Monday, August 18, 2025

Elegant theory predicts the chaos created by bubbles

Scientists uncover classic turbulence in swarms of rising gas swarms

Helmholtz-Zentrum Dresden-Rossendorf

image:
High-speed cameras capture swarms of bubbles rising through an LED-illuminated water column, revealing the chaotic flow patterns of bubble-induced turbulence.
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Credit: B. Schröder/HZDR

A team of international researchers from the Helmholtz-Zentrum Dresden-Rossendorf (HZDR), Johns Hopkins University and Duke University has discovered that a century-old theory describing turbulence in fluids also applies to a very bubbly problem: how rising bubbles stir the water around them. Their experiments, which tracked individual bubbles and fluid particles in 3D, provide the first direct experimental evidence that so-called ”Kolmogorov scaling“ can emerge in bubble-induced turbulence. The results were published in Physical Review Letters (DOI: 10.1103/v9mh-7pw1).

Bubble-induced turbulence happens in many places: from carbonated drinks to industrial mixing processes to the crashing ocean waves. When enough bubbles rise through a fluid, their wakes stir the surrounding liquid into a complex, turbulent motion. Understanding the rules behind this chaos is essential for improving industrial designs, climate models, and more. Yet, a central question has long puzzled researchers: Can the mathematical theory of turbulence derived by Russian mathematician Andrey Kolmogorov in 1941 – known as ”K41 scaling“ – apply to flows where bubbles drive the motion? Until now, conflicting experimental and computer simulation results made the answer unclear.

”We wanted to get a definitive answer by looking closely at the turbulence between and around bubbles, at very small scales,” says Dr. Tian Ma, lead author of the study and physicist at the Institute of Fluid Dynamics at HZDR. To achieve that, the researchers used advanced 3D simultaneous Lagrangian tracking of both phases – a technique that allows scientists to follow both bubbles and tiny tracer particles in the surrounding water with high precision and in real time. The experimental setup involved an 11.5 cm-wide column of water into which controlled swarms of bubbles were injected from the bottom. Four high-speed cameras recorded the action at 2500 frames per second.

They studied four different cases, varying the bubble size and the amount of gas, to replicate realistic bubbly flows. Importantly, the bubbles with three to five millimeter in diameter were large enough to wobble as they rose, creating strong turbulent wakes. In two of the four cases – those with moderate bubble size and density – the turbulence in the flow closely followed Kolmogorov’s predictions at small scales, that is, for eddies smaller than the size of the bubbles. This marks the first time such scaling has been confirmed experimentally in the midst of a bubble swarm.

Decoding turbulence: energy cascades from big to small

”Kolmogorov's theory is elegant. It predicts how the energy that cascades from big turbulent eddies down to smaller and smaller ones – until it’s eventually dissipated through viscous effects – controls the fluctuations of the turbulent fluid motion,” explains co-author Dr. Andrew Bragg from Duke University. ”Finding that this theory also describes bubble-driven turbulence so well is both surprising and exciting.”

The team also developed a new mathematical formula to estimate the rate at which turbulence loses energy due to viscous effects – known as the energy dissipation rate. Their formula, which only depends on two bubble-related parameters – its size and how densely packed the bubbles are – matched the experimental data remarkably well. Interestingly, they found that Kolmogorov scaling was stronger in regions outside the bubbles' direct wakes. In those wakes, the fluid is so strongly disturbed that the classic turbulent energy cascade is overpowered.

One crucial insight was that for the classic Kolmogorov ”inertial range“ – where his scaling laws work best – to appear clearly in bubble-induced turbulence, the bubbles would need to be significantly larger. But there's a catch: in reality, bubbles of such large sizes would break apart due to their own instability. This means there is a fundamental limit to how well the K41 theory can apply to bubbly flows. ”In a way, nature prevents us from getting perfect Kolmogorov turbulence with bubbles. But under the right conditions, we now know it gets close,” says Dr. Hendrik Hessenkemper, a co-author on the study who performed the experiments.

The findings not only settle an ongoing scientific debate but could also help engineers better design bubble-based systems, from chemical reactors to wastewater treatment. And for physicists, it adds another system – bubbly flows – to the growing list of chaotic phenomena where Kolmogorov’s 1941 theory proves surprisingly robust.

The researchers emphasize that their study is just the beginning. Future work could investigate how turbulence behaves with even more complex bubble shapes, bubble mixtures, or under different gravitational or fluid conditions. ”The more we understand the fundamental rules of turbulence in bubbly flows, the better we can harness them in real-world applications,” summarizes Ma. ”And it’s pretty amazing that a theory from over 80 years ago continues to hold up in such a bubbly environment.”

Publication:
T. Ma, S. Tan, R. Ni, H. Hessenkemper, A. D. Bragg, Kolmogorov scaling in bubble-induced turbulence, in Physical Review Letters, 2025 (DOI: 10.1103/v9mh-7pw1).

Further information:
Dr. Tian Ma | Head of HZDR junior research group "Bubbles go with turbulent flows"
Institute of Fluid Dynamics at HZDR
Phone: +49 351 260 3805 | Email: tian.ma@hzdr.de

Media contact:
Simon Schmitt | Head
Communications and Media Relations at HZDR
Phone: +49 351 260 3400 | Mob.: +49 175 874 2865 | Email: s.schmitt@hzdr.de

The Helmholtz-Zentrum Dresden-Rossendorf (HZDR) performs – as an independent German research center – research in the fields of energy, health, and matter. We focus on answering the following questions:

How can energy and resources be utilized in an efficient, safe, and sustainable way?
How can malignant tumors be more precisely visualized, characterized, and more effectively treated?
How do matter and materials behave under the influence of strong fields and in smallest dimensions?

To help answer these research questions, HZDR operates large-scale facilities, which are also used by visiting researchers: the Ion Beam Center, the Dresden High Magnetic Field Laboratory and the ELBE Center for High-Power Radiation Sources.
HZDR is a member of the Helmholtz Association and has six sites (Dresden, Freiberg, Görlitz, Grenoble, Leipzig, Schenefeld near Hamburg) with almost 1,500 members of staff, of whom about 680 are scientists, including 200 Ph.D. candidates.

High-speed cameras capture swarms of bubbles rising through an LED-illuminated water column, revealing the chaotic flow patterns of bubble-induced turbulence.

Credit

B. Schröder/HZDR

Journal

Physical Review Letters

DOI

10.1103/v9mh-7pw1

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Kolmogorov scaling in bubble-induced turbulence

New CABI-published book Planet Fungi: A Photographer’s Foray is a ‘feast for the eyes’

The new CABI-published book Planet Fungi: A Photographer’s Foray has been described as a ‘feast for the eyes’ with hundreds of beautiful images of weird and wonderful fungi captured in sharp focus from around the world.

CABI

Created by an award-winning team of documentary filmmaker, photographer and mycologist, well-known for their work with Sir David Attenborough documentaries and those broadcast on Netflix and National Geographic channel, the book captures the beauty and diversity of mushrooms in some of the most remote regions on earth.

It is a unique and immersive exploration of fungi, with each picture created from multiple images seamlessly merged into a single frame. Planet Fungi: A Photographer's Foray presents stunning imagery and pioneering explorations that reveal the intricacies of fungal biology and their ecological significance.

Book is partly born from confrontation with mortality

The book is partly born from Stephen Axford’s confrontation with mortality – when his wife of 13 years Pat Flannagan died of breast cancer – sparked his passion for fungi. This passion is shared by co-author and Axford’s partner Catherine Marciniak who helps capture the fungi with third author Dr Tom May.

Axford himself also discovered he had a life-threatening illness.

“This helped me to rethink my life. I was ready to take some risks, to reinvent myself,” he said.

It was a chance encounter in the forest with a purple mushroom that completely changed photographer Axford's view of the world. He became obsessed with documenting the largely unexplored kingdom of fungi, alongside Marciniak.

There are an estimated 2-5 million species of fungi found all over the world, yet with only around 155,000 described so far, there is so much left to discover. From glowing mushrooms in ancient forests to bizarre, alien-like forms, these extraordinary organisms will challenge how you see the natural world.

A stunning exploration of a hidden world

The book is aimed at researchers in mycology, plant science, ecology and the environment, as well as amateur mycologists, fungi enthusiasts, field naturalists, photographers, hikers, citizen scientists, and anyone interested in the natural world.

Merlin Sheldrake, author of 'Entangled Life' said of the book, “A stunning exploration of a hidden world. These are among the most remarkable images of fungi I’ve ever seen, woven into relation by a series of writings that beautifully illuminate the mysteries and wonders of fungal life.”

Giuliana Furci, Founding Director of Fungi Foundation, said, “A wondrous journey through epic fungal encounters, with sublime photography and beautiful tales.”

Renowned for his macro fungi photography

Stephen Axford is renowned for his macro fungi photography, which has been featured in publications and exhibitions worldwide. His fungi time-lapses appear in award-winning documentaries such as Planet Earth 2, Fantastic Fungi and Fungi: Web of Life. He co-writes and presents Planet Fungi's video productions, including Follow the Rain, capturing the intricate beauty of fungi globally.

Award-winning documentary filmmaker, photographer and journalist

Catherine Marciniak is an award-winning documentary filmmaker, photographer and journalist. She co-wrote the IMAX documentary Fungi: Web of Life and directed and co-produced Follow the Rain, exploring the world of fungi. She is also a two-time finalist in the Walkley Awards for Excellence in Journalism.

Passion for communicating and educating about fungi

Dr Tom May is a mycologist at Royal Botanic Gardens Victoria, Australia, where for nearly three decades he has had a distinguished research career and a passion for communicating and educating about fungi. Former President of Fungimap, he co-authored Wild Mushrooming: A Guide for Foragers and was awarded the Nancy T. Burbidge Medal and the Australian Natural History Medallion.

Additional information

Book reference

Planet Fungi: A Photographer’s Foray is edited by Catherine Marciniak, Stephen Axford and Tom May and published by CABI in EMEA & Asia, and CSIRO in ANZ.

Stephen Axford pictured here behind the lens of some wonderous Coprinopsis pulchricaerulea