Elementary particle

In particle physics, an elementary particle is a particle of which other, larger particles are composed. For example, atoms are made up of smaller particles known as electrons, protons, and neutrons. The proton and neutron, in turn, are composed of more elementary particles known as quarks. One of the outstanding problems of particle physics is to find the most elementary particles - or the so-called fundamental particles - which make up all the other particles found in Nature, and are not themselves made up of smaller particles.

Table of contents

1 Standard Model 1.1 The 12 fundamental 1.2 Antiparticles 1.3 Quarks 1.4 Gluons 1.5 Electroweak bosons 1.6 Higgs boson 2 Beyond the Standard Model 2.7 Supersymmetry 2.8 String theory 3 Links and References 3.9 Reference 3.10 See also 4 External links

Standard Model

The Standard Model of particle physics contains 12 species of elementary fermions ("matter particles") and 12 species of elementary bosons ("radiation particles"), plus their corresponding antiparticles and the still undiscovered Higgs boson. However, the Standard Model is widely considered to be a provisional theory rather than a truly fundamental one, since it is fundamentally incompatible with Einstein's general relativity. There are likely other elementary particles not described by the Standard Model, such as the graviton, the particle that would carry the gravitational force or the sparticles, supersymmetric partners of the ordinary particles.

The 12 fundamental

The 12 fundamental fermionic particles are divided into three families of four particles each. Six of the particles are quarks. The remaining six are leptons, three of which are neutrinos, and the remaining three of which have an electric charge of -1: the electron and its two cousins, the muon and the tauon.

Particle Generations
First family electron (e-) electron-neutrino (νe) up quark (u) down quark (d)		Second family muon (μ-) muon-neutrino (νμ) charm quark (c) strange quark (s)		Third family tauon (τ-) tauon-neutrino (ντ) top quark (t) bottom quark (b)

Antiparticles

There are also 12 fundamental fermionic antiparticles which correspond to these 12 particles. The positron (e⁺) corresponds to the electron and has an electric charge of +1. Its cousins are the positive muon, μ⁺, and the positive tauon, τ⁺. The antiquarks are: up antiquark , down antiquark , charm antiquark , strange antiquark , top antiquark , and bottom antiquark . The antineutrinos are: the electron-antineutrino , the muon-antineutrino , and the tauon-antineutrino .

Quarks

Quarks and antiquarks have never been detected to be isolated. A quark can exist paired up to an antiquark, forming a meson: the quark has a "color" (see color charge) and the antiquark a corresponding "anticolor". The color and anticolor cancel out, yielding black (i.e. absence of color charge). Or three quarks can exist together forming a baryon: one quark is "red", another "blue", another "green". These three colors together form white (i.e. absence of color charge). (Cf. RGB color space, complementary color.) Or three antiquarks can exist together forming an antibaryon: one antiquark is "antired", another "antiblue", another "antigreen". These three anticolors together form antiwhite (i.e. neutral). The result is that colors (or anticolors) cannot be isolated either, but quarks do carry colors, and antiquarks carry anticolors.

Quarks also carry fractional electric charges, but since they are confined within hadrons whose charges are all integral, fractional charges have never been isolated. Note that quarks have electric charges of either +2/3 or -1/3, whereas antiquarks have corresponding electric charges of either -2/3 or +1/3.

Gluons

Out of the 12 bosonic fundamental particles, eight of them are gluons. Gluons are the mediators of the strong force, and carry both a color and an anticolor. Although gluons are massless, they are never observed in detectors due to confinement; rather, they produce jets of hadrons like single quarks.

Electroweak bosons

Out of the remaining four fundamental bosons, three are weak gauge bosons: W⁺, W^-, and Z⁰; these mediate the weak force. The last fundamental boson is the photon, which mediates the electromagnetic force.

Higgs boson

Although the weak and electromagnetic forces appear quite different to us at everyday energies, the two forces are theorized to be unified as a single electroweak force at high energies. The reason for this difference at low energies is thought to be due to the existence of the higgs boson. Through the process of spontaneous symmetry breaking, the Higgs selects a special direction in electroweak space that causes three electroweak particles to become very heavy (the weak bosons) and one to remain massless (the electromagnetic photon). Although the Higgs mechanism has become an accepted part of the Standard Model, the boson itself has never been observed in detectors. This is thought to be due to the particle's great mass, but its continuing absence is a major cause of concern for particle physicists.

Beyond the Standard Model

Supersymmetry

One major extension of the standard model involves supersymmetric particles, abbreviated as sparticles, which include the sleptons, squarks, neutralinos and charginos. Each particle in the Standard Model would have a superpartner whose spin differs by 1/2 from the ordinary particle. In addition, the sparticles are heavier than their ordinary counterparts: they are so heavy that existing particle colliders would not be powerful enough to be able to detect them. However, some physicists believe that sparticles will be detected by 2008 in the Large Hadron Collider at CERN.

String theory

According to string theorists, each kind of fundamental particle corresponds to a different resonant vibrational pattern of a fundamental string (strings are constantly vibrating in standing wave patterns, similar to the way that quantized orbits of electrons in the Bohr model vibrate in standing wave patterns). All strings are essentially the same, but different particles differ in the way their strings vibrate. More massive particles correspond to more energetic vibrational patterns. But fundamental particles do not contain strings: they are strings.

String theory also predicts the existence of gravitons. Gravitons are impossible to detect experimentally, because the gravitational force is so weak compared to the other forces.

Links and References

Reference

• Brian Greene, The Elegant Universe, W.W.Norton & Company, 1999, ISBN 0-393-05858-1.

See also

• Subatomic particle
• Particle physics
• List of particles

External links

Informational

• Greene, Brian "Elementary particles". The Elegant Universe, NOVA (PBS)
• particleadventure.org: The Standard Model, Unsolved Mysteries. Beyond The Standard Model, What is the World Made of? The Naming of Quarks
• quarkdance.org ("Cute" dancing quarks with music)
• University of California: Particle Data Group
• particleadventure.org: Particle chart
• CERNCourier: Season of Higgs and melodrama
• Robert Rutkiewicz: Explaining Particle Spin

News

• 6 December, 2001, BBCNews: 'God particle may not exist Citat: "...its giant accelerator which should have shown up the presence of the Higgs found absolutely nothing - and this could mean particle physics having to revisit some of its most cherished ideas..."

Citations'

• Robert Rutkiewicz: Defining Mass Citat: "...The value of mass is not being redefined. But the concept of mass being a fundamental property is reviewed...A new physical law is postulated: All known particless are elements of momentum moving at a velocity c...This extension is based on special relativity and uses SR equation for mass..."

• The Physical Origin of Electron Spin - using quantum wave particle structure Citat: "...note that spin, and other properties, are attributes of the underlying quantum space rather than of the individual particle. This is why spin, like charge, has only one value for all particles...."

• Glimpses of a new paradigm. K.V.K. Nehru Citat: "...Dewey B. Larson introduces the new paradigm that motion is the basic and sole constituent of the physical universe, and space-time is the content—not the container—of the universe...", Dewey B. Larson (1898-1990)

• Milo Wolff: The Physical Origin of Electron Spin - using quantum wave particle structure Citat: "...The electron's structure, as well as its spin, had been a mystery. Providing a physical origin of spin for the first time is the purpose of this paper....note that spin, and other properties, are attributes of the underlying quantum space rather than of the individual particle. This is why spin, like charge, has only one value for all particles...This structure settles a century old paradox of whether particles are waves or point-like bits of matter. They are wave structures in space. There is nothing but space. As Clifford speculated 100 years ago, matter is simply, "undulations in the fabric of space". ..."

Particles in Physics - Elementary particles	Edit
Fermions : Quarks | Leptons
Gauge Bosons : Photon | W+, W- and Z0 bosons | Gluons
Not yet observed
Higgs boson | Graviton
Supersymmetric Partners : Neutralinos | Charginos | Gravitino | Gluinos | Squarks | Sleptons