New insights into current flow in vacuum diodes enhance electronic device design.
― 5 min read
Examining how environmental arrangements impact quantum system simulations.
― 5 min read
Recent progress in recurrence analysis enhances our understanding of system behavior over time.
― 6 min read
A simplified approach to compute Wannier functions improves material research.
― 4 min read
Discover how FastVPINNs improve fluid dynamics modeling using neural networks.
― 6 min read
New methods utilize single snapshots for effective turbulence analysis.
― 5 min read
Exploring the Lattice Boltzmann Method for fluid dynamics in transonic flows.
― 6 min read
A new method improves the study of complex multicomponent alloys.
― 4 min read
This new system improves speed and efficiency in visual data processing.
― 4 min read
New methods improve light interaction analysis in complex systems.
― 6 min read
A new method combines AI and quantum chemistry to solve complex equations efficiently.
― 5 min read
A new framework combines machine learning and PDEs for efficient scientific modeling.
― 5 min read
New methods improve heat transport simulations in anisotropic plasmas for fusion research.
― 5 min read
A look into how energy levels of diatomic molecules are studied.
― 5 min read
Patient-specific models enhance understanding of heart blood flow and treatment strategies.
― 6 min read
New methods provide clarity on excited states in argon clusters.
― 3 min read
Learn how PML improves wave simulation accuracy by minimizing reflections.
― 5 min read
nekCRF enhances combustion simulations for better efficiency and lower emissions.
― 5 min read
New method improves imaging of tiny structures using Coherent Diffraction Imaging.
― 6 min read
A new method to improve sampling in complex Bayesian inverse problems.
― 5 min read
Exploring the potential of silicon nanowires in technology and their behavior at low temperatures.
― 4 min read
A new method speeds up material phase study using active learning.
― 7 min read
Examining how training data diversity affects material behavior predictions.
― 5 min read
New approaches improve light diffraction simulations with tensor train decomposition.
― 5 min read
New techniques streamline the detection and analysis of gravitational wave signals.
― 5 min read
Research reveals new methods for studying complex fluid behaviors under rapid rotation.
― 5 min read
Study reveals how impurities impact nucleation in materials.
― 6 min read
Research highlights using influence functions to enhance PINN performance in physics problems.
― 6 min read
This study explores light's impact on bilayer graphene's thermoelectric efficiency.
― 6 min read
New technique significantly accelerates molecular dynamics simulations by optimizing reset conditions.
― 4 min read
A new method for finding ground states of quantum systems efficiently.
― 6 min read
Improving simulations of multiphase fluid flows using modern GPU technology.
― 6 min read
A detailed analysis of solvers for sparse linear systems with challenging conditions.
― 7 min read
A deep dive into variable-order diffusion equations and their solution methods.
― 6 min read
Combining physics models and deep learning to improve predictions and manage uncertainty.
― 5 min read
Researchers enhance magnetic sensing using machine learning with NV centers.
― 5 min read
Real-time reactor state estimation through innovative data-driven techniques.
― 6 min read
Researchers introduce a method for accurate atomic-level material modeling.
― 6 min read
This article reviews the importance of LXC potential in material science.
― 4 min read
Learn how simulations improve DNA origami designs and their applications.
― 6 min read