When do the world’s most powerful magnets collide?

Posted August 30, 2018 05:38:56 A new generation of high-performance magnets has been created, but the world is still reeling from the explosion of the new type of high energy magnets in the field.

The new type, called “electron” magnets, are far more powerful than previously thought, and are more than 10 times more powerful compared to ordinary magnets.

They have been used to power satellites, satellites that fly around the Earth and spacecraft.

But what makes them special is that they’re made from a very rare metal called argon.

The argon is very radioactive, and has a very high decay rate, meaning it will emit gamma rays at a very low frequency.

This has led to speculation that it could be used to create new, higher energy magnets.

However, a paper published in Nature Communications last week, which is one of the best in the world, found that there was no evidence of this happening.

What this means is that these high-energy magnets are just a theoretical possibility.

“The idea that these could exist, but not in our lifetime is an extremely surprising finding,” said lead author of the study, professor of physics at the University of Sydney, Professor Peter Dolan.

“There is no evidence for this at all.”

High-energy metals are used in everything from satellites to electric vehicles, but it’s rare to find them in their pure form.

That’s because of the high level of radioactivity they have in them.

“We thought it would be really interesting to investigate how they would behave under very high temperatures,” Professor Dolan said.

“But, as you know, these are not really radioactive.

When it comes to the argon, the authors of the paper looked at how it interacts with a group of other rare metals called platinum and gallium. “

That means we had to look for the source of the radioactivity in order to figure out how these would behave.”

When it comes to the argon, the authors of the paper looked at how it interacts with a group of other rare metals called platinum and gallium.

The researchers found that the metals would react with each other and the argons to form a new type called “gravitonium” and then form a type called an “electromagnetic gallium”.

They then looked at the properties of these two types of high intensity magnets, and found that they could produce an even higher energy.

The authors were able to create high-strength, very high-velocity magnets that could generate 1.6 times more energy than normal magnets.

Professor Dola said that the work showed that there could be a new class of high strength, very low-velocities high-intensity high-density electromagnets.

“You could theoretically use these high intensity electromagnars for high-voltage sensors, high-speed cameras, ultrafast computers,” he said.

The team are now working to see if they can find a way to make these high strength magnets more powerful, or even stronger, but they need to find a source of argon to make them.

It could be possible to make high-gravitational metals by using hydrogen as the fuel.

However Professor Dolans work has shown that this process would take hundreds of millions of years, so it’s unlikely to happen anytime soon.

“If you could make these superconducting high-gain magnets, you’d be able to build these things in a very short period of time,” he added.

“These magnets are going to be really important for satellites and for high speed satellites.”

What does this mean for us?

The research could also have a big impact on the future of space exploration.

“What we’re seeing here is a fundamental shift in our understanding of magnetism,” Professor Dan Belsky from the University.

“For the first time, we can understand what is really going on under the surface of these high energy materials.”

“The most exciting thing is that we can actually make these electromagnels using materials that we haven’t previously had a chance to study,” Professor Belski said.

While this is exciting news, Professor Dolar is not surprised.

“It’s a real step forward in our ability to do quantum computing,” he explained.

“And, even more importantly, it shows that we really don’t have to wait another 100 years before we can start looking at the very different possibilities in space exploration.”

Topics: physics-and-physics, research, science-and.science-economics, australia