Welcome to
Positron Physics Laboratory
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Positron Physics
"Physics is one of the oldest and most basic sciences and one which,
through its discoveries and their applications, has created many other
sciences and technologies. Much of physics today remains concerned with
most fundamental and philosophical questions. More often, however, it
takes real world problems from other areas of contemporary science and
technology and attacks them with every technology available." (Prof.
Roy N. West)
| Positron Annihilation
The positron is the antimatter particle of the electron. The two
particles have identical properties except that they have opposite
electric charges. When a positron encounters an electron, the particles
are annihilated, and their mass is converted into pure energy in the
form of gamma rays. The process is a direct demonstration of several
fundamental conservation laws of modern physics. Certain
characteristics of the process, however, can be influenced if the
particles meet in an atomic environment. As a consequence positrons can
be used as a probe for exploring the nature of matter. It turns out
that the probe is unusually sensitive and revealing when it is applied
to the regular arrays of atoms characteristic of most solids. It is
also beginning to have its uses in the study of living matter.
When a positron and an electron annihilate each other in condensed
matter (a solid or a liquid), they always give rise to two gamma ray
photons. The conversion of the particles' mass into energy exactly
follows Einstein's equation E = mc^2, in which E is the energy
liberated, m is the mass of the particles and c is the speed of light;
mass and energy are thus conserved. The sum of the positron's positive
charged (+1) and the electron's negative charge (-1) is zero. The gamma
ray photons that result from the annihilation carry no charge; charge is
thus conserved. In the annihilation events that are of interest here
the spins of the particles are antiparallel and add up to zero. The
gamma ray photons have no spin; spin is thus conserved. The two photons
each have an energy of .511 million electron volts (MeV), and they leave
the site of the annihilation in exactly opposite directions. Their net
momentum is zero; momentum is thus conserved. The annihilation process
therefore conserves energy, charge, spin and momentum. All the same,
electrons could annihilate the protons in the nuclei of atoms without
violating these laws, and if they did so, there would be no atoms.
Protons, however, are 2,000 times as massive as electrons. Electrons
can be annihilated only by antielectrons, that is, positrons. The fact
that our world exists therefore proves yet another universal law, a law
that might be called the conservation of light and heavy particles. In
short, the positron-electron system exemplifies the most basic
conservation laws found in nature. (Prof. Werner Brandt)
- Recent Topics
- Positron annihilation spectroscopy: Doppler broadening (PAS-DB)
- Positron annihilation spectroscopy: lifetime technique (PAS-LT)
- Positron annihilation spectroscopy: back-diffusion (PAS-BD)
- Two dimensional angular correlation of the annihilation radiation (2D ACAR)
- Time-selected, time-resolved, time-correlated measurements
- other related topics
Last Modified: Jan 20, 1998 by Toshikazu Kurihara(toshikazu.kurihara@kek.jp)
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