Chemistry, Third edition

Nuclear and

Radiochemistry

Objectives

Defines radioactivity

Looks at the properties of nuclear radiation

Gives examples of calculations involving radionuclides and isotopic half-lifes

Discusses the uses of radioisotopes

The radioactivity of naturally occurring and artificially produced isotopes, nuclear

fission (the reactions involved in commercial nuclear reactors) and nuclear fusion

(the source of the sun’s power) are all examples of nuclear reactions (Fig. 21.1).

Radioactivity started as a scientific curiosity. From these humble beginnings devel-

oped nuclear power (the main provider of power for the generation of electricity in

some countries) and the awesome power of nuclear warheads.

Radioactivity

Radioactivity was discovered accidentally in 1896, when Antoine Henri Becquerel

(1852–1908) noticed that an uranium ore caused a photographic plate to blacken.

The uranium gave off invisible ‘rays’ which were similar to the X-rays discovered the

previous year. Forty-nine years later, doctors in Hiroshima reported that previously

unexposed X-ray plates in hospital vaults had been fogged by the radiation emitted

by the first atomic bomb.

Pioneering work in radioactivity was carried out by the husband and wife team of

Pierre and Marie Curie, who (in 1898) extracted the elements polonium and radium

from an ore called pitchblende. The harmful effects of nuclear radiation were then un-

known, and even today their laboratory notebooks remain dangerously radioactive.

21.1

Contents

21.1Radioactivity 399

21.2Radionuclides and

radioisotopes 401

21.3More about nuclear

radiation 402

21.4Mathematics of

radioactive decay 403

21.5Uses of

radionuclides 405

21.5Revision questions 410

Fig. 21.1The main types of nuclear reaction.

Nuclear fusions

Nuclear reactions Nuclear Fissions

Radioactive decay

21

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