21 · NUCLEAR AND RADIOCHEMISTRY
More about nuclear radiation
Alpha particles
Alpha particles are doubly ionized helium atoms, i.e. helium nuclei. Since a helium
nucleus consists of two protons and two neutrons, the loss of an alpha particle from
a nucleus reduces the number of protons by two and the number of neutrons by two.
Therefore the mass number Afalls by four and the atomic number Zfalls by two.
The emission of alpha particles is represented by the general equation
Z
AX A 4
Z 2 Y
2 + 4
2 He
2
where X is the parent nuclide and Y is the daughter nuclide. Both Y^2 and^42 He^2
become electrically neutral by losing or gaining electrons from the container or the
surrounding air.
An example of alpha emission is provided by the decay of radium-226:
226
88 Ra—
222
86 Rn
2 4
2 He
2+
88 protons 86 protons 2 protons
138 neutrons 136 neutrons 2 neutrons
88 electrons 88 electrons 0 electrons
Notice that the total charge, the sum of the mass numbers, and the sum of the
atomic numbers, are equal on both sides. This is true of all nuclear equations.
Alpha particles are so bulky that they do not usually travel more than 10 cm in air.
They are easily stopped by card, brick or thin metal sheet. However, their mass and
speed (typically about 10^7 ms^1 ) means that they possess considerable kinetic
energy and so cause substantial ionisation, and if brought into close contact with
human tissue (for example, by ingestion) they usually cause much more damage
than beta or gamma radiation.
Beta particles
Beta particles are high-energy electrons which are ejected from the nucleus. Since
there are not normally any electrons in the nucleus, the beta particles must have been
produced in the nucleus during radioactive decay. It is now known that during this
process, a neutron changes into a proton and an electron. From this it follows that the
atomic number (the number of protons) of the nuclide increases by one, while the
mass number (the number of protons and neutrons) remains the same. The electron
escapes from the nucleus and is now called a beta particle. The general equation is
A
ZX Z 1
AY+
1
(^0) e
where the atomic number of the electron is (for the purposes of a balanced nuclear
equation) regarded as 1. An example of beta emission is the radioactive decay of
strontium-90:
90
38 Sr——
90
39 Y
+
1
(^0) e
38 protons 39 protons 0 protons
52 neutrons 51 neutrons 0 neutrons
38 electrons 38 electrons 1 electron
The positively charged yttrium ion will gain an extra electron from the surroundings.
Beta particles vary greatly in their energies and speeds, and (therefore) in their
penetration of matter. Some beta particles travel at speeds at 99% the speed of light,
and as a consequence penetrate several metres of air.
21.3
402
Alpha decay
Complete the equation
(^21884) Po ?? (^42) He2+
Exercise 21A
Beta decay
Complete the equation
(^21583) Bi ?? 10 e
Exercise 21B