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Why have fusion reactors have been so difficult to develop?

Why have fusion reactors have been so difficult to develop?

Normally, fusion is not possible because the strongly repulsive electrostatic forces between the positively charged nuclei prevent them from getting close enough together to collide and for fusion to occur.

How does fusion create more energy?

Fusion occurs when two atoms slam together to form a heavier atom, like when two hydrogen atoms fuse to form one helium atom. This is the same process that powers the sun and creates huge amounts of energy—several times greater than fission.

What are the technical difficulties with fusion reactors?

These problems comprise plasma heating, confinement and exhaust of energy and particles, plasma stability, alpha particle heating, fusion reactor materials, reactor safety and environmental compatibility.

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What is fusion and why is it so difficult to achieve?

Because fusion requires such extreme conditions, “if something goes wrong, then it stops. No heat lingers after the fact.” With fission, uranium is split apart, so the atoms are radioactive and generate heat, even when the fission ends. Despite its many benefits, however, fusion power is an arduous source to achieve.

How does fusion reactor work?

The energy-producing mechanism in a fusion reactor is the joining together of two light atomic nuclei. When two nuclei fuse, a small amount of mass is converted into a large amount of energy. Mass can be converted to energy also by nuclear fission, the splitting of a heavy nucleus.

How much energy would a fusion reactor create?

At present, fusion devices produce more than ten megawatts of fusion power. ITER will be capable of producing 500 megawatts of fusion power.

When will we have a nuclear fusion reactor?

A viable nuclear fusion reactor — one that spits out more energy than it consumes — could be here as soon as 2025. That’s the takeaway of seven new studies, published Sept. 29 in the Journal of Plasma Physics.

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Is thermonuclear fusion more expensive than nuclear fission?

Hence thermonuclear fusion will always have a much lower power density than nuclear fission, which means that any fusion reactor needs to be larger and therefore more costly, than a fission reactor of the same power output.

Will nuclear fusion ever be economically viable?

In order for nuclear fusion technology to become commercially viable, it must be economical. ‘Perfect fusion’ would be intrinsically economical, because it is an endless source of power once running. But the fusion we will likely reach within the next few years may not be so, and will possibly include huge capital costs.

Could Massachusetts’ SPARC reactor produce energy from nuclear fusion?

The Massachusetts Institute of Technology has announced that its SPARC reactor could begin producing energy from nuclear fusion by 2025, but it is a small reactor and likely to produce between just 50MW and 100MW of power. While this is much smaller than the long-predicted perfect fusion reactors, could it be an appealing source of energy?