The Search for the God particle in Europe

Jack Dikian

December 2011

The Higgs Boson, nicknamed the God particle is the quantum of the theoretical Higgs field expected to have a non-zero vacuum expectation value thus, as the theory goes giving mass to every elementary particle that couples with the Higgs field, including the Higgs boson itself.

Experiments attempting to find the particle are currently being performed using the Large Hadron Collider at CERN. Now, CERN may have confirmed this theory. Scientists hunting for Higgs boson say they've found "intriguing hints" but not definitive proof that it exists, narrowing down the search and hope to reach a conclusion on whether the particle exists by next year. So if it does exist, it can help explain why there is mass in the universe.

It seems the data indicates the particle itself may have a mass of between roughly 114 and 130 billion electron volts. One billion electron volts is roughly the mass of a proton. The most likely mass of the Higgs boson is around 124 to 126 billion electron volts.

The God Particle

Jack Dikian

October 2011

The Higgs boson is sometimes referred to as "the God particle" after the title of Leon Lederman's book, The God Particle: If the Universe Is the Answer, What Is the Question?

The Standard Model of particle physics is a theory concerning the electromagnetic, weak, and strong nuclear interactions, which mediate the dynamics of the known subatomic particles. The Standard Model gives us a framework for our understanding of the fundamental particles and forces of nature.

A theory to answer why particles have the masses they do or why they have any mass at all, however, isn’t so straightforward. Back in the early 60’s Peter Higgs proposed, the idea that space is permeated by a field, similar in some ways to the electromagnetic field. As particles move through space they travel through this field, and if they interact with it they acquire what appears to be mass. The Higgs boson is thought to give all matter mass.

This is similar to the action of viscous forces felt by particles moving through any thick liquid. The larger the interaction of the particles with the field, the more mass they appear to have. Thus the existence of this field is essential in Higg's hypothesis for the production of the mass of particles. As well as possibly explaining how particles receive their mass, some think it could also explain how the universe got its shape.

A theory put forward by researchers at Switzerland's École polytechnique fédérale de Lausanne argue that the Higgs boson might allow us to account for inflation, the otherwise unexplained process in which the early universe grew by a factor of at least 10^26 in an instant.

The Higgs boson is, however, the only elementary particle in the Standard Model that has not yet been observed in particle physics experiments.