Editing Nuclear chain reaction (section)

=== Enrichment process ===
{{Mainarticle|Enriched uranium}}
The fissile isotope uranium-235 in its natural concentration is unfit for the vast majority of nuclear reactors. In order to be prepared for use as fuel in energy production, it must be enriched. The enrichment process does not apply to plutonium. Reactor-grade plutonium is created as a byproduct of neutron interaction between two different isotopes of uranium. 

The first step to enriching uranium begins by converting [[uranium oxide]] (created through the uranium milling process) into a gaseous form. This gas is known as [[uranium hexafluoride]], which is created by combining [[hydrogen fluoride]], [[fluorine]], and uranium oxide. Uranium dioxide is also present in this process and is sent off to be used in reactors not requiring enriched fuel. The remaining uranium hexafluoride compound is drained into metal cylinders where it solidifies. The next step is separating the uranium hexafluoride from the [[Depleted uranium|depleted U-235]] left over. This is typically done with centrifuges that spin fast enough to allow for the 1% mass difference in uranium isotopes to separate themselves. A laser is then used to enrich the hexafluoride compound. The final step involves reconverting the enriched compound back into uranium oxide, leaving the final product: enriched uranium oxide. This form of UO<sub>2</sub> can now be used in fission reactors inside power plants to produce energy.