Bosons and Fermions are parts of Quaternion Electronic Particles. The Boson is the Quaternion Scalar part and the Fermion is the Quaternion Vector part. Quaternions are four dimensional "particles" a Boson and a three dimensional Fermion
The Quaternion Unit can be described by Q= Cos(Spin) + v Sin(Spin) where v is the unit vector. The Quaternion consists of a scalar part the Boson = Cos(Spin) and a vector part the Fermion = v Sin(Spin).
When the angle Spin = n pi/2 i
f n is a multiple of 1 then the Quaternion Unit is a positive Fermion;
If n is a multiple of 2 then the Quaternion is a negative Boson;
if n is a multiple of 3 then the Quaternion is a negative Fermion
if n is a multiple of 4, then the Quaternion is a Positive Boson.
In general Bosons are even spin angles of pi/2 and Fermions are odd spin angles of pi/2.
If the spin angel is not a multiple of pi/2 then the Quaternion is the sum of a Boson and a Fermion.
This looks like Complex Numbers. because it is. Complex Numbers are a Quaternion 2 dimensional subgroup with Boson and a single vector Fermions.
The Higgs Boson, if it exists, should be a massive point particle, so there should be nothing "in" it.
The Higgs Boson is called the "God" particle because it would help explain on of physics biggest mysteries: how gravity works. Can both God and the Higgs Boson exist? Yes, if God exists, then he could have created the Higgs Boson, like he created other particles.
We are not sure if the theorized Higgs boson is real or not. If it is, it would be provide some support to ideas about what mass (and, therefore, gravity, which is associated mass) really is. We're still looking for experimental support that the Higgs boson is real, and now that the Large Hadron Collider is up and running, all (interested) eyes are on CERN and awaiting results.
The two most prominent particle colliders that are looking for the Higgs boson are the Tevatron at FermiLab (although that one is going to close soon) and the LHC at CERN.
the sons of liberty
Yes, they are bosons. Fermions might be force carriers for supersymmetric particles if they exist but otherwise they are not.
Jordan wigner transformation is used to map the spin to Boson while holstein primikoff transformation to Fermion
Superstring theory incorporates supersymmetry, which also allows it to describe fermions. Supersymmetry, of course, is the idea that there exists a corresponding boson for every fermion and a corresponding fermion for every boson. A nice consequence of incorporating supersymmetry is that superstring theory only needs 10 dimensions to be consistent (or without logical contradictions), while bosonic string theory requires 26. The most recent version of the Superstring theory incorporates 11 dimensions.
I think perhaps your confused here somewhat. A fermion is a particle which obeys the Pauli exclusion principle; put simply two fermions can not be in the same state (i.e. have the same set of quantum no's) at the same time. Fermions cannot be broken down into anything smaller, fermions include quark's, electron's, muon's, tau's and neutrino's which are elementary i.e. not made of anything but energy Quarks make up all other particles. Bosons can be made of 3 quarks and are split into two catergorys: Baryons such as Protons, Neutrons and many other heavy particles these are effectively composite fermions as they contain 3 quarks. Or Mesons, which contain one quark and an anti quark and hence are not composite fermions.
The Navy Boson's mate is the Captain.... the Boson is the second in command...
A Z boson is fundamental particle - a gauge boson which, together with the W boson, mediates the weak nuclear force. It has a charge of 0.
A Z-boson is a fundamental particle, a gauge boson, which, together with the W-boson, mediates the weak nuclear force, and has a charge of 0.
Nicholas Boson died in 1708.
Nicholas Boson was born in 1624.
Higgs boson was created in 2011.
Thomas Boson was born in 1635.
Thomas Boson died in 1719.