Miniature sun with simulated gravity could help prepare us for deadly solar storms
The tiny sun used sound waves to simulate the sun's swirling mass of plasma
Physicists have created a mini sun with its own simulated gravity to investigate the causes of extreme space weather.
The tiny sun — consisting of a superheated plasma inside a 1-inch-wide (3-centimeter) glass sphere — produced sound waves that constrained the swirling plasma much like gravity does the actual sun.
Studying this mini-sun could help scientists predict the extreme stellar events that can cause power outages, cripple the internet and even send satellites tumbling to Earth, according to a study published Jan. 20 in the journal Physical Review Letters.
"Sound fields act like gravity, at least when it comes to driving convection in gas," lead study author John Koulakis, a physicist at the University of California, Los Angeles (UCLA), said in a statement. "With the use of microwave-generated sound in a spherical flask of hot plasma, we achieved a gravity field that is 1,000 times stronger than Earth's gravity."
Solar weather gone wild
The sun is a gigantic ball of plasma whose charged ions swirl over its surface to create powerful magnetic fields. As magnetic field lines cannot cross each other, sometimes these fields knot into kinks before suddenly snapping to launch bursts of radiation called solar flares or enormous plumes of solar material called coronal mass ejections (CMEs). Once launched, CMEs travel at speeds in the millions of miles per hour, sweeping up charged particles from the solar wind to form a giant, combined wavefront that (if pointed toward Earth) can trigger geomagnetic storms.
The exact details of when and how these storms form aren't clearly known. Previous attempts to replicate the conditions in the heart of the sun have been met with mixed success, mainly because the Earth's gravity tends to disrupt the simulated effects — altering them in unforeseeable ways.
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To shed some light on the situation, the physicists trapped sulfur gas inside a glass sphere before blasting it with microwaves to transform it into a scorching plasma with a temperature of 5,000 degrees Fahrenheit (2,760 degrees Celsius). The sound waves produced by the swirling, ionized gas acted as a substitute for gravity — constraining the burning mixture into patterns remarkably similar to the plasma flows seen on the sun's surface, and to those predicted by theory. By capturing these flows on camera, scientists hope that they will gain some insight into the fundamental workings of our star.
The researchers say that their next steps will be to scale up their experiment, enabling them to more closely mirror the conditions on the sun and observe the gas swirling for longer periods of time.
"People were so interested in trying to model spherical convection with laboratory experiments that they actually put an experiment in the space shuttle because they couldn't get a strong enough central force field on the ground," study senior author Seth Putterman, a professor of physics professor at UCLA, said in the statement. "What we showed is that our system of microwave-generated sound produced gravity so strong that Earth's gravity wasn't a factor. We don't need to go into space to do these experiments anymore."
Solar activity, which astronomers have tracked since 1775, rises and falls according to a roughly 11-year cycle. Solar activity has been especially high recently, with sunspot numbers nearly twice those of NOAA predictions. The increased activity has sent waves of high-energy plasma and X-ray bursts slamming into Earth's magnetic fields, downing Starlink satellites, triggering radio blackouts and causing auroras as far south as Pennsylvania, Iowa and Oregon. With the sun's activity expected to peak in 2025, many more flares will likely lash Earth in the coming years.
The largest solar storm in recent history was the 1859 Carrington Event, which released roughly the same energy as 10 billion 1-megaton atomic bombs. After slamming into Earth, the powerful stream of solar particles fried telegraph systems around the world and caused auroras brighter than the light of the full moon to appear as far south as the Caribbean.
If a similar event were to happen today, scientists warn it would cause trillions of dollars' worth of damage, trigger widespread blackouts and endanger thousands of lives. A massive solar storm in 1989 released a billion-ton plume of gas that caused a blackout across the entire Canadian province of Quebec, NASA reported.
But this may not even scratch the surface of what our star is capable of hurling at us. Scientists are also investigating the cause of a series of sudden and colossal spikes in radiation levels recorded in ancient tree rings across Earth's history. A leading theory is that the spikes could have come from the sun whipping up solar storms 80 times more powerful than the Carrington Event, but scientists have yet to rule out some other potentially unknown cosmic source.
Originally published on LiveScience.com
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Ben Turner is a U.K. based staff writer at Live Science. He covers physics and astronomy, among other topics like weird animals and climate change. He graduated from University College London with a degree in particle physics before training as a journalist. When he's not writing, Ben enjoys reading literature, playing the guitar and embarrassing himself with chess.
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Classical Motion A very unclear and puzzling article. With a bodacious claim. The photograph leaves much to be explained. What is the circle? Why is it offset? Is sulfur gas the only thing in the sphere? Is sulfur the only element that is ionized? Is the MW cw or pulse? What F is the sound? Where is the 1000g force applied in the photograph?Reply
Can it be tuned to a higher g force? Can the same be done with other elements? Can the same principle be applied to raw naked plasma? Or just ionized gas?
If we can hold plasma in a ball at that force, it ought to help us with fusion and other containment functions. Even if it's just ionized gas, the 1000 g figure is impressive. -
billslugg I am going to speculate that the sound waves served to compress the gas from all sides at the same time, similar to what a central gravity field would do on the Sun. The time for observation would be very short.Reply -
Classical Motion Why a short time? Do you figure the compression is at a sound rate? You might be right. When I think of g, I think of steady constant rate. So it might be a cyclic g. An in and an out?Reply -
billslugg From the paper's abstract: "...a high amplitude, spherically symmetric acoustic wave in a rotating spherical bulb containing weakly ionized sulfur gas."Reply
Any "acoustic" wave has periods of high pressure and low pressure. Maybe they time their movie camera to photograph it during the high pressure pulses. Maybe they set up standing waves. Don't really know. -
Classical Motion I must have mis-understood the process. I thought they said they heated gaseous sulfur in a glass sphere, then MW radiated and ionized the gas. The sound from the hot ionized particles corralled the particles in the center of the sphere, with a simulated force of 1000 g.Reply
I assumed it was steady state as long as the MW was applied. I thought the only input was the MW. -
billslugg As I read it, the microwaves did the ionization and the sound waves did the compression. The compression stimulated convection which resulted in the flow patterns they photographed.Reply
Convection in spinning spherical conductive fluids undergoing convection is very complex. There are Coriolis forces, covective forces and magnetic forces to consider. In the Sun, the result is the 22 year solar cycle with many layers of covective cells extending from equator to poles.
Magnetic forces are particularly hard to understand since a conductive fluid moving through a magnetic field generates a current that makes a magnetic field that directly opposes the field that created it.