Chapter 12 –Radioactivity PDF

Summary

This document covers chapter 12 on radioactivity, discussing fundamental concepts such as radioactive decay, types of radiation (alpha, beta, gamma), isotopes, and their applications. It also provides historical context with figures like Henri Becquerel and Marie Curie.

Full Transcript

Chapter 12 –Radioactivity
 Course Content
Principle of Radioactivity
– Definition of radioactivity decay
– Half-life
Types of Radiation
– Alpha, beta and gamma
Isotopes
– Definition
– Applications
 Radioactivity History
In 1896, Henri Becquerel discovered, almost by accident, that
uranium can blacken a photographic plate, even in the dark.

Uranium emits very energetic radiation - it is radioactive.

Henri Becquerel (1852-1908)
In 1903, he shared the Nobel Prize in Physics with Pierre Image of Becquerel's photographic plate which
and Marie Curie "in recognition of the extraordinary has been fogged by exposure to radiation from
services he has rendered by his discovery of a uranium salt.
spontaneous radioactivity".
 Then Marie and Pierre Curie
discovered more radioactive
elements including polonium and
radium.
She used the word radioactivity
to describe the property of
certain substances to give off
invisible “radiations” that could Marie Curie (1867-1934)
be detected by films.
Scientists soon realised that
there were three different types
of radiation.
These were called alpha (α), beta
(β), and gamma (γ) rays from the
first three letters of the Greek
alphabet.
Pierre Curie (1859-1906)
 Radioactive Decay
Radioactivity – the spontaneous decomposition or
disintegration of a nucleus forming a different nucleus
and producing one or more additional particles
Radioactive decay is a process by which the nuclei of a
nuclide emit ,  or  rays.
In the radioactive process, the nuclide undergoes a
transmutation, converting to another nuclide.
Nuclear Equation – shows the radioactive
decomposition of an element
14 C → 147N + 0 e
6 -1
Nuclear Forces – strong nuclear force holds neutrons
and protons together to form a nucleus (counters
electromagnetic repulsion).
Review of Atomic Terms
Nucleons – particles found in
the nucleus of an atom
– neutrons and protons
Atomic Number (Z) – number
of protons in the nucleus
Mass Number (A) – sum of
the number of protons and
neutrons
Isotopes – atoms with
identical atomic numbers but
different mass numbers
Nuclide – each unique atom Isotope review activity
 Isotopes
Most of the isotopes which occur naturally are
stable.
A few naturally occurring isotopes and all of the
man-made isotopes are unstable.
Unstable isotopes can become stable by
releasing different types of particles.
This process is called radioactive decay and the
elements which undergo this process are called
radioisotopes/radionuclides.
 Sources of Radiation
Ionizing radiation is a natural part of our
environment.
There are two chief sources of radiation you
will probably be exposed to:
– background radiation.
– radiation from radioisotopes or medical procedures
such as x-rays.
 Background radiation
Background radiation levels
can vary widely from place to
place.
– Cosmic rays are high energy
particles that come from
outside our solar system.
– Radioactive material from
nuclear weapons is called
fallout.
– Radioactive radon gas is
present in the atmosphere.
 Radioactive Decay
Radioactive decay results in the emission of either:

an alpha particle (),

a beta particle (),

or a gamma ray().
 Alpha Decay
An alpha particle is identical to that of a helium nucleus.

It contains two protons and two neutrons.
 Alpha Decay
Alpha-particle production
Alpha particle – helium nucleus
– Examples

Net effect is loss of 4 in mass number and loss of 2 in
atomic number.
 Alpha Decay

222 A 4

86
Rn Z
Y + 2
He

222 218 4

86
Rn 84
Po + 2
He
 Beta Decay
As a result of beta decay, the nucleus has one less
neutron, but one extra proton.

The atomic number, Z, increases by 1 and the mass
number, A, stays the same.
 Beta Decay
As a result of beta decay, the nucleus has one less
neutron, but one extra proton.

The atomic number, Z, increases by 1 and the mass
number, A, stays the same.
 Beta Decay
Beta-particle production
Beta particle – electron
– Examples

Net effect is to change a neutron to a proton.
 Beta Decay
218
218 At
84
Po 85


0

-1
 Beta Decay


A A 0

Z
X Z+1
Y + -1


218 218 0

84
Po 85
Rn + -1
 Gamma Decay
Gamma rays are not charged particles like a
and b particles.
Gamma rays are electromagnetic radiation with
high frequency.
When atoms decay by emitting a or b particles
to form a new atom, the nuclei of the new
atom formed may still have too much energy to
be completely stable.
This excess energy is emitted as gamma rays
(gamma ray photons have energies of ~ 1 x 10-
12 J).
 Gamma Decay
Gamma ray release
Gamma ray – high energy photon
– Examples

Net effect is no change in mass number or atomic
number.
 Absorption of Radiation
Alpha (α) – absorbed by 2-3 cm air and thin
paper
Beta (β ) – can penetrate paper absorbed by a
few mm of metal
Gamma (γ) – very penetrating absorbed by
many cm of lead and metres of concrete
Absorption of Radiation
 Detection of Radioactivity
Geiger-Muller counter – instrument which
measures radioactive decay by registering the
ions and electrons produced as a radioactive
particle passes through a gas-filled chamber
 Detection of Radioactivity
Scintillation counter instrument which
measures the rate of radioactive decay by
sensing flashes of light that the radiation
produces in the detector
 Radioactive Half-Life
Radioactive decay depends on chance.
It is possible to predict the average behavior of
lots of atoms, but impossible to predict when
any one atom will decay.
One very useful prediction we can make is the
half-life.
The half-life is the time it takes for half of the
original sample of radioactive material to decay
to half its original
 Radioactive Half-Life
Most radioactive
materials decay
in a series of
reactions.
Radon gas comes
from the decay of
uranium in the
soil.
Uranium (U-238)
decays to radon-
222 (Ra-222).
Radioactive Half-life
 Application of Isotopes
1. Food and Agriculture
1. Fertilisers
2. Increasing genetic variability
3. Food irradiation and preservation
2. Medicine
1. Sterilization
2. Treatment of cancer
3. Diagnosis - Tracers and imaging
3. Carbon dating
4. Smoke detectors
 Note:
 See Study guide and
 website: http://www.world-nuclear.org/info/non-power-
nuclear-applications/overview/the-many-uses-of-nuclear-
technology/