This is how these machines work, and why they're important.

The Titan supercomputer comes in as the fifth fastest machine in the world.

Twice a year, an organization called the TOP500 publishes a list of the world’s fastest supercomputers. It is a ranking of the most powerful machines in the world—mammoth installations with names like Sunway TaihuLight and Tianhe-2. Those are both Chinese computers, and the former is the world’s fastest. The most recent version of the list came out on Monday, and the top five supercomputers hail from China, Switzerland, Japan, and the United States.

But while the ranking is a timely who’s who of brawny computers—and right now, China dominates the list, with 202 of the top 500—its publication is also a good time to ask: what makes a supercomputer a supercomputer, and what do they do scientists use them for?

“A supercomputer is a large machine designed to focus its power on a single problem,” says Bill Gropp, who runs the National Center for Supercomputing Applications at the University of Illinois, home to a machine called Blue Waters. In other words, a large server farm might be powering your Gmail experience or streaming your Netflix, but its computing power is focused on many individual tasks, not a single, complex one.

And importantly, supercomputers are meant to handle problems that can be broken down into smaller pieces—but pieces that don’t remain in isolation. “Those pieces have to communicate with their neighbors,” Gropp says.

To picture what one looks like, imagine refrigerator-sized cabinets that pack layers of components, like processors, in them. Big ones can take up thousands of square feet.

The top supercomputers are ranked using a metric called flops, which stands for floating point operations per second—a measurement of how fast it can do math equations. The Sunway TaihuLight machine topped out at 93 petaflops, which is 93 quadrillion flops. The fastest U.S. machine on the list is called Titan, and it clocks out at over 17 petaflops. (Just don’t confuse them with belly flops, which are totally different and much less useful.)

"We’re studying nature at a very high resolution, atom by atom."

The world on silicon
Think about the complexity of the natural world—the way molecules interact, a tornado forms, or the path a hurricane takes. Simulating that digitally takes a lot of computing power.

Steve Scott, the chief technology officer at Cray Inc—which makes supercomputers—says that the powerful machines play a role in the scientific process. “Basically what computers are doing is simulating the natural world,” he says.

For example: consider HIV. That virus is wrapped in something called a capsid, which is comprised of 1,300 proteins. To better understand the interplay between the capsid and the cell the virus enters, Juan Perilla, an assistant professor of chemistry and biochemistry at the University of Delaware, used two supercomputers to run a simulation. One of those was Titan, at Oak Ridge National Laboratory. Another was Blue Waters, in Illinois.

The simulation produced so much data—almost 100 terabytes—they needed Blue Waters again just to crunch it.

He laughs when asked if it was something they could have done without a supercomputer. “It would have taken a couple lifetimes,” he says. “We’re studying nature at a very high resolution, atom by atom.”

Just like the interaction between a virus and a cell is complicated, so is a tornado forming from a supercell thunderstorm, a phenomenon that also took a supercomputer to simulate. And weather centers like the European Centre for Medium-Range Weather Forecasts rely on supercomputers to make predicting the weather possible, too.

The nuclear option
Besides modeling natural phenomena, supercomputers power other exploits, like figuring out how a dirty bomb, or a chemical weapon, would disperse its harmful elements in a city. “That’s actually a very computationally demanding problem,” says Scott, of Cray.

“The nuclear stockpile is maintained via simulation,” he adds. “It’s one of the most demanding problems, and one of the big drivers in the U.S. government circles for funding high-end computing.”

Look for an updated version of the list—that ranking of the machines across the world that drive science, industrial research, and national security—to be published in June of next year.