Nuclear fusion

by Chris Woodford. Last updated: October 25, 2023.

When scientists "split the atom" in the early 20th century, they thought they were revealing how the world is built from basic bits of matter. What they didn't realize at the time was that they'd invented a completely new way of producing energy that would soon be deployed in atomic bombs and nuclear power plants. Ernest Rutherford, the scientist who led the early atom-smashing experiments, famously said that "anyone who expects a source of power from the transformation of the atom is talking moonshine." In one sense at least, he was correct: though it's widely used in many countries, nuclear power has proved hugely expensive and politically controversial, caused some catastrophic accidents, polluted seas, and generated horrible amounts of highly dangerous radioactive waste. Today's nuclear power plants release energy by splitting up large atoms (in what's called nuclear fission); tomorrow's plants could work using an entirely different form of nuclear power where small atoms are forced together to make bigger ones. Known as nuclear fusion, this is much cleaner and safer and could potentially solve our energy needs forever. What is fusion and how does it work? Let's take a closer look!

Photo: One way to make nuclear fusion is to confine atoms in a small space and then blast them with laser beams, as in this experimental setup at the National Ignition Facility (NIF) in California. More about this further down the article. Photo credit: Lawrence Livermore National Laboratory.

What is nuclear fusion?

It's not immediately obvious, but almost everything you're doing right now (from breathing in and out to tapping away on your computer) and everything you can see around you (trees blowing, grass growing, and cars speeding by your window) is powered by nuclear fusion—because that's what drives the Sun, and the Sun drives the Earth. If you could get close enough to the Sun to peer inside its core and see what's going on inside, you'd see atoms of hydrogen joining together ("fusing") to make atoms of helium, releasing huge amounts of energy in the process. Apart from making incredible amounts of heat inside the Sun itself (the core is at a temperature of about 15 million °C or 27 million °F), the Sun's nuclear fusion also produces the solar energy that streams out across 150 million kilometers (93 million miles) of space sustaining pretty much all the life we see on Earth. [1]

Now suppose we could make a machine that copied what happens inside the Sun here on Earth, only in a much smaller and more controllable way. In theory, we'd just feed in hydrogen (a simple, fairly safe gas we can make from water) at one end, smash its atoms together inside, and get helium (a clean and safe gas) out of the other end. In the process, we'd produce huge amounts of heat energy, which we could use to drive steam turbines and generators to produce electricity, much as in any conventional power plant. There'd be no pollution, no carbon dioxide (one of the so-called greenhouse gases that causes global warming and climate change), and no deadly nuclear waste. We'd have simple, clean, safe, nuclear power!

Photo: The Earth is powered by nuclear fusion happening inside the Sun. Some time in the future, we might be able to create small-scale fusion power ourselves, here on Earth. This photo was taken by the Solar and Heliospheric Observatory (SOHO), a project of international cooperation between ESA (European Space Agency) and NASA. Picture courtesy of SOHO/EIT consortium.

How can we make nuclear fusion happen on Earth?

There's obviously a huge difference between the center of the Sun and the inside of a power plant on Earth—so how could we make nuclear fusion reactions happen in practice?

It turns out that, instead of using ordinary hydrogen atoms, the best approach is to use other isotopes (different atomic forms) of hydrogen that are slightly heavier. An ordinary hydrogen atom has just one proton in the nucleus and one electron in the space around it, but these heavier hydrogen isotopes are built differently (and are much less stable as a result). One of them, known as deuterium, has one proton and one neutron in the nucleus and one electron in the outside space. The other, called tritium, has one proton and two neutrons and one electron outside. Smash together an atom of deuterium and an atom of tritium and the bits we have to play with are two protons, three neutrons, and two electrons. From these, we can make one very stable atom of helium (which has two protons, two neutrons, and two electrons) and have one neutron left over. By converting two unstable atoms (one each of deuterium and tritium) into one stable helium atom, we release a great deal of energy.

Artwork: The nuclear reaction that produces fusion energy. Protons are shown as blue and neutrons as red. (Electrons aren't shown.)

Now what we have here sounds a little bit like a chemical reaction, where we might react something like sodium metal with chlorine gas to get sodium chloride (table salt). Chemical reactions can release energy if the products (the things you end up with) are more stable than the reactants (the things you start off with). However, you get much more energy out of a nuclear reaction (where the atoms you start with are changed into completely different atoms) than a chemical reaction (where the atoms retain their identity but join or rearrange into different molecules). That's because the amount of energy needed to hold the nucleus of one atom together is vastly greater than the amount of energy involved in binding two different atoms together.

How much energy is released in a fusion reaction?

If you compare the mass of a deuterium atom plus a tritium atom (what you start off with) with the mass of a helium atom and a neutron (what you finish with), you'll find some mass is "lost" during a fusion reaction. That's the mass that's converted into energy as the nuclei fuse together; the amount of energy is precisely related to the amount of mass by Einstein's famous equation E=mc2, which shows that a tiny amount of mass can produce a huge amount of energy (because c, the speed of light, is a very large number and c squared, which is c×c is even bigger). The amount of energy released in one single reaction is 17.59 MeV (17.59 million electron volts), which is one of those baffling measurements only physicists use and understand. [3] Translating that into more meaningful terms, you'd need about 3,500,000,000,000 (3.5 million million) of those reactions happening every single second to light a 10-watt, low-energy lamp. That sounds a lot, but remember that 1g (0.04 oz) of ordinary, pure hydrogen contains 600,000,000,000,000,000,000,000 (600,000 million million million) atoms and you can see we could potentially make a huge amount of fusion power with very little fuel at all. [4] (The figures are slightly different if we take account of deuterium and tritium, but the basic point—a small amount of matter contains an awful lot of atoms—still holds.)

Artwork: Energy being released in a nuclear fusion reaction (conceptual illustration). Artwork by US Department of Energy courtesy of Wikimedia Commons.

How would nuclear fusion plants work in practice?

As we've just discovered, the basis of nuclear fusion on Earth is converting deuterium and tritium to helium, with a big release of power as two unstable atoms rearrange themselves to make one stable atom. It sounds simple enough, but no-one has yet managed to make fusion work on a big enough scale to generate commercial amounts of power. That's because there are huge practical difficulties involved. To make two atoms fuse, you have to push their nuclei closer and closer together. The trouble is, the nucleus of every atom has a relatively large positive, electrical charge so two nuclei repel one another in much the same way as the north poles of two magnets ("like poles repel"). The nearer the nuclei get, the more energy it takes to get them any closer—and the amount of energy keeps on increasing. In fact, the repulsive force between two nuclei quadruples every time you halve the distance (if you're interested, that's because of Coulomb's Law). In practice, this means you have to use a vast amount of energy to make atoms fuse together in the hope that you can release even more energy in the end. After decades of trying, scientists have only just got to the point where they can release more energy from fusion as they use in the first place. That's why nuclear fusion is currently being studied only in scientific laboratories and why, for the moment at least, it's not a practical or viable source of power.

Confinement

What are scientists actually doing in those fusion labs? To make atoms fuse, we have to heat them up to make plasmas (ultra-hot soups of gases in which the atoms get so hot that they're blown apart into their constituent nuclei and electrons), then hold them tightly together in a confined space at temperatures at least as hot as you get in the center of the Sun. So the problem of generating energy by fusion becomes a slightly different one: how can we confine a super-hot plasma so it stays hot and energetic enough for the atoms inside it to overcome their natural repulsion and fuse together?

Artwork: Magnetic confinement: In a tokamak, plasma (gray) is confined in a donut shape by electromagnet coils (orange and black).

In stars like the Sun, gravity is the force that achieves this. On Earth, we have to achieve the same end artificially and there are two basic ways to do this. In one method, called magnetic confinement, deuterium and tritium are heated to sun-core temperatures of about 100 million degrees. Then a super-strong magnetic field is used to trap them in a donut-shape known as a torus. A machine that does this is known as a tokamak, a word coined in Russia for just this piece of apparatus (the biggest in the world is currently operating at a lab known as JET, Joint European Torus, a few km/miles south of Oxford in England). The other method of fusion is called inertial confinement and involves firing a powerful laser at a pellet of fuel so the atoms inside it are instantly heated and fused together. The fuel burns before it can blow apart, so its own mass (and therefore inertia) is effectively what confines it. One example of this technique is being used at NIF (National Ignition Facility) at Lawrence Berkeley National Laboratory in California, where 192 laser beams (collectively making the world's biggest laser) are fired simultaneously at a tiny fuel pellet to create the right conditions for nuclear fusion.

Artwork: Inertial confinement: Multiple lasers (blue) converge on a fuel pellet (gray) to bring about fusion.

Impressive though they are, JET and NIF are still just lab experiments. Hopes of achieving anything like commercially viable fusion are also being pinned on another international project known as ITER, currently under construction in southern France. Once complete, in around 2025, it should be able to generate about 10 times more energy than it consumes for up to about 8–10 minutes. Even that, which will be a major achievement, will be far short of generating fusion power hour after hour, day after day, and year after year. But it's a start!

Meanwhile, at MIT, scientists are hoping that "recent" breakthroughs in developing high-temperature superconductors could help to produce far stronger magnetic fields, so making fusion reactors more immediately feasible. Their project, run by MIT's Plasma Science and Fusion Center (PSFC) and a spinoff company called Commonwealth Fusion Systems (CFS), is called SPARC and, although less ambitious than ITER, it could potentially deliver results far faster. In September 2020, in a major boost for the project, 47 key researchers from 12 academic institutions who reviewed the project concluded that SPARC too would able to generate more energy than it consumed. But NIF reached that important milestone first, announcing the result in December 2022, so for now it's ahead of the pack.

Who will win the fusion race—JET, NIF, ITER, SPARC, or someone else altogether? It's far too early to say, but stay tuned as the race continues!

Can fusion ever deliver?

Nuclear fusion offers great promise for the future: huge supplies of clean energy made from readily available fuels that are effectively unlimited. It generates no nuclear waste or pollution (other than reactor equipment, which remains contaminated at the end of its life for about a century) and no greenhouse gases. There's no risk of nuclear accidents similar to those that have occurred with fission plants (in horrific incidents such as at Chernobyl, Ukraine in 1986 and Fukushima, Japan in 2011). On the negative side, scientists estimate we're still several decades away from seeing commercial fusion plants. It's only a matter of time before fusion plants are making some of our daily electricity, but can we develop them fast enough before Earth's energy crisis, and climate change, really hit home?

A brief history of nuclear fusion

• 1890s–1920s: New-Zealand-born Sir Ernest Rutherford (1871–1937) and associates demonstrate nuclear fission ("splitting the atom") and nuclear fusion in a long series of ingenious physics experiments, which gradually reveal the structure of the atomic nucleus.
• 1920: Sir Arthur Eddington (1882–1944), a British physicist, proposes that stars like the Sun make their energy from fusion. Atomic scientist Hans Bethe (1906–2005) fleshes out these ideas in 1939.
• 1934: Working with Rutherford at Cambridge University, Australian-born Sir Mark Oliphant (1901–2000) becomes the first person to demonstrate nuclear fusion in a laboratory.
• 1950: Soviet nuclear physicist Andrei Sakarov (1921–1989) designs a special reactor for creating fusion, the tokamak, so beginning the USSR's fusion program. The first Tokamak, the T-1, is created in 1958.
• 1951: American Lyman Spitzer (1914–1997) invents an alternative plasma-confinement reactor called a stellarator.
• 1983: The Joint European Torus (JET) tokamak reactor in England is completed. In 1997, it sets a world record for fusion generation of 16 megawatts (albeit from an input power of 24 megawatts).
• 1997: Work begins on the National Ignition Facility (NIF) fusion experiment at Lawrence Livermore National Laboratory in California.
• 2013: Construction starts on the International Thermonuclear Experimental Reactor (ITER) in France and is currently expected to be completed in 2025.
• 2018: MIT scientists predict that fusion power could be delivering electricity to the world's power grids within 15 years. They launch the SPARC project to realize that goal.
• 2022: NIF scientists announce that their giant laser experiment has finally produced more energy than it consumes—a milestone that heralds commercially viable nuclear fusion plants in the years to come.

Find out more

On this website

You might like these other articles on our site covering similar topics:

• Atoms
• Energy
• Nuclear power plants
• Renewable energy

Other websites

All these sites have good background material about nuclear fusion:

• Culham Centre for Fusion Energy: Home of the JET project in Oxford, England.
• General Fusion: A small-scale fusion project that uses elements of both magnetic and inertial confinement.
• ITER (International Thermonuclear Experimental Reactor): The successor to JET, located in France.
• JET (Joint European Torus)
• NIF (National Ignition Facility): Laser inertial confinement project at LLNL in California, USA.
• Fusor.Net: The Open Source Fusor Research Consortium: An online meeting place where amateur fusion scientists swap techniques and share ideas.
• SPARC: The MIT and CFS project aims to produce commercially viable fusion with the help of cutting-edge superconductors.

Books

Popular

• The Boy Who Played with Fusion by Tom Clynes. Eamon Dolan/Houghton Mifflin Harcourt, 2015. How a gifted young student attempted to crack the world's biggest energy challenge.
• A Piece of the Sun: The Quest for Fusion Energy by Daniel Clery. Overlook Press, 2014/Duckworth, 2013. Light on science, but a comprehensive review of how engineers have pursued the dream of nuclear fusion.
• Sun in a Bottle: The Strange History of Fusion and The Science of Wishful Thinking by Charles Seife. Viking, 2008.
• Fusion: The Search for Endless Energy by Robin Herman. Cambridge University Press, 1990. An entertaining history of fusion research, from Lyman Spitzer's secret Princeton experiments, which launched Project Matterhorn in 1951, to the Fleischmann–Pons, cold fusion fiasco of 1989. Unfortunately, since the book was published in 1990, it omits everything that's happened since then.
• The Fusion Quest by T. Kenneth Fowler. Johns Hopkins University Press, 1997. A historic, inside account of the quest for fusion from a former nuclear researcher at ORNL and LLNL.

Academic

• Fusion: The Energy of the Universe by G. M. McCracken and Peter E. Stott. Academic Press, 2012. A great introduction that starts with the basic concepts of fusion in the Sun and stars and energy from mass, examines man-made fusion, then reviews different approaches to fusion on Earth, including magnetic and inertial confinement.
• Nuclear Fusion: Half a Century of Magnetic Confinement Fusion Research by Cornelis Braams and Peter E. Stott. IOP, 2002. Historical review of attempts to achieve viable fusion power since the mid-20th century.

Articles

• Fusion "Breakthrough" Won’t Lead to Practical Fusion Energy: Just one more step on the long road to commercialization by Dina Genkina. IEEE Spectrum, December 14, 2022. Why NIF's fusion breathrough is just the beginning.
• Has Fusion Really Had Its 'Wright Brothers' Moment? by Dan Garisto. IEEE Spectrum, August 27, 2021. How significant are recent developments in the grand scheme of achieving commercially viable fusion power?
• General Fusion Takes Aim at Practical Fusion Power by Prachi Patel. IEEE Spectrum, August 13, 2021. A new demonstration reactor is taking aim at viable fusion by 2025 using Magnetized Target Fusion (MTF).
• Wanted: UK site for prototype nuclear fusion power plant by Damian Carrington, The Guardian, 2 December 2020. Will remote British communities embrace experimental fusion plants?
• Superconductor technology for smaller, sooner fusion by Leda Zimmerman, MIT News, 13 October 2020. An update on MIT's SPARC project.
• Iter: World's largest nuclear fusion project begins assembly by Paul Rincon, BBC News, 28 July 2020. Could a new French power project crack the world's clean energy problem?
• Try This at Home! Fusion in the Basement by Tom Clynes. IEEE Spectrum, February 20, 2020. How Microsoft's Carl Greninger is teaching kids about nuclear fusion in Seattle.
• 5 Big Ideas for Making Fusion Power a Reality by Tom Clynes. IEEE Spectrum, January 28, 2020. A great comparison of five promising approaches that could deliver commercial fusion power.
• Nuclear fusion on brink of being realised, say MIT scientists by Hannah Devlin. The Guardian, March 9, 2018. MIT and Commonwealth Fusion Systems believe they can deliver fusion power to the grid within 15 years with a new technique that uses more powerful magnets.
• Startup: LPPFusion Embraces Instability by Mark Anderson. IEEE Spectrum, September 22, 2017. Exploring a new approach to fusion called Dense Plasma Focus (DPF).
• Three Alternative Fusion Projects That Are Making Progress by Mark Anderson. IEEE Spectrum, November 18, 2015. Giant, big-budget tokamaks aren't the only hope for achieving nuclear fusion; small-scale research efforts are approaching the problem from different directions.
• Start-Ups Take On Challenge of Nuclear Fusion by Dino Grandoni. The New York Times, October 25, 2015. Can energetic startups find the holy grail of fusion where governments and universities have so far failed?
• How Far Can Crowd-funded Nuclear Fusion Go? by Mark Anderson. IEEE Spectrum, July 15, 2014. Why Focus Fusion is exploring a process called proton-boron fusion, long abandoned by mainstream researchers.
• Machinery of an Energy Dream: The Challenge: How to Keep Fusion Going Long Enough by Kenneth Chang. The New York Times, March 17, 2014. A good review of NIF, ITER, and other current fusion projects.
• Giant laser experiment powers up by Jonathan Fildes, BBC News, 31 March 2009. A look at how NIF works and what it hopes to achieve.
• This Machine Might* Save the World (* that's a big, fat "might") by Josh Dean, Popular Science, 23 December 2008. How General Fusion is attempting to create nuclear fusion on a small scale.

Notes and references

1. ↑   The Sun: Basics, NASA.
2. ↑   According to the BP Statistical Review of World Energy 2022, p.3: "Fossil fuels accounted for 82% of primary energy use last year, down from 83% in 2019 and 85% five years ago."
3. ↑   An electron volt is the amount of energy an electron gains when it's accelerated through a voltage of 1 volt. It's a great unit for quantifying energy at the atomic scale, but pretty meaningless for the (relatively) massive amounts of energy we use in everyday life. If you have a 10-watt low-energy lamp and use it for one second, it uses 10 joules of energy, which is the same as 62,415,093,432,601,790,000 electron volts! Now you see why we don't use "electron volts" for electricity bills.
4. ↑   1g of hydrogen is 1 mole of hydrogen and 1 mole of anything contains 6 × 10²³ atoms.