An ecological perspective on water shedding from leaves

Lenz, Anne-Kristin; Bauer, Ulrike; Ruxton, Graeme D.

doi:10.1093/jxb/erab479

Cited by 17 publications

(11 citation statements)

References 149 publications

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“…The off-centre axis of bending restricts the possible direction of movement to the pure up–down pivoting that is essential for ‘springboard' trapping [ 12 ]. Impact-induced oscillations are not unique to N. gracilis lids, but occur in all leaves, where they aid water shedding (reviewed in [ 14 ]) and thereby the dispersal of contaminants and pathogen spores [ 15 ]. In contrast to the clean pivoting of the N. gracilis lid, most leaves show a complex mixture of flapping, bending and twisting [ 16 ].…”

Section: Discussionmentioning

confidence: 99%

Pitcher geometry facilitates extrinsically powered ‘springboard trapping' in carnivorousNepenthes gracilispitcher plants

Lenz

Bauer

2022

Biol. Lett.

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Carnivorous pitcher plants capture insects in cup-shaped leaves that function as motionless pitfall traps. Nepenthes gracilis evolved a unique ‘springboard' trapping mechanism that exploits the impact energy of falling raindrops to actuate a fast pivoting motion of the canopy-like pitcher lid. We superimposed multiple computed micro-tomography images of the same pitcher to reveal distinct deformation patterns in lid-trapping N. gracilis and closely related pitfall-trapping N. rafflesiana . We found prominent differences between downward and upward lid displacement in N. gracilis only. Downward displacement was characterized by bending in two distinct deformation zones whist upward displacement was accomplished by evenly distributed straightening of the entire upper rear section of the pitcher. This suggests an anisotropic impact response, which may help to maximize initial jerk forces for prey capture, as well as the subsequent damping of the oscillation. Our results point to a key role of pitcher geometry for effective ‘springboard' trapping in N. gracilis .

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Section: Discussionmentioning

confidence: 99%

Pitcher geometry facilitates extrinsically powered ‘springboard trapping' in carnivorousNepenthes gracilispitcher plants

Lenz

Bauer

2022

Biol. Lett.

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“…Upon impact, raindrops shatter on vegetative surfaces producing multiple, smaller residual drops, and these residual drops continue to fall to the ground or impact additional vegetative surfaces below before reaching the ground (Levia et al, 2019; Nanko et al, 2022; Papierowska et al, 2019). Additionally, a proportion of the smaller residual drops produced after raindrops shatter on vegetative surfaces can adhere to leaf surfaces contributing to the leaf surface storage (Lenz et al, 2022; Wohlfahrt et al, 2006; Xiong et al, 2019). Leaf surface storage is the maximum amount of water retained on a leaf divided by the all‐sided surface area of the leaf (Holder, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Leaf surface storage is the maximum amount of water retained on a leaf divided by the all‐sided surface area of the leaf (Holder, 2013). The water contributing to leaf surface storage can be lost to evaporation, absorbed into the leaf, or contribute to throughfall or stemflow as the smaller water drops on leaf surfaces coalesce to form larger water drops and move off the leaf (Cavallaro et al, 2022; Lenz et al, 2022; Nanko et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Progression toward maximum leaf surface storage during the rainfall interception process

Holder,

Lauderbaugh

2023

Hydrological Processes

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During rainfall events, leaves in the canopy absorb kinetic energy from falling raindrops causing the leaves to vibrate after each individual drop impact. Additionally, intercepted water gradually increases on foliar surfaces adding greater mass exerted on each leaf. This accumulated mass of water increases the leaf inclination angle and may enable the drainage of water from the leaf surface as the water drop retention angle is surpassed. This study explored the dynamic process of leaf vibration and changes in steady‐state leaf inclination angles after raindrop impact for three species (Acer saccharinum, Quercus gambelii, and Ulmus pumila) and with four different drop sizes. An incremental increase in steady‐state leaf inclination angle was measured from processing single frames of videos as each additional raindrop impacted leaf surfaces. In general, larger drops increased leaf inclination angles to a larger degree than the smaller drops. As maximum leaf surface storage or the water drop retention angle was approached, water drained from leaf surface causing an abrupt rebound of the leaf inclination angle. The maximum changes in steady‐state leaf inclination angle before rebound (LIAmax) and the number of drops needed for leaf inclination angle rebound were significantly correlated with the initial leaf inclination angle (LIAi) for experiments with A. saccharinum and U. pumila, but not for the experiments with Q. gambelii. No significant correlations were found between LIAmax and any leaf trait (i.e., leaf area, leaf mass, petiole length, petiole diameter, leaf hydrophobicity, and water drop retention) for A. saccharinum and U. pumila; however, a significant negative correlation was found for Q. gambelii between maximum changes in leaf inclination angle and petiole diameter. Of the leaf characteristics examined, leaf surface storage is most influenced by LIAi before drop impact.

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“…Interfacial properties such as wettability are fundamental features of surfaces. Wettability is crucial for many processes in nature [1][2][3] and for many technical applications, such as the separations of emulsions. [4][5][6] The wettability of a given surface is typically evaluated by (static) contact angle measurements, where often water is used as a probe liquid.…”

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Optical and chemical control of the wettability of nanoporous photoswitchable films

et al. 2022

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An ecological perspective on water shedding from leaves

Cited by 17 publications

References 149 publications

Pitcher geometry facilitates extrinsically powered ‘springboard trapping' in carnivorousNepenthes gracilispitcher plants

Pitcher geometry facilitates extrinsically powered ‘springboard trapping' in carnivorousNepenthes gracilispitcher plants

Progression toward maximum leaf surface storage during the rainfall interception process

Optical and chemical control of the wettability of nanoporous photoswitchable films

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