The Age of Things: Sticks, Stones and the Universe

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Presentation transcript:

The Age of Things: Sticks, Stones and the Universe The Physics of Carbon 14 http://cfcp.uchicago.edu/~mmhedman/compton1.html

Last Time

The Basic Idea of Carbon 14 Willard F. Libby, inventor of Carbon-14 Dating

Nomenclature Different Elements Proton Carbon 12 Nitrogen 14 Neutron + Proton Carbon 12 Nitrogen 14 Neutron 6 protons 6 neutrons 6 electrons 7 protons 7 neutrons 7 electrons Electron Same Element, Different Isotopes Element: Number of Protons Isotope: Number of Neutrons (Same No. of Protons) Carbon 12 Carbon 14 6 protons 6 neutrons 6 electrons 6 protons 8 neutrons 6 electrons

Warning! Astrophysicist Talking About Nuclear Physics!

E = m c2 Why are nuclei stable? Because…. Just a number Energy Mass Any object with mass also contains a certain amount of energy

E = m c2 Same Push Why are nuclei stable? Because…. Just a number Energy Mass: Intrinsic quality of an object Determines how the object moves in response to forced More Mass Less Motion Same Push Less Mass More Motion

E = m c2 Why are nuclei stable? Because…. Just a number Energy: Mass: A conserved quantity (energy can change form, but not be created or destroyed) The potential to cause motion Mass: Intrinsic quality of an object Determines how the object moves in response to forced Less velocity, less Kinetic Energy More velocity, more Kinetic Energy

E = m c2 Why are nuclei stable? Because…. Just a number Energy: Mass: A conserved quantity (energy can change form, but not be created or destroyed) The potential to cause motion Mass: Intrinsic quality of an object Determines how the object moves in response to forced m m Energy = E Energy = E + E

Nuclear Stability Mass of Carbon-12 < Mass of 6 protons + Mass of 6 Neutrons

Since E = m c2…… Nuclear Stability Mass of Carbon-12 < Mass of 6 protons + Mass of 6 Neutrons Since E = m c2…… Energy of Carbon-12 < Energy of 6 protons + Energy of 6 Neutrons So, energy must be supplied to the nucleus to break it into its component parts. The nucleus cannot break apart on its own. A nucleus can only only decay if the products of the decay have less mass than the original nucleus

Since E = m c2…… Nuclear Stability Mass of Carbon-12 < Mass of 6 protons + Mass of 6 Neutrons Since E = m c2…… Energy of Carbon-12 < Energy of 6 protons + Energy of 6 Neutrons Mass of Initial State > Mass of Final State

Three Types of Nuclear Decay Helium Nucleus  electron  neutrino photon 

This is an allowed transformation (beta-decay) Carbon 14 Decay Nitrogen 14 Carbon 14 electron neutrino This is an allowed transformation (beta-decay) Mass of Carbon 14 > Mass of Nitrogen 14 etc. so the transformation can occur without an external source of energy

Half-Life

Half-Life 1/2

Half-Life 1/4

Half-Life 1/8

Half-Life 1/16

Another system with a half-life

Another System with a Half-life

OR A nucleus can only exist in two definite forms electron neutrino Carbon 14 Nitrogen 14 The probability the nucleus is in one of these forms has a half-life This is a nice example of Quantum Mechanics

Aside on Quantum Mechanics Similar Calculations accurately describe the probability that a Carbon-14 atom has decayed.

Similar Calculations accurately describe the probability that a Carbon-14 atom has decayed or not. Carbon 14 Nitrogen

But what if you hang around Carbon 14 “click” Nitrogen

But, what happens when the probabilities become one particular answer ? No one really knows….

R = Measuring Age with Carbon-14 Current amount of Carbon-14 Original amount of Carbon-14 R =

R = Measuring Age with Carbon-14 Current fraction of Carbon-14 Original fraction of Carbon-14 R = Amount of Carbon 14 Amount of all types of Carbon Fraction of Carbon-14 =

Carbon-14 is produced by cosmic rays Cosmic rays are nuclei that move through space at speeds approaching the speed of light.

The Origin of Carbon-14: Cosmic Rays Their origin is uncertain because they are deflected by magnetic fields.

The paths of Cosmic Rays in the galaxy

Cosmic Rays and Carbon-14 Nitrogen Atoms in Atmosphere

Cosmic Rays and Carbon-14 Violent collision between cosmic ray and nitrogen atom releases subatomic particles, including neutrons

Cosmic Rays and Carbon-14 These neutrons eventually are captured into another Nitrogen nucleus

Cosmic Rays and Carbon-14 Currently, roughly 2 Carbon-14 atoms are produced every second per square centimeter at earth’s surface Only one in 1,000,000,000,000 carbon atoms is a Carbon-14 atoms The nucleus then throws off a proton, leaving behind a Carbon-14 atom

Current fraction of Carbon-14 Original fraction of Carbon-14 Measuring Age with Carbon-14 Current fraction of Carbon-14 Original fraction of Carbon-14 R =

Measuring the current Carbon-14 fraction of objects Nitrogen 14 electron Carbon-14 is radioactive neutrino Carbon-14 has extra mass Carbon 12 Carbon 14

Measuring Carbon-14: Decay Methods Libby’s curve of knowns Libby’s Measurement system

If this rectangle represents all the Carbon-14 in an object

If this rectangle represents all the Carbon-14 in an object This square represents how much Carbon-14 actually decays in a year

Measuring the current Carbon-14 fraction of objects Nitrogen 14 electron Carbon-14 is radioactive neutrino Carbon-14 has extra mass Carbon 12 Carbon 14

Measuring Carbon-14: Direct Counting with Mass Spectrometry

In order to measure the tiny Carbon-14 content of most objects, we need Accelerator Mass Spectrometry

Next Time Correcting and using Carbon-14