,”
J. Fluid Mech.
904
,
R5
(
2020
).
14.
J. W.
Park
,
J.
Ryu
, and
H. J.
Sung
, “
Effects of the shape of an inverted flag on its flapping dynamics
,”
Phys. Fluids
31
(
2
),
021904
(
2019
).
15.
R.
Padilla
,
V.
Durgesh
,
T.
Xing
, and
A.
Nawafleh
, “
Experimental study of flag fluid–structure interaction in a laminar jet and application of POD
,”
J. Fluids Struct.
125
,
104040
(
2024
).
16.
Y.
Jin
,
J.-T.
Kim
,
S.
Fu
, and
L. P.
Chamorro
, “
Flow-induced motions of flexible plates: Fluttering, twisting and orbital modes
,”
J. Fluid Mech.
864
,
273
285
(
2019
).
17.
L.
Schouveiler
and
C.
Eloy
, “
Coupled flutter of parallel plates
,”
Phys. Fluids
21
(
8
),
081703
(
2009
).
18.
J. E.
Sader
,
J.
Cossé
,
D.
Kim
,
B.
Fan
, and
M.
Gharib
, “
Large-amplitude flapping of an inverted flag in a uniform steady flow—A vortex-induced vibration
,”
J. Fluid Mech.
793
,
524
555
(
2016
).
19.
R. D.
Blevins
,
Flow-Induced Vibration
(
Van Nostrand Reinhold Company
,
New York
,
1977
).
20.
B. Y.
Ballal
, “
Vibrations of rectangular plates
,” Ph.D. thesis (
Rice University
,
1966
).
21.
S.
Alben
, “
The flapping-flag instability as a nonlinear eigenvalue problem
,”
Phys. Fluids
20
(
10
),
104106
(
2008
).
22.
S.
Michelin
,
S. G.
Llewellyn Smith
, and
B. J.
Glover
, “
Vortex shedding model of a flapping flag
,”
J. Fluid Mech.
617
,
1
10
(
2008
).
23.
D.
Lopez
,
C.
Eloy
,
S.
Michelin
, and
E.
de Langre
, “
Drag reduction, from bending to pruning
,”
Europhys. Lett.
108
(
4
),
48002
(
2014
).
24.
S.
Vogel
,
Glimpses of Creatures in Their Physical Worlds
(
Princeton University Press
,
2009
).
You do not currently have access to this content.