Any particle that obeys Fermi-Dirac statistics and is subject to the Pauli exclusion principle

Usage examples of fermion.

The Riemann real part one-half corresponds precisely with the fermion spin of one-half.

In 1976 Daniel Freedman, Sergio Ferrara, and Peter Van Nieuwenhuizen, all then of the State University of New York at Stony Brook, discovered that the most promising were those involving supersymmetry, since the tendency of bosons and fermions to give cancelling quantum fluctuations helps to calm the violent microscopic frenzy.

If your vision could extend a little farther down the ladder of size, you would discover that the atoms are made of fermions and bosons.

The fermions, if you ever found them, would be made of quarks, which themselves occur in several different colors and several different flavors.

Exclusion Principle stated that no two fermions -electrons or quarks - could exist in the same quantum state.

Since supersymmetry ensures that bosons and fermions occur in pairs, substantial cancellations occur from the outset—cancellations that significantly calm some of the frenzied quantum effects.

Like opposite ends of a seesaw, when the quantum jitters of a boson are positive, those of a fermion tend to be negative, and vice versa.

Electrons, protons, neutrons, positrons, muons, and neutrinos all satisfy what is known as Fermi-Dirac statistics, and they are collectively known as fermions.

The classical properties of a fermion were having a spin of half a unit, obeying the Pauli exclusion principle (which kept all the electrons in an atom, and neutrons and protons in a nucleus, from falling together into the same, lowest-energy state), and responding to a 360-degree rotation by slipping 180 degrees out of phase with its unrotated version.