Latest Articles for Fluid Dynamics

Examining gas dynamics in less dense conditions for better predictions and applications.

Research reveals unique properties of solitary waves in dipolar Bose-Einstein condensates.

New method improves predictions in turbulent fluid dynamics using reduced complexity.

Research reveals strong solutions for heat and magnetic fields in fluids.

Examining how size and density affect particle travel in water currents.

This study investigates how liquids fill microcavities in Lab-on-a-Chip technology.

Scientists study how colloidal particles form and evolve structures in confined spaces.

An overview of the complexities in modeling neutron star merger events.

A look into vortex dynamics and their implications in Bose-Einstein condensates.

Research shows pipe rotation can significantly lower drag in fluid transport.

This article examines how nanoparticles act in liquids and gases.

Researchers study stability and blowup solutions in the complex Ginzburg-Landau equation.

Studying neutron star glitches reveals complex fluid dynamics in their interiors.

REMIX improves fluid simulations by addressing key issues found in traditional SPH methods.

A method to analyze fluid behaviors at sharp boundaries and interfaces.

Research confirms dual boundary conditions for the Stokes problem, aiding fluid dynamics.

Using FPGAs and HLS tools to enhance FTLE calculations in fluid dynamics.

Study of sphere movement affecting density-stratified fluids and its implications.

A new approach to topology optimization using machine learning enhances design efficiency.

A closer look at how the hypersphere model helps understand viscous liquids.

A look at high-order numerical methods for fluid dynamics.

Explore the interaction of different fluids and their real-world applications.

Analyzing Proper Orthogonal Decomposition's performance excluding difference quotients.

This method improves the solving of PDEs on surfaces that change shape over time.

An exploration of bubble movement affected by temperature and surfactants in unique fluids.

Learn how time discretization helps us study viscoelastic materials.

New methods improve accuracy in fluid-solid interaction modeling within poroelasticity.

This study evaluates new methods for simulating coupled nonlinear Schrödinger equations.

A study on how vortices interact in counterflowing superfluids and their implications.

This study explores how to manipulate fluid movement in defined spaces.

Research sheds light on shear viscosity in quark-gluon plasma under varying conditions.

A new approach to enhance accuracy in hyperbolic conservation laws using jump filters.

A model reveals how bacterial patterns change during growth phases.

Innovative methods enhance understanding of water flow dynamics.

Exploring how fractional calculus enhances the modeling of physical phenomena.

Examining how magnetic fields are generated and sustained in astrophysical systems.

Explore how shear-thinning fluids behave under stress and the effects of instabilities.

Study of charged particle movement in fluids under electric fields.

Investigating how thermal fluctuations influence fluid behavior in small systems.

A method for simulating fluid flow in complex environments.