Explore how fusion reactors, ITER tokamaks, plasma confinement, and deuterium tritium fuel work together to unlock net energy gain and deliver reliable, large-scale clean energy. Pixabay, ...

Installation of a neutron diagnostics system in the laboratory of the Institute of Nuclear Physics of the Polish Academy of Sciences in Cracow. Cracow, 10 September 2025 - In the Universe, ...

Scientists have almost completed the development of the High Resolution Neutron Spectrometer (HRNS). The system will be used to measure both the number and energies of neutrons emitted by plasma ...

Scientists at Durham University have completed a large-scale quality verification program for the international ITER fusion energy experiment, the world’s largest project aimed at proving the ...

Four years into Russia’s war with Ukraine, nearly all ties between Russian and European science have been severed. Russian ...

Add Yahoo as a preferred source to see more of our stories on Google. The sun-mimicking technology known as nuclear fusion hopes to create “limitless” energy by smashing light nuclei together using ...

Fusion reactors smash two forms of hydrogen together (top) so that they fuse, producing helium and a high energy electron (bottom). Credit: Wykis/WikimediaCommons The JET result demonstrates ...

Here’s what you’ll learn when you read this story: The plasma density barrier is a mathematical limit to the density of plasma that can exist in a tokamak before destabilizing. A new study led by a ...

Today, many fusion reactors rely on deuterium and tritium—heavy isotopes of hydrogen—to power fusion reactions. But where did ...

Here’s what you’ll learn when you read this story: Tungsten, represented unexpectedly by the letter W on the periodic table of elements (for wolframite, an ore where tungsten is often found), is ...