Testing Nuclear Weapons with the World's Largest Laser
© Alastair Philip Wiper“It's like a car that you've parked out in your garage for 30 years, and it's your rescue vehicle, but you can't test it until you actually need it” explains Bruno. He is telling me what the largest laser in the world is used for.
“The basic challenge that we are facing is that we have a stockpile of nuclear weapons that was designed and built many years ago, anywhere between 10 to 50 years ago. And since the early '90s, we have not been able to conduct any tests any longer. So, in the meantime, the materials age, the equipment ages, the electronics age, and we have to make sure that every year we can certify that the stockpile will work when it is needed as a deterrent or when the president makes the decision to deploy it. So, you need to have weapons that will work after 30 years of storage, that can be loaded on a missile or on a plane, and that they will function. And that is of course, a very difficult challenge without testing.”
I’m talking to Bruno Van Wonterghem, Operations Manager at the National Ignition Facility (NIF), part of the Lawrence Livermore National Laboratory in California. A critical task of the laboratory is ensuring the safety, security, and reliability of the USA's nuclear weapons through science, engineering, and technology. The last time the USA tested a nuclear bomb was in 1992, and when they made the decision to stop full-scale testing, they needed to find a way to make sure that the bombs that they had would continue to work, the people stay trained, and the physics is up to date. And that is why NIF was born.
Bruno, who earned his PhD in chemical physics in Belgium in 1987 and has worked at NIF since 1992, goes on. “The laser is used to create extreme temperatures and pressures and recreate conditions that can only be found in stars or in the interior of planets. But for the laboratory, of course, very importantly, inside a nuclear weapon.”
The laser system is about three football fields in length, about 200 meters long, 100 meters wide, and 20 meters high. “It is a monster laser. It is the largest laser ever built, and it is the first laser system engineered to be this efficient to work so reliably. And it took us 20 years to build that machine,” says Bruno.
The laser is focused on a plastic-coated pellet about the size of a pencil tip, inside a 10m wide circular chamber, surrounded by a six-foot-thick concrete wall. The lasers take 60 seconds or so to charge and then fire a pulse about 10 billionths of a second long. The energy from the laser is so intense that it causes the plastic to implode, squeezing down on the fuel inside to the width of a human hair. The temperature is raised to hundreds of millions of degrees, allowing nuclear fusion to occur. The energy released for one trillionth of a second exceeds the sun's total power on the earth's surface.
That release of fusion power leads to an important bi-product of NIF, research into nuclear fusion as a sustainable energy source. On December 5th 2022, the National Ignition Facility made an epic breakthrough in nuclear fusion research by creating, for the first time, a reaction that produced more energy than was put into it. Nuclear fusion has long been seen as the ultimate goal in sustainable energy – it has unlimited fuel resources and produces no waste – if anyone can get it to work on a large enough scale. Several experiments worldwide are working towards this goal, such as JET in the UK and the humungous, awe-inspiring ITER in France, but these experiments use extremely strong magnetic fields to initiate fusion rather than lasers. “We are aware of what they're doing,” says Bruno. “We read their papers, we review their papers sometimes, but at NIF we don't have an active collaboration, although the lab has an official effort in the magnetic fusion community. And hopefully, that can change in the future because, of course, together, we will be much stronger.”
Currently, NIF is the only facility in the world that can do what it does, but that is changing. “Several countries are currently in the process of building facilities”, explains Bruno. “France has a very similar design, and we worked with them during the design and build phase. They are only a third of the way along the facility commissioning. Russia is currently building a facility that is very similar to NIF. They claim they will start experiments soon. China is developing several laser facilities, some of which are even significantly larger than the NIF. And so, we know that our competitors are pursuing the same type of technology and may ultimately have this capability. Now, we are still significantly ahead, but of course, we must ensure we stay there.”
I had always wondered how nuclear weapons are tested when they can’t blow them up anymore, and now I have the answer. As Bruno hinted, the theory of nuclear deterrence - that we are all safer with (functioning) nuclear weapons than without them because if one side launches, they will immediately be destroyed as well – is an important “peacekeeping” goal of NIF. Given the current world situation, let’s hope it works.
I asked Bruno how the war in Ukraine affects work at the lab and was told to contact the U.S. Department of Energy for an official statement. So I did, and this is what I got:
“The U.S. government condemns the continued unprovoked and unjustified attacks by Russian military forces on Ukraine. The Department of Energy, NNSA, and its labs, plants, and sites – including Lawrence Livermore National Laboratory (LLNL) – are a key part of U.S. Government efforts to support Ukraine. LLNL’s work at NIF supporting stockpile stewardship and fusion ignition research goes on normally.”
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