As anyone who has experienced turbulence knows, its onset and departure are abrupt, and how long it lasts seems to be unpredictable. Fast flowing fluids are always turbulent, but at slower speeds the flow transitions to smooth and predictable (laminar) with intermittent patches of turbulence. In the human body, transitional turbulence can be deadly. Near the transition to turbulence, violent oscillations between laminar and turbulent blood flow can lead to aneurisms that rupture the arteries in the heart.
How does transitional turbulence die away? And what controls its lifetime? These questions have perplexed scientists ever since the first experiments were performed in 1883.
Now, physicist Nigel Goldenfeld, graduate student Hong-Yan Shih, and former undergraduate student Tsung-Lin Hsieh at the Univ. of Illinois at Urbana-Champaign have developed a theoretical understanding of this laminar-turbulent transition that explains the lifetime of turbulent flows.
In this work, the researchers started from the most detailed and fundamental equations of fluid flow in a pipe, but they discovered that near the transition, most of the complexity was not important. In fact, to explain and reproduce through computer simulation the most precise experiments ever done on the laminar-turbulent transition, they found that only two classes of fluid motion were needed: a swirling vortex mode around the axis of the pipe and random, irregular fluctuations in the center of the pipe. To the researchers’ surprise, these modes behaved like predators and prey in an ecosystem on the verge of extinction: the time for the predators and prey to die out corresponded to the lifetime of the transitional turbulence state.
The Illinois researchers approached the problem not by thinking about fluid mechanics, but by thinking about phase transitions—the complex phenomena that occur when matter changes its state to become ordered. Examples include the formation of magnets, the formation of ice crystals from water, or even the ordering that occurred when the Universe cooled after the Big Bang, leading to the formation of all known matter. By regarding the turbulence transition as being like a phase transition, they were able to utilize conceptual and mathematical techniques not usually considered in the context of fluid flow, such as methods from modern statistical mechanics and even population biology.
The article was published online in Nature Physics.
Goldenfeld explains, “In physics, we often make use of minimal descriptions of collective behavior, stripping away details of individual particles. So, if we were trying to understand the orbit of the planet Mars around the Sun, we can pretend the planet is a point—a particle with no structure—and then it is quite simple to describe what is actually going on. The transition from laminar flow to turbulence involves very complicated phenomena, most of which aren’t important. Producing a simpler model is useful, because we are not blinded by all of the complexities of the phenomenon.”
The transition between laminar and turbulent flow was first mentioned by Osborne Reynolds in a classic experiment published in 1883. Since then, various measurements have been made of the lifetime of turbulence, but the huge range over which the turbulence lifetime varies created insuperable experimental difficulties. In 2008, Björn Hof and colleagues at the Max Planck Institute in Göttingen, Germany, made a breakthrough, developing an ingenious and very sensitive technique to study how long turbulent phases persist. These results quantified how the lifetime of turbulence varied so strongly with the fluid flow speed, defying theoretical understanding at first. The Illinois researchers were able to account for the detailed results from these experiments and to show that similar phenomena are predicted to occur near the extinction of predator-prey ecosystems.
The Illinois group had clues from their work on population biology and nonlinear dynamics about the ecosystem to pipe turbulence analogy, but it was not until Tsung-Lin Hsieh, at that time an undergraduate, was able to perform detailed computer simulations of fluid flow in a pipe that the specific details became clear.
Goldenfeld notes, “Tsung-Lin used a wonderful open-source code written by British mathematician Ashley Willis to run computer simulations of pipe flow. We were looking for a collective mode, and we found it.”
The computer simulations showed that at the center of the pipe, the flow travels mainly along the axis of the pipe, as one might expect, but with large fluctuations. But around the interior edge of the pipe, the Illinois group discovered what is known as a large-scale zonal flow—a large vortex, similar to the jet stream circling around the Earth. They found that the turbulence excites the zonal flow, but the zonal flow inhibits the turbulence. So the turbulence builds up gradually, creating the zonal flow. When the zonal flow is sufficiently strong, it sweeps the turbulence up, thus reducing the turbulence. With reduced turbulence, the zonal flow itself begins to die, allowing the turbulence to build up, and thus begin a new cycle. The resulting behavior is an oscillation in the intensity of turbulence, mathematically similar to the population oscillations seen in ecology.
“The analogy of this type of system to laminar-turbulence oscillations provides a simpler, minimal model to study. The fluctuating turbulence is analogous to the prey population, and the zonal flow is like the predator population,” Shih explains.“The parallels between these oscillations in pipe flow and predator-prey dynamics in biological systems were a big surprise to us. In our group, we also study biological problems, so it was interesting that we could apply the methods of biology to the problem of turbulence.”
From this discovery, the researchers were able to construct the simplest ecological model that possessed all the symmetries of the fluid interactions. Hong-Yan Shih developed a computer program that simulated predator-prey dynamics near extinction, building on her earlier research on ecological and evolutionary dynamics. She confirmed that the ecosystem dynamics precisely mimics the mathematical behavior found experimentally in the laminar-turbulence transition in pipe flow.
The Illinois researchers also showed that near the transition, their simple ecological model is mathematically equivalent to an even simpler model that had been suspected to describe the laminar-turbulent transition. In this model, known as directed percolation, particles hop on a disordered lattice, rather like water percolating downwards under the influence of gravity in a coffee machine. Whether or not they can pass from one side of the lattice to the other depends on the disorder, such as the compactness of the coffee grains in the espresso machine. At the point when the particles can no longer get through, the system is behaving mathematically like the transition in turbulence, as indicated in earlier computer experiments by Maksim Sipos and Nigel Goldenfeld. The new results establish that this is not an accident and applies to both turbulence and ecology.
Turbulence is important economically, because it creates much more frictional drag than laminar flow, making transport of oil and other fluids through pipelines expensive and energy intensive. The Illinois researchers hope that their work might lead to an improved understanding of how the onset of turbulence can be controlled, thus potentially reducing energy costs in oil pipelines. The work may also have implications for cardiovascular medicine, perhaps reducing the risk of aneurisms.