Latest Articles for Fluid Dynamics

New research highlights mathematical identities in turbulent flows.

A novel approach to calculating movements of particles in three-dimensional fluids.

Discover how FastVPINNs improve fluid dynamics modeling using neural networks.

New methods combine neural networks and finite element techniques to improve fluid flow simulations.

Exploring how particle sizes affect porosity in various materials.

A new model provides accurate predictions for crude oil viscosity across temperatures.

This study tests riblets on hydrofoils to reduce drag for smaller vehicles.

Exploring the behavior and interactions of vortices within two-dimensional supersolids.

Exploring how active rods interact with their environment.

New methods utilize single snapshots for effective turbulence analysis.

Exploring the Lattice Boltzmann Method for fluid dynamics in transonic flows.

Analyzing particle behavior using the relaxation time approximation and its implications.

A look at numerical methods for efficient fluid flow solutions.

This study examines how liquids flow through granular materials, highlighting key drainage mechanisms.

Researchers create simpler models to predict complex fluid behaviors efficiently.

Researchers unveil the mechanics behind the swimming of tiny organisms using cilia and flagella.

Spinners interact and synchronize on a vibrating liquid surface, revealing fascinating behaviors.

A look at how the BGK model simplifies the study of gas behavior.

Exploring how elastic turbulence improves mixing in viscoelastic fluids.

This study explores how medical foam absorbs water to stop bleeding during emergencies.

This article explores unique properties of solutions in quasilinear elliptic equations.

Examining how equations model complex systems over time.

New insights into particle dynamics in confined fluids and their applications.

A look into how machine learning improves the study of material flow.

Introducing TFPONets for solving interface problems with deep learning techniques.

Introducing ComFNO, a method for tackling complex differential equations using deep learning.

Examining how rotation influences fluid stability between moving plates.

Study reveals unexpected interactions of particles in viscous fluids near walls.

Exploring how liquid droplets move on solid surfaces and the effects of temperature and friction.

Examining the interplay of fluids, magnetism, and spin in high-energy environments.

This study reveals how droplets form intricate patterns during evaporation.

Exploring the breakup of liquid jets and its implications for various industries.

A new method enhances moisture representation in weather models.

A new method speeds up fluid simulations using a blend of machine learning and CFD.

This research advances modeling of turbulent flows in rotating systems.

New insights into controlling tiny particles for various applications.

Study reveals how critical Casimir forces levitate colloids above patterned surfaces.

New AI techniques improve fluid dynamics modeling accuracy and efficiency.

A look into how different fluid components interact within superfluids.

Learn how viscoelastic fluids behave in various applications.