Scientists Create 3.3 Trillion Degree Particle Soup to Mimic the Universe Just after the Big Bang

Scientists Measure the Temperature of the Universe Just after the Big Bang

By Clara Moskowitz edited by Lee Billings

For the past quarter-century, scientists using a particle collider on Long Island have been smashing the nuclei of gold atoms together at nearly the speed of light to create the hottest matter ever made on Earth. The soup of particles born from the collision mimics the universe as it was just after the big bang. Now researchers have at last accurately measured the temperature of this matter for the first time.

After the gold nuclei crashed, the protons and neutrons within them melted into a seething cloud of quark-gluon plasma. This inferno re-creates conditions from the dawn of time, when the universe was too hot and dense to form regular atoms—or even their ingredients such as protons and neutrons. Instead the primordial cosmic soup would have been a blazing mess of the fundamental particles called quarks, as well as gluons, which carry the strong force that binds atomic nuclei together. “These are the building blocks of the particles that make up the visible world, and we’re trying to figure out how they work,” says physicist Zhangbu Xu of Brookhaven National Laboratory and Kent State University.

The experiment took place at Brookhaven National Laboratory’s Relativistic Heavy Ion Collider (RHIC), within the STAR (Solenoidal Tracker at RHIC) detector. There, gold nuclei racing along a 2.4-mile loop reach mind-boggling speeds before they bang together and disintegrate into quark-gluon plasma. Each primordial cloud lasts for only a split second, churning out many particles as it cools, including photons (particles of light) that decay into pairs of electrons and their antimatter counterparts, positrons.

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Physicists measured the mass ranges of such particle pairs to gauge the energy of the photons that birthed them, which in turn showed the temperature at which the photons were emitted. This revealed that temperature to be an astonishing 3.3 trillion degrees Celsius (5.94 trillion degrees Fahrenheit)—roughly 220,000 times hotter than the core of the sun. The scientists reported their results in Nature Communications.

Determining this temperature will help physicists figure out when and how the fiery primeval universe transitioned from quark -gluon plasma to the building blocks of atoms. These two states are different phases of matter, akin to the more familiar solid, liquid and gas phases of everyday life. “We want to map out what you could call the most fundamental ‘phase diagram’ that we know of,” says Frank Geurts of Rice University, a spokesperson for STAR. “What could be more interesting than the phase diagram of the fundamental building blocks of the universe?”

The RHIC accelerator and its STAR experiment are in the final stages of their last run, after starting up 25 years ago. The machines will shut down in the next few months to make way for a larger facility called the Electron-Ion Collider, which is due to open in the early 2030s. Even after STAR closes, however, scientists will analyze its last batch of data over the next few years to further hone their measure of this original cosmic fire.

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