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Quantum Physics - Subatomic particles

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Great books on Elementary particles

The main subatomic particles

Welcome to my Series on Quantum Physics, you can either start here or at my central hub on the subject here

Elementary particles are divided into two general categories depending upon the spin of the particle they are:

  • Fermions:
    Quarks — up, down, charm, strange, top, bottom
    Leptons — electron neutrino, electron, muon neutrino, muon, tau neutrino, tau
  • Bosons:
    Gauge bosons — gluon, W and Z bosons, photon
    Other bosons — Higgs boson, graviton

However we will NOT be discussing the Bosons except the photon as they don't really fit into the framework of this series.

Combining Quarks


The Fundamental Fermions

The standard model of Particle physics has 12 different Fermions they are as follows;

  • Leptons - electron (e-) neutrino electron (Ve), muon neutrino (Vμ), muon (μ-), , tau neutrino (VT), tau (T-)
  • Quarks - Up quark (u), Down Quark (d), charm Quark (c), Strange quark (s), top quark (t), bottom quark (b)

These also have antiparticles, which are exactly the same, just with the charge reversed, so the electron has the anti-electron known as the positron which is a positively charge electron. Take a look at the chart below at some of the physical characteristics of these particles;

Physical Characteristics of the Fermions: subatomic particles chart

A subatomic particle chat of Femions

A subatomic particle chat of Femions

Quarks:Inside the Atoms

Great Books on Quarks

Funny Cartoon

Just how Quantum Physics feels sometimes

Just how Quantum Physics feels sometimes


Due to a phenomenon known as color confinement which involves the strong force and was developed in the theory of Quantum chromodynamics (QCD), in order to prevent Pauli exclusion principle being violated (This is very vague and a hub on this will be coming soon). Quarks are never in isolation; they can only be found within hadrons (i.e protons, neutrons etc). For this reason, much of what is known about quarks has been drawn from observations of the hadrons themselves.

There are six different types of quarks, known as flavors: up (u), down (d), charm (c), strange (s), top (t) and bottom (b).

Up and down quarks have the lowest masses of all quarks and are the most stable and most common in the universe. The other quarks are much bigger, and rapidly decay into the lighter up and down quarks. Due to this, the heavier charm, strange, top and bottom quarks can only be produced in high energy collisions, such as in particle accelerators such as the LHC (Large Hadron Collider) in CERN. They are also produced in collisions involving cosmic rays.

Quarks have fractional electric charge values, either −1⁄3 or +2⁄3 times the elementary charge which is the charge of an electron (e-), depending on flavor: up, charm and top quarks have a charge of +2⁄3, while down, strange and bottom quarks have −1⁄3. The common particles (hadrons) of the neucleus of atoms i.e. the neutron and the protons are made up of three differnet quarks in different combinations. For example the proton is made up of 2 up quarks and a down quark, this can be worked out using the chart above to calculate the charges (2/3 x 2) + -1/3 = +1 the charge of the proton. So what do you think the neutron is made of? (it has a charge of 0)

Spin is an intrinsic property of quantum particles, and its direction is an important 'degree of freedom'. It is sometimes visualized as the rotation of an object around its own axis (hence the name spin), but this notion is somewhat misguided at subatomic scales because elementary particles are believed to be point-like so have no axis. Spin can be represented by a vector whose length is measured in units of h/(2π), where h is the Planck constant. The spin of a quark along any axis is always either ħ/2 or −ħ/2; so quarks are classified as 1/2 spin particles.This spin is known as spin-up or spin-down and is used throughout many of the experiments later in the series.

Leptons and Quarks




The first lepton identified was the electron, discovered in 1897. Then in 1930, Wolfgang Pauli predicted the electron neutrino to preserve conservation of energy, conservation of momentum, and conservation of angular momentum in beta decay. Pauli hypothisized that this undetected particle was carrying away the observed difference between the energy, momentum, and angular momentum of the particles. The electron neutrino was simply known as the neutrino back then, as it was not yet known that neutrinos came in different flavours.

the muon was discovered in 1936, 40 years after the electron. It was initially categorized as a meson rather than a lepton due to it's massive mass, however it was realized the muon was much more similar to the electron than other mesons, as muons do not experience the strong interaction and hence was re-catorigized. In 1962 it was proved that more than one type of neutrino exists by first detecting interactions of the muon neutrino, which earned Leon M. Lederman, Melvin Schwartz and Jack Steinberger the 1988 Nobel Prize.

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The tau was first detected in a series of experiments between 1974 and 1977. Like the electron and the muon, it too was expected to have an associated neutrino. The first evidence for tau neutrinos came from the observation of missing energy and momentum in tau decay, similar to the missing energy and momentum in beta decay leading to the discovery of the electron neutrino. The first detection of tau neutrino interactions was announced in 2000 making it the latest particle of the Standard Model to have been directly observed.

Leptons are 1/2 spin particles similar to Quarks, so see that section above for more information.

one of the most important properties of the leptons is their charges designated by Q. This charge determines how strong the electromagnetic interactions, the how strongly a particle reacts to a magnetic field and the strength of the magnetic and electrical fields created by these particles. Each group of Lepton's have a particle with a charge of -1 e.g. electron, muon and Tau and one with a charge of 0 the respective neutrino's.


Please take a look at further articles in the series or if you are really interested take a look at some of the great books listed.


MUKUNDDESHPANDE on July 11, 2017:

To be studied in deep concious.

Rudimental on December 10, 2012:

Always enjoy reading this stuff. Even the previously read stuff, in order to keep remembering/rediscovering (I'm getting old ;) It's kind of like this; if you don't use it every day, it's a tough thing to have available at the forefront of your mind. I don't know about the rest of you, but I don't carry a pocketful of fermions around with me (they tickle), so I always forget what they look like. Anyway, thanks for some fun reading. I look forward to checking out the rest of your hubs on physics as well. Thanks.

Jimikrackorn on May 22, 2012:

The comment about the observer and the observed is a useless attempt to include humans the unfolding drama that is physics.

Silly humans like to think they are at the center of everything and even claim to be created by and in the image of god.

dipless (author) from Manchester on December 23, 2011:

Thank you glad you like them :)

lundmusik from Tucson AZ on September 03, 2011:

great articles!!!!

letsfrownupsidedown on March 22, 2011:

Did you know Stephen Hawking used that cartoon in his book, The Grand Design? It's a good book. You should read it if you haven't already. It's quite funny, too.

Mat Chaduhry on January 13, 2011:

The relationship between the observer and the observed is the crux of the quantum physics.

dipless (author) from Manchester on July 30, 2010:

ptosis lol ;)

ptosis from Arizona on July 19, 2010:

'And then a miracle occurs' - One of my favorite comic - it's used for economic, religious, political - and my checking account balance!

dipless (author) from Manchester on March 03, 2010:

No problem, very glad you enjoyed it. Have you taken a look at my other physics hubs?

KenWu from Malaysia on February 25, 2010:

This is very informative, it really takes time to digest. Thanks for sharing writing up this quantum physics article. I'm always thrilled by this subject.

dipless (author) from Manchester on February 05, 2010:

Thanks back now after a short break back to writing me thinks =)

quicksand on August 09, 2009:

Oooooooooo! You've got some great hubs. Just discovered them! Need to take a day off to check them all out. :)

metaphysician on July 06, 2009:

I guess got to re-read this again, I'm a bit lost.

dipless (author) from Manchester on June 21, 2009:

No worries glad you found them interesting :)

Tom on June 12, 2009:

I came here from a link I found and in all of the articles you have written are detailed and easy to understand, thanks for making my head spin

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