TY - JOUR
T1 - Evaporating droplets on inclined plant leaves and synthetic surfaces
T2 - Experiments and mathematical models
AU - Tredenick, Eloise C.
AU - Forster, W. Alison
AU - Pethiyagoda, Ravindra
AU - van Leeuwen, Rebecca M.
AU - McCue, Scott W.
N1 - Funding Information:
Experimental components were performed at , Rotorua, New Zealand. The authors gratefully acknowledge support from the Australian Research Council through the ARC Linkage Project (LP160100707) and the associated industry partners Syngenta and Nufarm.
Publisher Copyright:
© 2021 Elsevier Inc.
PY - 2021/6/15
Y1 - 2021/6/15
N2 - Hypothesis: Evaporation of surfactant droplets on leaves is complicated due to the complex physical and chemical properties of the leaf surfaces. However, for certain leaf surfaces for which the evaporation process appears to follow the standard constant-contact-radius or constant-contact-angle modes, it should be possible to mimic the droplet evaporation with both a well-chosen synthetic surface and a relatively simple mathematical model. Experiments: Surfactant droplet evaporation experiments were performed on two commercial crop species, wheat and capsicum, along with two synthetic surfaces, up to a 90° incline. The time-dependence of the droplets’ contact angles, height, volume and contact radius was measured throughout the evaporation experiments. Mathematical models were developed to simulate the experiments. Findings: With one clear exception, for all combinations of surfaces, surfactant concentrations and angles, the experiments appear to follow the standard evaporation modes and are well described by the mathematical models (modified Popov and Young–Laplace-Popov). The exception is wheat with a high surfactant concentration, for which droplet evaporation appears nonstandard and deviates from the diffusion limited models, perhaps due to additional mechanisms such as the adsorption of surfactant, stomatal density or an elongated shape in the direction of the grooves in the wheat surface.
AB - Hypothesis: Evaporation of surfactant droplets on leaves is complicated due to the complex physical and chemical properties of the leaf surfaces. However, for certain leaf surfaces for which the evaporation process appears to follow the standard constant-contact-radius or constant-contact-angle modes, it should be possible to mimic the droplet evaporation with both a well-chosen synthetic surface and a relatively simple mathematical model. Experiments: Surfactant droplet evaporation experiments were performed on two commercial crop species, wheat and capsicum, along with two synthetic surfaces, up to a 90° incline. The time-dependence of the droplets’ contact angles, height, volume and contact radius was measured throughout the evaporation experiments. Mathematical models were developed to simulate the experiments. Findings: With one clear exception, for all combinations of surfaces, surfactant concentrations and angles, the experiments appear to follow the standard evaporation modes and are well described by the mathematical models (modified Popov and Young–Laplace-Popov). The exception is wheat with a high surfactant concentration, for which droplet evaporation appears nonstandard and deviates from the diffusion limited models, perhaps due to additional mechanisms such as the adsorption of surfactant, stomatal density or an elongated shape in the direction of the grooves in the wheat surface.
KW - Capsicum
KW - Evaporation
KW - Incline
KW - Mathematical model
KW - Parafilm
KW - Sessile droplet
KW - Surfactant
KW - Teflon
KW - Wheat
KW - Young–Laplace equation
UR - http://www.scopus.com/inward/record.url?scp=85103683996&partnerID=8YFLogxK
U2 - 10.1016/j.jcis.2021.01.070
DO - 10.1016/j.jcis.2021.01.070
M3 - Article
C2 - 33676194
AN - SCOPUS:85103683996
SN - 0021-9797
VL - 592
SP - 329
EP - 341
JO - Journal of Colloid and Interface Science
JF - Journal of Colloid and Interface Science
ER -