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Gauge bosons are what make the fundamental forces of nature possible.
Gauge bosons are carrier particles for three of the four fundamental forces.
The only remaining fundamental force that has no known gauge boson is gravity.
The different types of gauge bosons are described below.
Gauge bosons are thought to interact with the Higgs field.
The gauge bosons, which were particles that exchange forces.
Another is a new gauge boson, with a corresponding new quantum number.
The theoretical gauge boson for gravity is called a graviton.
There are three known gauge bosons which are fundamental particles.
This coupling is induced by gauge bosons of the enlarged group.
It is also sometimes referred to as the self energy of the gauge boson (photon).
This slowing reduces the amount of kinetic energy in the gauge boson.
These four gauge bosons form the electroweak interaction among elementary particles.
The gauge bosons of the Standard Model all have spin (as do matter particles).
The gauge bosons associated with spontaneously broken symmetries are massive.
In particular, the physical W and Z gauge bosons become massive.
First, the energy starts out in the gauge boson that interacts with the Higgs field.
(We are not yet sure if gravity works through a gauge boson.)
This is the gauge boson (force-carrying particle) of weak force.
Other theoretical gauge bosons are predicted, such as gravitons for gravity.
Another possibility is for the Higgs to split into a pair of massive gauge bosons.
A gluon is a type of gauge boson.
After the gauge boson interacts with the Higgs field, it is slowed down.
Its underlying idea is that they are mediated by the exchange of spin-1 particles, the so-called gauge bosons.
In particular, this framework assumes there are no Z' or W' gauge bosons.