ScienceIQ.com: Cool science facts delivered daily to your email


 Facts By Category:


 » Physics
 » Astronomy
 » Chemistry
 » Biology
 » Mathematics
 » Geology
 » Engineering
 » Medicine
 » Science

  by keyword search:

    
 ScienceIQ Team:


 »Writers & Editors



Discovery Capsule: A monthly subscription box for kids featuring cool toys, specimen and STEM projects. From the makers of xUmp.com. As low as $20 per month. Sign up now at Kickstarter!

Neutrinos to the Rescue


Beta Decay Have you ever wondered what the most abundant particle in the universe is after photons of light? The answer is: Neutrinos. These tiny, neutral and almost mass-less particles that move at almost the speed of light hardly ever interact with anything in the universe. In fact about ten thousand trillion neutrinos will pass through your body by the time you are finished reading this.

The existence of neutrinos was predicted by Wolfgang Pauli in 1930. After observing the beta decay, a process where a neutron (which was not yet discovered at the time) from atom's nucleus decays into a proton and an electron, it was noticed that the energy just did not add up. Namely, there was a missing amount of energy that was a threat to the well-established law of conservation of energy. Pauli then postulated that there must be a new particle which was not seen that would carry this missing difference in energy. He named it the 'neutron'. This name did not last too long since in 1932 James Chadwick actually discovered the neutron. Fermi then renamed it a neutrino, which in Italian means: little neutral one. It was only in 1956 that Clyde Cowan and Fredrick Reines actually detected neutrinos from a nuclear power plant for the first time.

Most of the neutrinos in the universe were created during the first few seconds after the Big Bang. Thanks to their weak interaction with matter, most of those neutrinos are still around. Neutrinos are also created in nuclear power plants and in our Sun and other stars where, in the process of fusion, four protons and two electrons get fused into an atom of Helium and in the process create two neutrinos. We still know very little about these elusive particles, namely that their mass is very small (smaller than that of the electron), but we don't know exactly what that mass is. We also believe that they travel at or close to the speed of light, but again we are not sure what that speed is. Further research into neutrinos will not only answer these questions but will also allow us to peek into the early universe, to learn about the formations of stars and explosions of supernovas. The message is in the neutrinos.

About the Author


Anton SkorucakAnton Skorucak, MS
Anton Skorucak is a founder and publisher of ScienceIQ.com. Anton Skorucak has a Master of Science (MS) degree in physics from the University of Southern California, Los Angeles, California and a B.Sc. in physics with a minor in material science from the McMaster University, Canada. He is the president and creator of PhysLink.com, a comprehensive physics and astronomy online education, research and reference web site.
PhysLink.com

Further Reading
Are There Really Neutrinos?: An Evidential History
by Allan Franklin


Related Web Links
Neutrinos
by Fermi National Accelerator Laboratory

The Neutrino and the SNP
by Sudbury Neutrino Observatory





Home | About Us / Contact Us | Privacy Policy

Copyright © 2002-2014 ScienceIQ.com - All Rights Reserved