Suction Flows Generated by the Carnivorous Bladderwort Utricularia—Comparing Experiments with Mechanical and Mathematical Models

Singh, Krizma; Reyes, Roberto C.; Campa, Gabriel; Brown, Matthew; Hidalgo, Fatima; Berg, Otto; Müller, Ulrike K.

doi:10.3390/fluids5010033

Cited by 9 publications

(10 citation statements)

References 65 publications

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“…We recorded 24 suction events for 15 traps of Utricularia gibba (data published in validation of a mechanical model, (Singh et al ., 2020)) and 11 traps of Utricularia australis using PIV to characterise the flow outside the trap (Fig. 1; Table S2), and 14 suction events for 14 traps of U. gibba using particle tracking to characterise the flow inside the channel (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…(e) Flow speed sampled along a semicircular transect as indicated in (a). Lines show model predictions by a creeping‐flow model (Sampson, 1891) and a mechanical model simulating the flow of a bladderwort trap (Singh et al ., 2020) to facilitate comparison, the speed axis of each model curve has been scaled to yield the same flux into the hemispherical cap as calculated from the bladderwort data. (f) Axial transect measurements from 24 traps (points), with distance z scaled by the gape diameter d and speed u normalised to speed at the half‐gape point u d /2 .…”

Section: Methodsmentioning

confidence: 99%

“…Linearised Navier–Stokes equations have been developed for undeveloped steady‐state flow at a circular pipe entrance (Langhaar, 1942). These solutions have been implemented in commercial software (Wolfram Mathematica) (Berg et al ., 2020; Singh et al ., 2020); the energy balance as a function of speed could be solved with the integral values as given (Berg et al ., 2019). To solve for speed as a function of pressure drop the roots of the energy balance were found numerically.…”

Section: Methodsmentioning

confidence: 99%

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Bladderworts, the smallest known suction feeders, generate inertia‐dominated flows to capture prey

et al. 2020

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Aquatic bladderworts (Utricularia gibba and U. australis) capture zooplankton in mechanically triggered underwater traps. With characteristic dimensions less than 1 mm, the trapping structures are among the smallest known to capture prey by suction, a mechanism that is not effective in the creeping-flow regime where viscous forces prevent the generation of fast and energy-efficient suction flows. To understand what makes suction feeding possible on the small scale of bladderwort traps, we characterised their suction flows experimentally (using particle image velocimetry) and mathematically (using computational fluid dynamics and analytical mathematical models). We show that bladderwort traps avoid the adverse effects of creeping flow by generating strong, fast-onset suction pressures. Our findings suggest that traps use three morphological adaptations: the trap walls' fast release of elastic energy ensures strong and constant suction pressure; the trap door's fast opening ensures effectively instantaneous onset of suction; the short channel leading into the trap ensures undeveloped flow, which maintains a wide effective channel diameter. Bladderwort traps generate much stronger suction flows than larval fish with similar gape sizes because of the traps' considerably stronger suction pressures. However, bladderworts' ability to generate strong suction flows comes at considerable energetic expense.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Bladderworts, the smallest known suction feeders, generate inertia‐dominated flows to capture prey

et al. 2020

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“…This is because if the magnitude of the ow velocity around the ori ce is large enough to move the sediment, the sediment can escape out of the pipe with the water, and if the velocity is small, the sediment remains stationary. Singh et al (2020) studied the ow phenomenon that occurs when a pipe sucks in the surrounding uid, which is similar to the phenomenon of an ori ce sucking water in a limestone bed. They presented the velocity distribution when a small pipe sucks in the surrounding uid, as shown in Fig.…”

Section: Evaluation Of Water Ow Rate In Limestone Layermentioning

confidence: 99%

Experimental Study on the Adoption of Flushing Technique in Successive Alkalinity-Producing Systems with a Focus on Influence Radius of Orifice

Lee

Cheong

2021

Preprint

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As a successive alkalinity-producing system pond for purifying mine drainage is operated, sediment accumulates in the limestone layer of the pond, and as the amount of accumulated sediment increases, the water permeability and treatment efficiency of the pond decrease. Hence, a flushing system is required, comprising of a network of perforated pipes installed in the limestone layers, to periodically discharge sediment and mine drainage to the outside. The performance of a flushing system depends on four distinct characteristics of the system: the characteristics of the limestone layer, the sediment, the flow, and the flushing device. However, existing studies have evaluated the performance of the entire system without considering these conditions. In this study, a new experimental method for designing a flushing system is proposed. This method is based on an experiment to evaluate the influence radius of orifice, which is the radius of the spherical volume around an orifice that can suck sludge by flushing. The results showed that the flow rate of water through the orifice in the glass bead layer matched well with the Blake–Kozeny formula, and that the greater the diameter of the orifice, the greater the influence radius of orifice. The influence radius of orifice according to the diameter and spacing of the orifice was evaluated, which provides a key criterion for designing a flushing system.

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“…Models have been developed to understand the extreme biomechanics of latch-mediated spring actuated organisms. Organism-specific models, including both continuum mechanics-based models (2)(3)(4)(5)(6)(7)(8)(9)(10) and physical modeling with biomimetic devices (2,(10)(11)(12)(13)(14), have been used to test hypotheses about the mechanisms of movement in specific organisms (Table 1 summarizes examples of recent work).…”

Section: Introductionmentioning

confidence: 99%

A Tunable, Simplified Model for Biological Latch Mediated Spring Actuated Systems

Cook

Pandhigunta

Acevedo

et al. 2020

Preprint

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We develop a model of latch-mediated spring actuated (LaMSA) systems relevant to comparative biomechanics. The model contains five components: two motors (muscles), a spring, a latch, and a load mass. One motor loads the spring to store elastic energy, and the second motor subsequently removes the latch, which releases the spring and causes movement of the load mass. We develop open-source software to accompany the model, which provides an extensible framework for simulating biological LaMSA systems. Output from the simulation includes information from the loading and release phases of motion, which can be used to calculate kinematic performance metrics that are important for biological function. By rapidly iterating through biologically relevant input parameters to the model, simulated changes in kinematic performance can be used to explore the evolutionary dynamics of biological LaMSA systems.SIGNIFICANCEIn this work, we provide an example of a simple and extensible modeling framework that is grounded in physical principles. This framework enables both the rapid testing of ideas and the flexibility of tuning the model to a specific biological system. The model and open-source software can be used to explore questions in comparative biomechanics related to spring actuated movements.

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Suction Flows Generated by the Carnivorous Bladderwort Utricularia—Comparing Experiments with Mechanical and Mathematical Models

Cited by 9 publications

References 65 publications

Bladderworts, the smallest known suction feeders, generate inertia‐dominated flows to capture prey

Bladderworts, the smallest known suction feeders, generate inertia‐dominated flows to capture prey

Experimental Study on the Adoption of Flushing Technique in Successive Alkalinity-Producing Systems with a Focus on Influence Radius of Orifice

A Tunable, Simplified Model for Biological Latch Mediated Spring Actuated Systems

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