One-dimensional turbulence (ODT) modelling represents a powerful stochastic framework for simulating turbulent flows while reducing computational complexity. By focussing on a single spatial dimension ...

Scientists are blending physics-informed AI with supercomputing to model plasma turbulence more accurately and efficiently. These breakthroughs could improve predictions for fusion reactors, ...

Researchers used the world's fastest supercomputer for open science to train an artificial intelligence model that captures ...

Mention the word “turbulence” and you might conjure up images of bumpy flights, stormy weather, and choppy ocean or river currents. For many, turbulence is a fact of daily life, yet it is also one of ...

Boundary layer transition and turbulence modelling represent central challenges in fluid dynamics, with profound implications for the design and performance of aerospace, automotive, and energy ...

Astronomers have developed a groundbreaking computer simulation to explore, in unprecedented detail, magnetism and turbulence in the interstellar medium (ISM) -- the vast ocean of gas and charged ...

Those who have searched for a pattern in the chaotic splatters of a Jackson Pollock painting may intuitively grasp turbulence and all its complexity. Now imagine Pollock’s swirls of paint in motion ...

The irregular, swirling motion of fluids we call turbulence can be found everywhere, from stirring in a teacup to currents in the planetary atmosphere. This phenomenon is governed by the Navier-Stokes ...

For decades, turbulence was treated as a known nuisance—unpredictable, occasionally dangerous, but broadly manageable within the design assumptions of modern aircraft. Engineers modeled it, pilots ...