Latest Articles for Computational Modeling

MICROSIM software simplifies materials science simulations for researchers and engineers.

Discover how LaSDI transforms complex simulations into efficient models.

Research reveals how polymers respond to electric fields, impacting technology development.

A look into quantum effects on material properties in engineering.

Examining filament dynamics for insights into biological processes and engineering applications.

Research reveals new configurations within pulsar magnetospheres and their link to fast radio bursts.

Exploring the role of soft solvent models in scientific research.

Exploring the interplay between colloids and liquid crystals for new material possibilities.

New enhancements to BIT1 improve plasma simulation performance using advanced computing techniques.

Researchers develop efficient models to study lipid membranes and cellular dynamics.

Researchers assess aspirin forms' stability using computer modeling and machine learning.

An overview of hysterons, their interactions, and implications for materials science.

New method enhances fluid movement modeling in complex underground environments.

New preconditioner improves fluid simulations in porous materials for various industries.

This study explores using AI methods to predict how materials crack over time.

New methods enhance predictions for composite materials in various industries.

An overview of finite-volume schemes and their applications in numerical analysis.

This paper presents L-HiTS, a method for simulating complex systems using deep learning.

This study looks at how small particles move in stretchy fluids under force.

Research enhances CO2 conversion efficiency using microbial fermentation techniques.

Combining AI with simulations to enhance fusion energy research.

SMART helps scientists simulate and understand cell signaling processes.

New methods in VEM improve solutions for mathematical problems with irregular boundaries.

A novel approach to simulating how solids interact with fluids during contact.

Researchers are advancing methods to control ferrimagnetic skyrmions for future tech.

Investigating unusual movement behaviors in materials under stress.

Scientists investigate how electrons and phonons influence materials' properties and applications.

Exploring new methods for more effective fluid-structure interaction simulations.

Research reveals the significance of neutron star mergers and the role of simulations.

A new model predicts turbulent behavior, aiding future fusion reactor designs.

Researchers are enhancing ion flow in ceramics for better energy technologies.

A study of MCPA and Wang-Landau algorithms in modeling physical systems.

This study focuses on structural monitoring in fusion devices under various forces.

Researchers use Tensorized Fourier Neural Operator to enhance solar magnetic field simulations.

A computer program simulating fluid movement in porous materials for various research fields.

SPOD enhances modeling efficiency by accurately capturing system behavior over time and space.

A new method enhances accuracy in calculating sublimation enthalpies for molecular crystals.

A look into Block Finite Difference methods for solving heat equations.

A new measure of dissimilarity improves transfer learning in varied data distributions.

A new FFT-based method improves the study of materials with complex microstructures.