Will nuclear fusion really work? It promises limitless power from minimal fuel but the challenge for scientists is taming it. Now there is mounting excitement about new advances.
The race to harness the power of the sun
Will nuclear fusion really work? It promises limitless power from minimal fuel but the challenge for scientists is taming it. Now there is mounting excitement about new advances.
Can we bottle a star? Almost all energy we use on Earth comes from the sun.
It is a giant thermonuclear fusionAn atom's nucleus contains a large amount of energy. This can be released either by fission (splitting the atom) or fusion (joining lighter nuclei together to form heavier nuclei). reactor, smashing hydrogen atoms together under heat and pressure. These reactions will keep the sun burning bright for seven billion years.
For the last six decades, scientists have dreamed of building their own star. A clean and cheap source of power.
Creating star-like conditions is not easy. Physicist Arthur Turrell says it is "the greatest technical challenge humanity has ever taken on".
The sun's core is over 15 million degrees Celsius, hydrogen atoms break apart to form plasmaa gas charged with electricity, found in stars such as the Sun. Physicists regard it as a state of matter, along with gas, liquid and solid.. Weighing 333,000 times more than Earth, the sun's gravitational pull fuses particles together into helium and energyWhen two atoms fuse, they lose some of their mass as energy. Einstein's famous equation E = mc2 shows that a small mass contains a huge amount of energy..
Scientists use laser beams, x-rays, microwaves and magnets to replicate this environment. There is a problem: all these approaches use more energy than they create.
Scientists believe they are on the brink of "ignition".
In August, a US lab fired 192 lasersThe combined energy of the lasers at the National Ignition Facility makes them the most powerful laser in the world. at a hydrogen pellet, turning it into a blob of superhot plasma. It generated more energy than it absorbed.
Physicist Jeremy Chittenden says it is like striking a match. Once you light the flame, fusion becomes a "self-sustaining process - for as long as we can hold the burning plasma together."
Which is only a tenth of a billionth of a second. Another machine in China kept a reaction going for 101 seconds. But "we're still doing science," says expert Steven Krivit, "we're not doing technology". Fusion needs to last for more than a few seconds before it can save the world.
Industry leader Andrew Holland is hopeful. "Fusion is coming," he says, "faster than you expect". He counts at least 35 companies, aiming to have working reactors by 2025. And hook up power plants by the 2030s.
The potential is enormous.
Fusion will get most of its hydrogen fuel from waterFusion uses two types of hydrogen. Deuterium is found naturally in water. Tritium must be artificially created in a nuclear reactor.. And a small amount goes a long way. Scientists estimate one glass of fusion energy could replace a million gallons of oil.
It is also green. Fusion does not release greenhouse gasses or leave behind radioactive wasteNuclear fission uses uranium which stays radioactive. Fusion can only take place in the unique conditions of the reactor.. As fuel for carbon captureTechnology which captures carbon dioxide from the air and transports it to storage sites underwater, preventing it from warming the atmosphere. , it might help reverse climate change.
Some are unconvinced. "Bottling up the power of the sun will always be 20 years away", says science writer Charles Seife. In 1951, Argentina declared it would offer fusion like bottled milk. In 1989, US chemists claimed to have created fusion energy at room temperature. Bottled star-fuel and cold fusionThe results turned the science world upside down, but other scientists could not replicate the experiment. turned out to be too good to be true.
As the world aims for net-zeroCountries have committed to not putting more CO2 into the atmosphere than they are removing through carbon capture. This is also known as carbon neutral., physicist Nicholas Hawker says we need to develop fusion technology "at maximum speed".
Will nuclear fusion really work?
No. The Earth has a functioning fusion reactor - the sun. We should build more solar panels, rather than waste money on unproven technology. It's too expensive and complex to be an affordable source of energy.
Yes. A revolution is taking place. Fusion began as a long-term research project funded by governments. Dozens of companies are in a race to be the first to build a working reactor. Competition and investment will make fusion a success.
Keywords
Thermonuclear fusion - An atom's nucleus contains a large amount of energy. This can be released either by fission (splitting the atom) or fusion (joining lighter nuclei together to form heavier nuclei).
Plasma - a gas charged with electricity, found in stars such as the Sun. Physicists regard it as a state of matter, along with gas, liquid and solid.
Energy - When two atoms fuse, they lose some of their mass as energy. Einstein's famous equation E = mc2 shows that a small mass contains a huge amount of energy.
192 lasers - The combined energy of the lasers at the National Ignition Facility makes them the most powerful laser in the world.
Water - Fusion uses two types of hydrogen. Deuterium is found naturally in water. Tritium must be artificially created in a nuclear reactor.
Radioactive waste - Nuclear fission uses uranium which stays radioactive. Fusion can only take place in the unique conditions of the reactor.
Carbon capture - Technology which captures carbon dioxide from the air and transports it to storage sites underwater, preventing it from warming the atmosphere.
Cold fusion - The results turned the science world upside down, but other scientists could not replicate the experiment.
Net-zero - Countries have committed to not putting more CO2 into the atmosphere than they are removing through carbon capture. This is also known as carbon neutral.
The race to harness the power of the sun
Glossary
Thermonuclear fusion - An atom's nucleus contains a large amount of energy. This can be released either by fission (splitting the atom) or fusion (joining lighter nuclei together to form heavier nuclei).
Plasma - a gas charged with electricity, found in stars such as the Sun. Physicists regard it as a state of matter, along with gas, liquid and solid.
Energy - When two atoms fuse, they lose some of their mass as energy. Einstein's famous equation E = mc2 shows that a small mass contains a huge amount of energy.
192 lasers - The combined energy of the lasers at the National Ignition Facility makes them the most powerful laser in the world.
Water - Fusion uses two types of hydrogen. Deuterium is found naturally in water. Tritium must be artificially created in a nuclear reactor.
Radioactive waste - Nuclear fission uses uranium which stays radioactive. Fusion can only take place in the unique conditions of the reactor.
Carbon capture - Technology which captures carbon dioxide from the air and transports it to storage sites underwater, preventing it from warming the atmosphere.
Cold fusion - The results turned the science world upside down, but other scientists could not replicate the experiment.
Net-zero - Countries have committed to not putting more CO2 into the atmosphere than they are removing through carbon capture. This is also known as carbon neutral.