The way scientists think about fusion changed forever in 2022, when what some called the experiment of the century demonstrated for the first time that fusion can be a viable source of clean energy.
Authors
- George R. Tynan
Professor of Mechanical and Aerospace Engineering, University of California, San Diego
- Farhat Beg
Professor of Mechanical and Aerospace Engineering, University of California, San Diego
The experiment, at Lawrence Livermore National Laboratory, showed ignition : a fusion reaction generating more energy out than was put in.
In addition, the past few years have been marked by a multibillion-dollar windfall of private investment in the field , principally in the United States.
But a whole host of engineering challenges must be addressed before fusion can be scaled up to become a safe, affordable source of virtually unlimited clean power . In other words, it's engineering time.
As engineers who have been working on fundamental science and applied engineering in nuclear fusion for decades, we've seen much of the science and physics of fusion reach maturity in the past 10 years.
But to make fusion a feasible source of commercial power, engineers now have to tackle a host of practical challenges. Whether the United States steps up to this opportunity and emerges as the global leader in fusion energy will depend, in part, on how much the nation is willing to invest in solving these practical problems - particularly through public-private partnerships .
Building a fusion reactor
Fusion occurs when two types of hydrogen atoms, deuterium and tritium, collide in extreme conditions. The two atoms literally fuse into one atom by heating up to 180 million degrees Fahrenheit (100 million degrees Celsius), 10 times hotter than the core of the Sun. To make these reactions happen, fusion energy infrastructure will need to endure these extreme conditions.
There are two approaches to achieving fusion in the lab: inertial confinement fusion, which uses powerful lasers , and magnetic confinement fusion, which uses powerful magnets .
While the "experiment of the century" used inertial confinement fusion, magnetic confinement fusion has yet to demonstrate that it can break even in energy generation.
Several privately funded experiments aim to achieve this feat later this decade , and a large, internationally supported experiment in France, ITER, also hopes to break even by the late 2030s . Both are using magnetic confinement fusion.
Challenges lying ahead
Both approaches to fusion share a range of challenges that won't be cheap to overcome. For example, researchers need to develop new materials that can withstand extreme temperatures and irradiation conditions .
Fusion reactor materials also become radioactive as they are bombarded with highly energetic particles. Researchers need to design new materials that can decay within a few years to levels of radioactivity that can be disposed of safely and more easily.
Producing enough fuel, and doing it sustainably, is also an important challenge. Deuterium is abundant and can be extracted from ordinary water. But ramping up the production of tritium , which is usually produced from lithium, will prove far more difficult. A single fusion reactor will need hundreds of grams to one kilogram (2.2 lbs.) of tritium a day to operate.
Right now, conventional nuclear reactors produce tritium as a byproduct of fission, but these cannot provide enough to sustain a fleet of fusion reactors.
So, engineers will need to develop the ability to produce tritium within the fusion device itself. This might entail surrounding the fusion reactor with lithium-containing material, which the reaction will convert into tritium .
To scale up inertial fusion, engineers will need to develop lasers capable of repeatedly hitting a fusion fuel target, made of frozen deuterium and tritium, several times per second or so. But no laser is powerful enough to do this at that rate - yet. Engineers will also need to develop control systems and algorithms that direct these lasers with extreme precision on the target.
Additionally, engineers will need to scale up production of targets by orders of magnitude: from a few hundreds handmade every year with a price tag of hundreds of thousands of dollars each to millions costing only a few dollars each.
For magnetic containment, engineers and materials scientists will need to develop more effective methods to heat and control the plasma and more heat- and radiation-resistant materials for reactor walls. The technology used to heat and confine the plasma until the atoms fuse needs to operate reliably for years.
These are some of the big challenges. They are tough but not insurmountable.
Current funding landscape
Investments from private companies globally have increased - these will likely continue to be an important factor driving fusion research forward. Private companies have attracted over US$7 billion in private investment in the past five years .
Several startups are developing different technologies and reactor designs with the aim of adding fusion to the power grid in coming decades. Most are based in the United States, with some in Europe and Asia.
While private sector investments have grown, the U.S. government continues to play a key role in the development of fusion technology up to this point. We expect it to continue to do so in the future.
It was the U.S. Department of Energy that invested about US$3 billion to build the National Ignition Facility at the Lawrence Livermore National Laboratory in the mid 2000s , where the "experiment of the century" took place 12 years later.
In 2023, the Department of Energy announced a four-year, $42 million program to develop fusion hubs for the technology . While this funding is important, it likely will not be enough to solve the most important challenges that remain for the United States to emerge as a global leader in practical fusion energy.
One way to build partnerships between the government and private companies in this space could be to create relationships similar to that between NASA and SpaceX . As one of NASA's commercial partners, SpaceX receives both government and private funding to develop technology that NASA can use. It was the first private company to send astronauts to space and the International Space Station.
Along with many other researchers, we are cautiously optimistic. New experimental and theoretical results, new tools and private sector investment are all adding to our growing sense that developing practical fusion energy is no longer an if but a when.
George R. Tynan has received research funding from the US Department of Energy and the Office of Fusion Energy Sciences, and has served on numerous advisory panels to DOE and the International Atomic Energy Agency. He is slated to serve on a soon-to-be-established technical advisory board for XCimer Energy, which is a laser fusion startup, and he has some collaborations (without any funding attached) with Commonwealth Fusion Systems.
Farhat Beg receives funding from DOE and industry.
