Nuclear Physics: An Introduction

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Nuclear Physics is concerned with the fundamental nature of matter. The central focus of this area of study is the relationships between a quantity of energy and its mass, given by E = mc2, and the fact that matter can be converted from one form (energy) to another (particles) in particle accelerators and nuclear reactors.

The results of particle accelerator experiments have led scientist to postulate the existence of three types of forces important in the nucleus: The strong force, the weak force, and the electromagnetic force. These forces are though to account for all types of interaction found in matter. The fourth force found in nature, but not in the nucleus, is the gravitational force. These forces are believed to be generated by the exchange of particles between the interacting pieces of matter. For example, the gravitational force is thought to be carried by particles called gravitons. The electromagnetic force is assumed to be exerted through the exchange of photons. The strong force, not charge related, and only effective at very short distances ( approximately10-13 cm), is postulated to involve the exchange of particles called gluons. The weak force is 100 times weaker than the strong force and seems to be exerted through the exchange of two types of large particles, the W (has a mass 70 times the proton's mass) and the Z (has a mass 90 times the proton's mass).

The particles discovered have been classified into several categories. Three of the most important classes are as follows:

  1. Hadrons are particles that respond to the strong force and have internal structure. Hadrons consist of Baryons and Mesons. A Baryon is composed of three quarks. A Meson is composed of a quark and an antiquark.
  2. Leptons are particles that do not respond to the strong force and have no internal structure.
  3. Quarks are particles with no internal structure that are thought to be the fundamental constituents of hadrons. Neutrons and protons are hadrons that are thought to be composed of three quarks each.

    Each of these main classes also contains antiparticles. For example the electron, which is a Lepton, has an antiparticle called a positron ("electron" with a positive charge).

The world of particle physics appears mysterious and complicated. For example, particle physicists have discovered new properties of matter they call "color", "charm", and "strangeness" and have postulated conservation laws involving these properties. This area of science is extremely important because it should help us to understand the interactions of matter in a more unified way.

Nucleus
Hadrons Leptons
Baryons Mesons
Protons
Neutrons
Other, short-
lived particles
Pions
Kaons
Other, short-
lived particles
Tau
Muon
Electron
Tau neutrino
Muon neutrino
Electron neutrino

Elementary Particles: Leptons and quarks
Quarks
Bottom Top
Strange Charm
Down Up

The Four Forces of Nature

  1. Gravatational Force
    weakest of the four
    acts at long range, varying by 1 / d2
    force transmitted by gravitons

  2. Electromagnetic Force
    originally two forces, electric and magnetic until they were unified into the electromangetic
    holds atoms, molecules, liquids, and solids together
    acts at long range, varying by 1 / d2
    force transmitted by photons
    studied in quantum electrodynamics (QED)

  3. Weak Nuclear Force
    this second weakest force allows matter to disintegrate and transmutate,
    beta- decay from neutrons, beta+ decay from protons
    acts at very short range
    independant of electric charge
    acts between leptons and hadrons
    acts between hadrons and other hardons

  4. Strong Nuclear Force
    holds the quarks together to form mesons and baryons
    strongest of all the forces
    acts at very short range
    force transmitted by gluons (coors of quarks)
    studied in quantum chromodynamics (QCD)


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This page was made by Erik Epp.