Nuclear physics

Question 1

Activity

Answer 1

The rate of decay of the radioactive nuclei in a given isotope. It is proportional to the total number of nuclei in the sample and is measured in Becquerels.

Question 2

Alpha decay

Answer 2

The emission of an alpha particle (2 protons and 2 neutrons) from an unstable nucleus (usually one with too much mass) to make it more stable. Alpha radiation is strongly ionising and is stopped by a few centimetres of air or a sheet of paper.

Question 3

Atomic mass unit

Answer 3

A unit used to express atomic masses. One AMU is equal to one twelfth of the mass of a carbon atom.

Question 4

Background radiation

Answer 4

Radiation that is found in small quantities all around us. It originates from natural sources such as rocks and cosmic rays as well as man-made sources such as nuclear accidents and medical sources.

Question 5

Beta decay

Answer 5

The emission of a beta particle when a proton turns into a neutron (or vice versa) in an unstable nucleus. Beta minus radiation is weakly ionising. Beta plus radiation is immediately annihilated by electrons.

Question 6

Binding energy

Answer 6

The amount of energy required to split a nucleus into all its separate constituent nucleons. It is equivalent to the mass defect.

Question 7

Chain reaction

Answer 7

The process of the neutrons released by a fission reaction inducing further fissile nuclei to undergo fission.

Question 8

Closest approach

Answer 8

A method of estimating a nuclear radius by firing an alpha particle at it. It involves calculating the distance at which all the alpha particle’s kinetic energy is converted to electric potential energy.

Question 9

Contamination

Answer 9

The introduction of radioactive material to another object. The object is consequently radioactive.

Question 10

Control rods

Answer 10

Rods found in nuclear reactors to absorb neutrons and control the rate of reaction. They can be raised or lowered depending on the rate required.

Question 11

Coolant

Answer 11

A substance that passes through nuclear reactors and is responsible for removing heat from the core. This heat is then used to generate energy.

Question 12

Critical mass

Answer 12

The smallest mass of fissile material required in a fission reactor for a chain reaction to be sustained.

Question 13

Electron capture

Answer 13

A process that occurs in proton-heavy nuclei, in which an electron is drawn into the nucleus, causing a proton to transition into a neutron. An electron neutrino is also produced.

Question 14

Fission

Answer 14

The splitting of a nucleus, to form two smaller daughter nuclei, neutrons and energy.

Question 15

Fusion

Answer 15

The joining of two smaller nuclei to form a larger nuclei and to release energy.

Question 16

Gamma decay

Answer 16

The emission of gamma rays from an unstable nucleus that has too much energy. Gamma radiation is only very weakly ionising but requires several centimetres of lead to be stopped.

Question 17

Half-life

Answer 17

The average time it takes for the number of radioactive nuclei in a sample to halve.

Question 18

Inverse square-law

Answer 18

A law that governs the intensity of gamma radiation. It means that the intensity of radiation at any point is inversely proportional to the square of the distance from its surface.

Question 19

Irradiation

Answer 19

The exposure of an object to radiation. The exposed object does not become radioactive.

Question 20

Mass defect

Answer 20

The difference in mass between a nucleus and the sum of the masses of its constituent nucleons.

Question 21

Moderator

Answer 21

A material in nuclear reactors that absorbs energy from fast moving neutrons, to slow them down to speeds that can be absorbed by fissile neutrons to induce fission.

Question 22

Radioactive dating

Answer 22

The use of radioactive isotopes with known half-lives to date objects. The isotope that is usually used in Carbon-14.

Question 23

Radioactive waste

Answer 23

The waste produced from the products of fission reactions. Since the waste is unstable and radioactive, it must be stored and handled carefully.

Question 24

Random nature of radioactive decay

Answer 24

Radioactive decay is random - you cannot predict when a nucleus will decay or which nucleus will decay next.

Question 25

Rutherford scattering

Answer 25

An experiment involving firing alpha particles at a thin gold foil and observing their deflections. It showed the existence and nature of the nucleus.