Wednesday, May 14, 2025

Flamingos create water tornados to trap their prey

Stomp dancing, head jerking, chattering and skimming generate whorls and eddies that funnel brine shrimp and small animals into the birds’ mouths

University of California - Berkeley

Flamingos create water vortices to capture prey — image:
Flamingos feed by dragging their flattened beaks forward along the bottom of shallow lakes. To increase the efficiency of feeding, they stomp dance to churn the bottom, create an upwelling vortex with their heads and clap their beaks constantly to draw food, like brine shrimp, into their mouths.
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Credit: Aztli Ortega

Flamingos standing serenely in a shallow alkaline lake with heads submerged may seem to be placidly feeding, but there's a lot going on under the surface.

Through studies of Chilean flamingos in the Nashville Zoo and analysis of 3D printed models of their feet and L-shaped bills, researchers have documented how the birds use their feet, heads and beaks to create a storm of swirling tornados, or vortices, in the water to efficiently concentrate and slurp up their prey.

"Flamingos are actually predators, they are actively looking for animals that are moving in the water, and the problem they face is how to concentrate these animals, to pull them together and feed," said Victor Ortega Jiménez, an assistant professor of integrative biology at the University of California, Berkeley, who specializes in biomechanics. "Think of spiders, which produce webs to trap insects. Flamingos are using vortices to trap animals, like brine shrimp."

Ortega Jiménez and collaborators at the Georgia Institute of Technology in Atlanta; Kennesaw State University in Marietta, Georgia (KSU-Marietta); and the Nashville Zoo will publish their findings this week in the journal Proceedings of the National Academy of Sciences.

The researchers found that flamingos use their floppy webbed feet to churn up the bottom sediment and propel it forward in whorls that the birds then draw to the surface by jerking their heads upward like plungers, creating mini tornados. All the while, the birds’ heads remain upside down within the watery vortex, their angled beaks chattering to create smaller vortices that direct the sediment and food into their mouths, where it's strained out.

The beak of a flamingo is unique in being flattened on the angled front end, so that when the bird’s head is upside down in the water, the flat portion is parallel to the bottom. This allows the flamingo to employ another technique called skimming. This involves using its long, S-shaped neck to push its head forward while rapidly clapping its beak, creating sheet-like vortices — von Kármán vortices — that trap prey.

This suite of active feeding behaviors belie the flamingo's reputation as a passive filter feeder, Ortega Jiménez said.

"It seems like they are filtering just passive particles, but no, these animals are actually taking animals that are moving," he said.

The principles he discovered could be used to design better systems for concentrating and sucking up tiny particles, such as microplastics, from water; better self-cleaning filters, based on chattering; or robots that, like flamingos, can walk and run in mud.

Chattering

Ortega Jiménez, a native of Puebla, Mexico, became fascinated with the feeding behavior of flamingos during a visit to Zoo Atlanta with his wife and daughter before the COVID-19 pandemic. Filming the birds' feeding behavior, he observed only ripples on the surface.

"We don't know anything about what is happening inside. That was my question," he said.

At the time a postdoctoral fellow at Kennesaw State University in Georgia, Ortega Jiménez focused on flamingo feeding as his next research project. He views himself, he said, as a modern-day Darwinian naturalist, investigating the behavior of animals of all types, from nematodes and flies to springtails and birds, focusing on how the animals interact with and manipulate their surroundings, including air, water and electromagnetic fields.

From Kennesaw State he moved to the Georgia Institute of Technology to work in the lab of Saad Bhamla, where he collaborated with engineers, and they gained access to Chilean flamingos at the Nashville Zoo. The team filmed them feeding in a large tray, using a laser to illuminate gas bubbles in the water in order to see the vortices created by the heads and beaks of the animals.

After moving to the University of Maine in Orono as an assistant professor, Ortega Jiménez refined 3D printed models of a flamingo beak and foot to study more precisely the movement of water and particles during the beak clapping, or "chattering," that the birds use when eating.

In 2024, he moved again, to UC Berkeley, where he conducted experiments to see how effective the chattering and foot stomping was in capturing live brine shrimp. The new paper summarizes all of this collaborative work.

At UC Berkeley, he attached a real flamingo beak to an actuator to simulate chattering and added a small pump in the mouth to simulate the tongue and suck up the brine shrimp captured by the mouth. With this setup, he was able to establish that chattering is key to flamingo feeding.

"The chattering actually is increasing seven times the number of brine shrimp passing through the tube," he said. "So it's clear that the chattering is enhancing the number of individuals that are captured by the beak."

Stomp Dancing

The feeding behavior begins with the feet, Ortega Jiménez said. If you look at a flamingo in very shallow water, you can often see its dancing-in-place or circular dancing behavior.

The feet are webbed, but as with many wading birds, they are floppy, so that when the bird lifts a foot, the webbing collapses and comes away from the bottom without the suction that makes it hard for humans to walk in mud. When walking or running, flamingos seem to slide their feet into the water instead of stomping, a technique that could help robots walk in water or mud.

Ortega Jiménez created models of both rigid and flexible flamingo feet to compare how the two designs affect fluid flow, and he found that the floppy feet are much more effective at pushing vortices of sediment out in front of each step. Rigid webbing primarily produces turbulence.

Creating a 3D model of the L-shaped beak, he was able to show that pulling the head straight upward in the water creates a vortex swirling around a vertical axis, again concentrating particles of food. He measured the head speed at about 40 centimeters per second (1.3 feet per second). The small tornados were strong enough to entrap even agile invertebrates, such as brine shrimp and the microscopic crustaceans called copepods.

Chattering also creates vortices around the beak. In this case, the flamingo keeps its upper beak stationary, though it is capable of independent motion, and moves only the lower beak — about 12 times per second during chattering, Ortega Jiménez discovered.

Tien Yee, a co-author of the paper and a professor at KSU-Marrieta, employed computational fluid dynamics to simulate on a computer the 3D flow around the beak and the feet. He confirmed that the vortices do indeed concentrate particles, similar to experiments using a 3D-printed head in a flume with both actively swimming brine shrimp and passively floating brine shrimp eggs.

"We observed when we put a 3D printed model in a flume to mimic what we call skimming, they are producing symmetrical vortices on the sides of the beak that recirculate the particles in the water so they actually get into the beak," Ortega Jiménez said. "It's this trick of fluid dynamics."

His next projects are to determine the role of the flamingo's piston-like tongue and how the comb-like edges of the beak filter prey out of briny and sometimes toxic water.

"Flamingos are super-specialized animals for filter feeding," he said. "It's not just the head, but the neck, their legs, their feet and all the behaviors they use just to effectively capture these tiny and agile organisms."

In addition to Yee, other co-authors of the paper are postdoctoral fellow Pankaj Rohilla, graduate student Benjamin Seleb and Professor Saad Bhamla at Georgia Tech; and Jake Belair of the Nashville Zoo in Tennessee. The work was supported by grants from the National Science Foundation (NSF CAREER iOS-1941933), and the Open Philanthropy Project to Bhamla, and from the University of Maine and UC Berkeley to Ortega Jiménez.

A Chilean flamingo feeding in shallow water.

Chilean flamingo.

Credit

Victor Ortega Jiménez, UC Berkeley

Journal

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2503495122

Method of Research

Experimental study

Subject of Research

Animals

Article Title

Flamingos use their L-shaped beak and morphing feet to induce vortical traps for prey capture

Article Publication Date

12-May-2025

FFAR taps Danforth Center plant scientists for crop research to preserve soil and water health

Research aims to optimize yield and reduce production costs

Donald Danforth Plant Science Center

ST. LOUIS, MO, May 12, 2025 — The Foundation for Food & Agriculture Research (FFAR) and matching funders today awarded two Seeding Solutions grants totaling over $5 million to the Donald Danforth Plant Science Center (Danforth Center) for crop development research.

FFAR, the Danforth Center, Kansas State University, The Land Institute, the Perennial Agriculture Project and Saint Louis University provided $2,926,098 to a project accelerating the domestication of perennial crops, which are planted once and harvested over several growing seasons. Additionally, FFAR, the Danforth Center, Pennsylvania State University and Valent BioSciences LLC awarded $2,196,825 for research extending the root system of corn to improve synthetic fertilizer efficiency and preserve soil and water health.

“These projects open opportunities for farmer income growth and lower consumer costs by developing efficient, high-performing agricultural systems,” said Dr. Kathy Munkvold, FFAR scientific program director.

The grantees include:

Allison Miller, PhD, Member, Danforth Center; Professor, Saint Louis University

Farming annual crops, like wheat and corn, requires high input costs and can degrade soil over time. Perennial crops, however, have deep roots that can lower farming costs by conserving nutrients and water. Still, few herbaceous perennial species have been domesticated for large-scale agricultural production. Together with collaborators, Miller aims to optimize and expedite the domestication of perennials by developing strategies for screening potential breeding candidates at early life stages. This research team is screening plants at early stages of their lifespan—seeds and seedlings—using genetics and spectral traits separately and in combination to learn which method creates the largest gains in targeted traits and yield. This team is conducting this research on perennial crops in pre-breeding stages—wild species with limited or no breeding—and those in more advanced stages of domestication to establish if the stage of domestication influences a screening method’s success.

“For more than 40 years, perennial alternatives to major grains and legumes have been recognized for their potential to feed people and, through their deep, persistent roots, to provide critical ecosystem services to agricultural lands,” said Miller. “Although perennial herbaceous species are abundant in nature, they were not domesticated by early farmers. This project builds on previous work where we demonstrated that spectral data taken on seeds and seedlings can be used to predict performance of these promising emerging crops. Building on that success, the current project aims to further hone perennial grain development, with the goal of broadening the diversity of species entering the domestication pipeline and shortening the time it takes to develop new crops that benefit people and the planet.”

Christopher Topp, PhD, Member, Danforth Center

Industrial farming relies on large applications of synthetic nitrogen fertilizer. However, a significant portion of fertilizer is not used by the plants, which costs producers money and can affect soil and water health. Topp and his team are exploring the impacts of deep rooted corn, and the symbiotic relationship between corn and arbuscular mycorrhizal fungi, both of which can increase the reach of corn roots. The research team is leveraging unique genetics controlling root system architecture and fungal-corn interactions, including the use of wild corn relatives to optimize root systems for greater nitrogen uptake, increasing yield. The research results can increase producer profits through greater yield and lower input costs, while also improving farmland health.

“This project is born out of a nearly decade-long collaboration with Valent BioSciences to study the interactions of corn roots and mycorrhizal fungi, which are ubiquitous and abundant in agricultural soils,” said Topp. “We have strong preliminary evidence that increasing rooting depth and interactions with mycorrhizal fungi can, separately, capture more nitrogen and increase grain production. This new support from FFAR and Valent BioSciences will allow us to scale the analysis up and test the potential combinatorial effects of deep roots and arbuscular mycorrhizal fungi. We aim to develop nitrogen-smart root systems that leverage natural biological processes to improve the efficiency of crop nitrogen nutrition that will boost yield and reduce input costs, all with fewer environmental downsides.”

About the Donald Danforth Plant Science Center
Founded in 1998, the Donald Danforth Plant Science Center is a nonprofit research institute with a
mission to improve the human condition through plant science. Research, education and outreach
aim to have an impact at the nexus of food security and the environment, and position the St. Louis
region as a world center for plant science. The Center’s work is funded through competitive grants
from many sources, including the National Science Foundation, National Institutes of Health, U.S.
Department of Energy, the Gates Foundation and through the support of individuals and
corporations. Learn more at danforthcenter.org

Media Contacts:
Danforth Plant Science Center, Karla Roeber, kroeber@danforthcenter.org
FFAR, Ryan Conley, rconley@foundationfar.org

Images available upon request

A cost-efficient and equitable facility location problem for public service

Beijing Zhongke Journal Publising Co. Ltd.

The cost-efficient and equitable facility location problem (CEEFLP) — image:
The mathematical model is easy to understand, effective in application, relatively simple to solve, and outperforms the existing equitable location approaches. This model can also be easily extended for other planning scenarios. Image credit: the authors.
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Credit: Beijing Zhongke Journal Publising Co. Ltd.

This study is led by Dr. Yunfeng Kong from the Faculty of Geographical Science and Engineering at Henan University. Dr. Kong and his team are dedicated to geospatial optimization research, focusing on mathematical models, intelligent algorithms, and applications for vehicle routing, facility location planning, and geographic districting. One of their latest research contributions, the Cost-Efficient and Equitable Facility Location Problem (CEEFLP), provides spatially equitable solutions for public service planning.

Delivering quality services in a cost-efficient and equitable manner is critical to the general public. However, according to Dr. Kong, balancing facility costs, travel efficiency, and spatial equity in location planning remains both theoretically and practically challenging. Existing equitable location models are often highly complex, conflict with travel convenience, and/or are computationally intractable.

Dr. Kong and his graduate students proposed a novel location problem to balance travel efficiency and spatial equity in 2023 and extended the model to include facility cost in 2024. “Theoretically, the CEEFLP is a three-objective optimization problem that minimizes facility cost, travel distance, and spatial inequity. We simplified the problem into a bi-objective optimization by combining travel distance and the spatial inequity indicator. Furthermore, we solved the problem by converting the cost objective into a cost constraint,” said Dr. Kong

The effectiveness of the CEEFLP was tested using four well-known benchmark instances, five author-generated instances and five real-world urban and rural instances. Their experimental results demonstrate that the proposed model effectively balances facility cost, travel cost, and spatial equality in site-selection of facilities. Two key findings emerge from the Pareto-optimal solutions: Increasing the facility cost budget can simultaneously reduce travel costs and improve spatial equality. Once the facility cost budget is determined, all spatial equality indicators can be improved with only a slight increase in mean travel distance.

The authors claim that the CEEFLP is easy to understand, effective in application, relatively simple to solve, and outperforms the existing equitable location approaches, making it a valuable tool for public service planning applications.

Six location planning outcomes for an urban area using different location models

In the six location planning outcomes, each cross symbol represents the location of a service facility, and the colored polygon surrounding the facility represents its service area. Outcome (e) presents the most cost-efficient and equitable solution. Image credit: the authors.