Latest Articles for Energy Research

Examining drift wave solitons and their role in plasma behavior and fusion energy.

Explore how stellarators use magnetic fields for efficient plasma confinement in fusion research.

New models aim to improve safety and efficiency in fusion energy.

Discover the unique properties and potential applications of double-double perovskite oxides.

Researchers uncover unique wobbling motions in Palladium, revealing new atomic behaviors.

Study explores AI's role in optimizing plasma stability through effective magnetic field predictions.

Introducing an innovative method for accurate magnetohydrodynamics simulations.

Research reveals how palladium nanocrystals adapt to strain during phase transformations.

Research reveals new insights into the stability of tungsten nanoparticles in various environments.

Examining the impact of Alfvén eigenmodes on plasma behavior in fusion devices.

Research reveals important insights on plasma stability in magnetic confinement fusion.

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

Using deep learning to analyze plasma dynamics can improve fusion energy control.

New electric field designs in stellarators may improve plasma performance and reduce impurities.

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

This article examines how collisions affect wave modes in plasmas.

Imidogen (NH) is crucial for understanding nitrogen in space and Earth.

This article examines how mosaic crystals affect X-ray measurements in high-energy systems.

TORAX is an open-source simulator designed for tokamak plasma research.

Research focuses on managing plasma disruptions to improve fusion reactor safety.

Researchers examine how disorder impacts the properties of (CaSr)RhSn materials.

Research reveals complex electron transfer behaviors in optical cavity environments.

Research on double-null configurations offers new insights for managing heat exhaust in fusion reactors.

Research identifies promising alternatives to tungsten for fusion reactor components.

A novel technique improves our grasp of light’s effect on molecular behavior.

Study reveals crucial insights into ion temperatures during nuclear fusion processes.

Examining turbulence dynamics at the edge of Tokamaks for improved fusion research.

A new method improves plasma control in stellarators by optimizing magnetic islands and coil design.

New methods improve plasma stability and computational efficiency in fusion reactors.

Exploring the impact of drift-tearing modes on plasma stability in tokamak devices.

Research on plasma and materials is vital for future fusion energy development.

SCR-1 stellarator in Costa Rica studies plasma for future fusion energy.

Recent findings on NT plasmas could shape the future of fusion energy systems.

Research highlights how nonuniformity affects plasma behavior in fusion reactors.

New models improve understanding of anharmonic oscillators' energy levels.

Researchers examine large-angle collisions impacting fusion processes in burning plasmas.

Recent advancements in studying warm dense matter using Bohm SPH show promising results.

Recent findings shed light on Zirconium-89's isotopes and neutron absorption.

Research on QC-modes in plasma sheds light on fusion energy dynamics.

G2C3 improves simulations of plasma microturbulence in fusion devices using neural networks.