Latest Articles for Computational Methods

Analyzing how slight shape variations affect the Poisson equation's solutions.

This article examines how mutation strength adaptation improves evolutionary algorithm performance.

A look at theories and methods for analyzing shell structures in engineering.

Introducing AVQDS(T): a new approach to quantum dynamics simulations reducing complexity and improving accuracy.

A look into Feynman amplitudes and their significance in particle interactions.

Researchers use MeshGraphNets to improve fluid dynamics simulations efficiently.

Explore the significance of geminal theory in electron interactions and chemical bonding.

Exploring the role of excited states in chemical reactions and electron behavior.

This article discusses recovering probability distributions from noisy measurements using Chebyshev polynomials.

New algorithms enhance understanding of surface states in photonic and acoustic systems.

Enhancing fluid flow control with innovative numerical techniques and robust approaches.

Improving stability and accuracy in RBF interpolation through innovative parameter selection.

A method to solve matrix equations for better image quality.

A new method improves synthetic networks to better reflect real-world communities.

New methods improve molecule creation for drugs and materials.

New methods improve simulations of fluid flows in porous media with uncertain parameters.

A new method improves accuracy in fluid dynamics for charged particles.

New methods enhance nonlocal diffusion problem modeling across various fields.

High-entropy alloys show potential for efficient catalysts in clean energy applications.

New methods simplify calculations for precision matrices in large datasets.

Introducing improved estimators for energy and heat capacity in quantum materials.

An overview of cohomology, lens spaces, and algebraic structures in topology.

A methodical approach to solving complex equations using contour integrals.

A look into the figure-eight knot and its geometric features.

A novel approach to analyze nonlinear systems using energy functions and efficient calculations.

New methods enhance predictions for nuclear fission processes and behaviors.

Introducing a new method for faster energy function calculations in nonlinear systems.

Innovative method enhances beam analysis efficiency and accuracy.

A new approach using Cayley coordinates enhances volume calculations in molecular science.

A new method enhances neural networks for solving complex physics equations.

A fresh approach to analyzing chaotic dynamics in turbulent flows.

An overview of the relationship between Calabi-Yau operators and paramodular forms.

Examining particle interactions is key to advances in biology and chemistry.

An overview of how deep learning methods tackle differential equations.

New methods improve efficiency in transporting resources with lower costs.

Discover how quantum computing tackles complex data challenges efficiently.

Innovative techniques improve efficiency in studying hyperelastic materials and their applications.

Researching how to learn operators and handle errors effectively in function spaces.

A new approach to enhance stability in bilevel optimization problems.

New methods improve computations for differential equations involving Lie groups in quantum dynamics.