6.4 Nuclear and Particle Physics

Question 1

What is an Antimatter

Answer 1

Antimatter is made up of antiparticles. Every particle has an antiparticle. Antiparticles have the same mass and rest energy but are oppositely charged. They are usually labelled with a line over the top of their symbol.

Question 2

What is the antiparticle of the proton

Answer 2

The Antiproton
It has the same mass (1.67×10-27 kg) and rest energy (938 MeV) as a proton.
It has a relative charge of -1, the opposite to a proton.
Its symbol is overline{p}

Question 3

What is the antiparticle of a electron

Answer 3

Positron
It has the same mass (9.11×10-31 kg) and rest energy (0.51 MeV) as an electron.
It has a relative charge of +1, the opposite to an electron.
Its symbol is e+.

Question 4

What is the antiparticle of a neutron

Answer 4

The antiparticle of the neutron is the antineutron.
It has the same mass (1.67×10-27 kg) and rest energy (940 MeV) as a neutron.
It has a relative charge of 0 (the opposite of 0 is also 0).
Its symbol is overline{n}

Question 5

What is the antiparticle of the neutrino

Answer 5

The antiparticle of the neutrino is the antineutrino.
It has a mass of 0, the same as a neutrino.
It has a relative charge of 0 (the opposite of 0 is also 0).
Its symbol is overline e

Question 6

What is Annihilation

Answer 6

When a particle and its corresponding antiparticle collide, they annihilate each other.
Their masses are converted into pure energy, producing a pair of gamma photons.
The energy carried away by the gamma photons must equal the total energy of the particles to begin with (kinetic energy plus rest mass energy).
So each gamma photon must carry away at least the rest mass energy of one particle.

Question 7

What is Pair production

Answer 7

Pair production is the opposite of annihilation.
Pair production is when one high energy photon spontaneously turns into a particle-antiparticle pair.
The energy of the photon must be at least the total rest mass energy of the particle-antiparticle pair it creates.

Question 8

How does the alpha-scattering experiment give evidence of a small, dense nucleus?

Answer 8

A few alpha particles bounce back. This wouldn’t happen if the positive charge in the atom was distributed evenly throughout (as in the Plum Pudding Model), which suggests they must be hitting a dense positive charge. The fact it only happens to a very small number of alpha particles shows the nucleus must be small.

Question 9

What are the main constituents of an atom?

Answer 9

● Proton
● Neutron
● Electron

Question 10

How many times bigger is an atom than a nucleus?

Answer 10

Approximately 100,000 times.

Question 11

What is the letter associated with a proton number?

Answer 11

Z.

Question 12

What is a nucleon?

Answer 12

A particle that makes up the nucleus: a protons or a neutron.

Question 13

What letter represents nucleon number?

Answer 13

A.

Question 14

What is the definition of an isotope?

Answer 14

Isotopes are atoms of an element (with the same number of protons) with a different number of neutrons (and therefore a different mass number).

Question 15

What is the strong nuclear force?

Answer 15

The force that holds the nucleus together. It must overcome the electrostatic force of
repulsion between protons, but not so much as to cause the nucleus to collapse.

Question 16

Describe the range of the strong force.

Answer 16

Repulsive up to 0.5fm.

Attractive up to 3fm.

Question 17

What is the equation relating the radius of an atom and its nucleon number?

Answer 17

r = r0 A1/3

Where r = radius, r0 = constant (for all atoms), A = nucleon number

Question 18

Which has higher density: an atom or a nucleus?

Answer 18

A nucleus is much more dense than an atom because the atom includes a lot of empty space.

Question 19

Give a difference and a similarity between particles and antiparticles

Answer 19

Similarity: Mass.
Difference: Charge (eg. for protons/anti-protons).

Question 20

What is the name of the antiparticle of an electron?

Answer 20

Positron.

Question 21

What is a hadron?

Answer 21

A type of particle which is affected by the strong nuclear force.

Question 22

What are hadrons made of?

Answer 22

Hadrons are made up of quarks.

Question 23

What are the classes of hadrons?

Answer 23

● Baryon (three quarks)

● Mesons (two quarks)

Question 24

What are two examples of baryons?

Answer 24

Protons and neutrons.

Question 25

What are the four fundamental forces?

Answer 25

● Strong nuclear
● Weak nuclear
● Electrostatic
● Gravity

Question 26

Which forces are hadrons subject to?

Answer 26

It can be all 4! (Only charged hadrons, like protons, will be subject to electrostatic forces).

Question 27

What are leptons?

Answer 27

Leptons are fundamental particles which are not subject to the strong nuclear force. (They do still interact via the weak nuclear force).

Question 28

Give some example of leptons

Answer 28

● Electron
● Muon
● Neutrino
● And their corresponding antiparticles

Question 29

What are the three types of quark?

Answer 29

● Up (u)
● Down (d)
● Strange (s)
● And their corresponding antiparticles

Question 30

State the quark composition of protons and neutrons.

Answer 30

● Proton (uud)

● Neutron (udd)

Question 31

Can Quarks can be found on their own,

in pairs or in triplets

Answer 31

Quarks are never found on their own

‘free’

Question 32

Give the charges of the up, down and strange quarks (in terms of the electron charge, e).

Answer 32

Up = +2⁄3e
Down = -1⁄3e
Strange = -1⁄3e
(The charges of corresponding antiparticles are the same number, but opposite sign).

Question 33

What is meant by beta minus decay?

Answer 33

When a neutron turns into a proton, the atom releases an electron and an anti electron neutrino.

Question 34

Which quark decays in beta minus decay? What does it turn into?

Answer 34

A down quark turns into an up quark.

Question 35

What quantities must be conserved during the decay of particles?

Answer 35

Charge, mass, baryon and lepton numbers. (And energy - but you can’t show this in a symbol equation).

Question 36

What are the defining features of radioactive decay?

Answer 36

Radioactive decay is spontaneous and random - you can’t predict when an individual nucleus will decay (or which nucleus will go next).

Question 37

What features of a nucleus might cause it to radioactively decay?

Answer 37

● Too many or too few neutrons
● Too heavy overall (too many nucleons)
● Too much energy

Question 38

Name 3 types of radiation?

Answer 38

● Alpha
● Beta (plus and minus)
● Gamma

Question 39

Order Alpha,Gamma and Beta radiation starting with the most ionising?

Answer 39

● Alpha
● Beta
● Gamma

Question 40

What is an alpha particle?

Answer 40

A particle which contains two protons and two neutrons, the same as a helium nucleus.

Question 41

Which type of radiation can only be stopped by lead or concrete?

Answer 41

Gamma.

Question 42

How far does a beta particle typically penetrate in air?

Answer 42

50cm - 1m.

Question 43

What materials would be needed to investigate whether a radioactive source was releasing alpha, beta or gamma?

Answer 43

● Alpha - paper
● Beta - ~5mm thick aluminium
● Gamma - thick lead sheet

Question 44

A particle with nucleon number, A, and atomic number, Z, undergoes alpha decay. What are the nucleon and atomic numbers of the resulting particle? (In terms of A and Z)

Answer 44

Nucleon number = A - 4

Atomic number = Z - 2

Question 45

In beta plus decay, how does the atomic number change?

Answer 45

It decreases. (A proton turns into a neutron and a positron, so mass is ‘constant’ but atomic number
decreases).

Question 46

What is the activity of a source?

Answer 46

The number of radioactive decays per second (measured in Becquerels, Bq).

Question 47

In the equation A = λN, what do each of the letters/symbols stand for?

Answer 47

A = activity
λ = decay constant
N = number of radioactive nuclei

Question 48

What is the half-life of an isotope?

Answer 48

The average time taken for the activity of a sample (or the number of radioactive nuclei) to halve.

Question 49

What is the equation linking the activity of a sample, A, at time, t, to the original activity of the sample, A0?

Answer 49

A = A0 e -yt

Question 50

What isotope is commonly used to find out how old artefacts are?

Answer 50

Carbon-14 (in radiocarbon dating).

Question 51

What equation is used to convert mass to its energy equivalent?

Answer 51

E = mc2

Question 52

What occurs when a particle and antiparticle meet?

Answer 52

● Annihilation.
● When a particle and its antiparticle meet, they will annihilate each other and releases two gamma rays.
● Two rays are released in order to conserve momentum.
● The mass of the particles will transform into the energy equivalent.

Question 53

Why does beta plus decay have a very low penetration?

Answer 53

Because it will annihilate with matter almost immediately.

Question 54

What is the mass defect?

Answer 54

The difference between the total mass of all the nucleons separately compared to the mass of the nucleus.

Question 55

Why is there a mass defect?

Answer 55

Because energy is released as the nucleons bind together into a nucleus.

Question 56

What is binding energy?

Answer 56

The energy required to separate a nucleus into its constituent parts. (This will be the same numerical value as the energy released when the nucleus binds, and is equivalent to the mass defect).

Question 57

True or false: A low binding energy per nucleon will mean that an element is more stable.

Answer 57

False: a low binding energy per nucleon means not much energy would be required to separate the nucleus (ie. it’s more likely to decay).

Question 58

What is nuclear fission?

Answer 58

Where a unstable nucleus splits into 2 smaller nuclei. Often occurs with the larger nuclei.
The binding energy per nucleon increases when fission occurs therefore the overall process releases energy.

Question 59

What is fusion?

Answer 59

When two small nuclei fuse together to create a larger nuclei. The new nucleus has a larger binding energy per nucleon than the old nuclei therefore energy is released in the process.

Question 60

Which process (fission or fusion) releases the most energy?

Answer 60

Fusion releases a lot more energy per reaction. This is because the change in binding energy is very drastic.

Question 61

Why is it difficult to make fusion occur on earth?

Answer 61

There is a large repulsion between the two positively charged nuclei, therefore a lot of energy is required to overcome the repulsion and fuse them together. It is hard to get a material that can withstand the heat and be cost effective.

Question 62

How is fission used in nuclear reactors?

Answer 62

Rods of uranium-235 absorb neutrons and become unstable and then split into two daughter nuclei. It also releases 2 or 3 more neutrons. These then go on to be reabsorbed by another uranium-235.

Question 63

What is the purpose of a moderator?

Answer 63

To slow down the neutrons so they travel slow enough to be absorbed by the uranium. They do this through elastic collisions between the moderator and the nucleus.

Question 64

Why are control rods essential for a nuclear power station?

Answer 64

They stop the chain reaction from being out of control. They absorb neutrons so that only 1 of the neutrons released in each reaction can go on to be absorbed by another uranium. If not then the nuclear reactor would overheat as too many reactions would happen at once.

Question 65

Give an example of a material that can be used as a moderator?

Answer 65

Water.

Question 66

What is a chain reaction?

Answer 66

A chain reaction is when exactly one neutron from each decay goes on to cause another decay - so the amount of energy released is constant and doesn’t increase or decrease.

Question 67

How is nuclear waste (eg. spent fuel rods) disposed of?

Answer 67

It is first stored in cooling ponds. It will then be put in sealed steel containers and potentially stored deep underground or
underwater.

Question 68

Give one environmental benefit and risk of nuclear power.

Answer 68

Benefit - no release of greenhouse gas, no contribution to global warming, doesn’t use fossil fuels. Risk - leak or escape of material can be catastrophic.