Latest Articles for Fluid Dynamics

Cholla-MHD enhances astrophysical simulations using magnetohydrodynamics for detailed cosmic studies.

Examining how draining flows affect quantum vortices' stability and behavior.

A new approach to handle complex changing domains in numerical simulations.

A method to estimate blood flow parameters using advanced imaging data.

Researchers combine neural networks to enhance simulation accuracy and efficiency.

This study examines the influence of viscosity on Faraday waves in confined liquids.

This article compares grid-based and pseudo-spectral solvers in plasma research.

Study of time-periodic vortex solutions in lake equations reveals water movement insights.

New methods improve understanding of poroelastic materials in biological tissues.

A look into how liquids interact at surfaces and the role of line tension.

New methods enhance boundary treatment in compressible fluid flow simulations.

Research confirms local well-posedness of E-MHD equations amid large magnetic field changes.

A new method improves fluid dynamics simulations using neural networks.

A new program improves fluid flow calculations using Regent and LSKUM methods.

Examining the movement of solid objects in electrically conducting fluids.

This article examines the stability and behavior of Stokes waves in deep water.

This study rethinks energy barriers affecting molecule transport in polymer membranes.

Study examines how synthetic jets manage airflow for improved airfoil performance.

Research connects turbulent fluid dynamics to black hole physics, revealing new insights.

Introducing a method that combines kernel-based reconstruction with finite volume techniques for fluid flows.

The new Discrete Direct Deconvolution Model enhances turbulence simulation accuracy.

A new approach transforms how we model fluid and solid interactions.

Examining energy transfer mechanisms in MHD turbulence for better modeling.

This article presents a new method for quick pressure calculations from velocity data.

This study examines how wall shapes affect nonlinear acoustic wave behavior.

A new method reveals dynamics of hydrogels in confined spaces.

Study investigates how porous environments affect the performance of tiny three-sphere robots.

This research explores how small changes in fluid flows lead to complex behaviors.

Researchers propose innovative methods for deploying Lagrangian drifters to better understand fluid flows.

Research reveals mechanisms behind Giardia's ability to attach to surfaces using fluid dynamics.

A study on how forces affect the movement of liquids and glass transitions.

Research on magnetic nanoparticles reveals insights into their flow behaviors in complex materials.

This research examines the complexities of mixing in turbulent fluid flows.

Exploring the behavior of inertia-gravity waves in geophysical vortices.

A method to separate relevant flow information for improved predictions and strategies.

Exploring wave actions and their impact on fluid movement in porous materials.

This study focuses on how helicopters disturb sandy surfaces during landing.

Research reveals techniques for improving performance of low-aspect-ratio wings through airflow management.

A detailed look into how vortices behave in fluid dynamics.

Examining how pressure variations affect fluid flow in turbulent boundary layers.