Using the world's most powerful particle accelerator, the Large Hadron Collider, scientists have found that the quark-gluon ...

In the very first moments after the Big Bang, the universe looked nothing like it does today. Instead of stars, atoms, or ...

The new research verifies Rajagopal’s account of the QGP, using a neutral, electrically weak particle called the Z boson as a marker to track the movement of quarks in the plasma. Since the Z boson ...

Everything you see around and is there in outer space originated from superhot quark-gluon plasma. Moments after the Big Bang, the universe was unimaginably hot, dense, and filled with freely moving ...

In its first moments, the infant universe was a trillion-degree-hot soup of quarks and gluons. These elementary particles ...

Scientists recreate the early universe to study the first liquid ever formed and uncover how quarks moved through primordial matter.

Scientists from the CMS collaboration at CERN have measured the speed of sound in the quark-gluon plasmas with record precision, a key step to understanding how matter behaved in the very early ...

According to theoretical predictions, within a millionth of a second after the Big Bang, nucleons had not yet formed, and matter existed as a hot, dense "soup" composed of freely moving quarks and ...

Dilaton (EMD) holographic QCD model combined with Bayesian analysis to conduct a detailed investigation into the ...