M6, C4 Nuclear and Particle Physics

Question 1

what are the relative charges of:

• proton
• antiproton
• neutron
• antineutron
• electron
• positron
• neutrino
• antineutrino

Answer 1

• proton: +1
• antiproton: -1
• neutron: 0
• antineutron: 0
• electron: -1
• positron: +1
• neutrino: 0
• antineutrino: 0

Question 2

what are antiparticles

Answer 2

each particle type has a corresponding antiparticle with the same mass but the opposite charge

Question 3

what is a neutrino

Answer 3

symbol is v
mass and relative charge are 0
lepton
only take part in weak interactions

Question 4

what is the symbol for an antiproton

Answer 4

_

p

Question 5

whats the symbol for a positron

Answer 5

e+

Question 6

what are hadrons

give examples

Answer 6

they are made up of quarks

eg. protons and neutrons

Question 7

what does a neutron decay into

Answer 7

a proton, an electron and an antineutrino

Question 8

what are leptons

give examples

Answer 8

they are fundamental particles (can’t be split into smaller particles)
eg. electrons and neutrinos

Question 9

what’s the antiparticle of an electron

Answer 9

positron

Question 10

what are quarks

Answer 10

they are the building blocks for hadrons like protons and neutrons
there are 6 flavours

Question 11

what is the symbol and charge of the 3 anti-quarks, anti-up, anti-down and anti-strange?

Answer 11

anti-up: u with a line on top and a charge of -2/3e

anti-down: d with a line on top and a charge of +1/3e

anti-strange: s with a line on top and a charge of +1/3e

Question 12

what quarks are protons made of

Answer 12

2 up quarks and 1 down quark because

2/3 + 2/3 -1/3 = +1

Question 13

what quarks are neutrons made of

Answer 13

1 up quark and 2 down quarks
2/3 + -1/3 + - 1/3
= 2/3 - 1/3 - 1/3 = 0

Question 14

what are mesons

Answer 14

made of one quark and one anti-quark

Question 15

what is the conservation of charge

Answer 15

in any particle reaction, the total charge after the reaction must equal the total charge before the reaction

Question 16

identify the missing quark and name the particle

uus -> ?dd + u(d with a line on top)

Answer 16

uus = 2/3 +2/3 - 1/3 = +1
?dd = ? - 1/3 -1/3 = ?-2/3
ud with a line on top = 2/3 + 1/3 = +1

+1 = ?-2/3 +1
? = +2/3
this is an up quark

the particle is therefore ‘udd’ which is a neutron

Question 17

what is einstein’s mass-energy equation and what does it mean

Answer 17

∆E = ∆mc^2

energy can turn into mass and mass can turn into energy

Question 18

The mass of a proton at rest is 1.673 X 10^-27 kg.

Calculate the energy that would be released if this proton were completely converted into energy.

Answer 18

∆E = ∆mc^2

=1.673 X10^-27 X (3 X 10^8)^2
= 1.51 X 10^-10 J

Question 19

what nuclear forces are hadrons subject to?

what nuclear forces are leptons subject to?

Answer 19

all hadrons are subject to both the strong nuclear force and the weak nuclear force

all leptons are subject to the weak nuclear force but not the strong nuclear force

Question 20

what was the Rutherford alpha-scattering experiment

Answer 20

a stream of alpha particles from a radioactive source was fired at a thin gold foil
flashes of light were produced and Geiger and Marsden counted these flashes
most alpha particles went straight through but a few scattered at angles greaters than 90 degrees

Question 21

what conclusions did Rutherford conclude from the alpha scattering experiment with the alpha particles being sent through a thin gold foil

Answer 21

• most of the alpha particles went straight through the foil so the atom is mainly empty space
• some alpha particles were deflected through large angles so the centre of the atom must have a highly positive charge to repel them
• very few particles were deflected by angles greater than 90 degrees so the nucleus must be tiny
• most of the mass must be in the nucleus since the fast alpha particles were deflected backwards by the nucleus

Question 22

what is the actual charge of a proton

Answer 22

+1.6 X 10 ^-19 C

Question 23

what is the diameter of an atom

Answer 23

0.1 nm

Question 24

what is the diameter of a nucleus

Answer 24

a few femtometres

1 fm = 1 X 10^-15 m

Question 25

what are the particles that make up the nucleus called

Answer 25

nucleons

Question 26

what are the forces in the nucleus

Answer 26

The electrostatic force which causes the positively charge protons to repel each other
The gravitational force which causes all the nucleons in the nucleus to attract each other due to their masses (this is tiny compared to the electrostatic force)

therefore there has to be another force called the strong nuclear force

Question 27

what’s been discovered about the strong nuclear force

Answer 27

overcomes the electrostatic force
it has a short range - it can only hold nucleons together when they are separated by up to a few femtometres (the size of a nucleus)
the force is between all nucleons regardless of whether they are protons or neutrons

Question 28

what does the graph that compares the electrostatic and strong nuclear force show

Answer 28

• the strong nuclear force is repulsive for very small separations of nucleons (below 0.5fm)
• as nucleon separation increases past 0.5 fm, the strong nuclear force becomes attractive. it reaches a max attractive value then falls rapidly to 0. after 3 fm it can no longer hold nucleons together
• the electrostatic repulsive force extends over a much larger range

Question 29

calculate the electrostatic, repulsive force between 2 protons using the equation:
F=q^2/(4πε_0 r^2 )

Answer 29

ε_0 = 8.85 X 10^-12 (in equation sheet)
r = 2 X 10^-15m (because that is the distance between 2 protons approx.)

(1.6X10^-19)^2 / 4π X 8.85X10^-12 X (2X10^-15)^2

= 57.5 N

Question 30

calculate the attractive force between 2 protons using the equation:
F = Gm^2/r^2

Answer 30

G = 6.67 X 10^-11 (in equation sheet)
m = 1.673 X 10^-27 (mass of proton given in equation sheet)
r = 2 X 10^-15m (because that is the distance between 2 protons approx.)

6.67X10^-11 X (1.673X10^-27)^2 / (2X10^-15)^2
= 4.67 X 10^-35 N

Question 31

describe pair production with a proton

Answer 31

If you fire two protons at each other at a high speed, you’ll end up with a lot of energy at the point of impact.

This energy might be converted into more particles

When energy is converted into mass you get equal amounts of matter and antimatter
eg. if an extra proton is formed then there will be an antiproton

Question 32

what conditions have to be there for a photon to undergo pair production

Answer 32

one photon needs enough energy to produce that much mass (eg. a gamma ray photon)
tends to happen near a nucleus, which helps conserve momentum

Question 33

describe pair production with a photon

Answer 33

if a photon has the minimum energy equal to the energy of the 2 particles at rest it can produce an electron-positron pair

Question 34

in photon pair production how do you calculate the minimum energy of the photon

Answer 34

the particle and antiparticle have the same mass so it would equal 2M
E = mc^2
so the minimum energy of a photon would be:
E = 2mc^2

Question 35

in photon pair production, how do you calculate the maximum wavelength or the minimum frequency of the photon

Answer 35

use E = hc/wavelength = hf
E = 2mc^2

max wavelength = hc / 2mc^2 = h/2mc

min frequency = 2mc^2 / h

Question 36

Calculate the minimum energy photon must have to produce an electron-positron pair

Calculate the minimum frequency of this photon

Answer 36

mass of an electron and a positron= 9.11 X 10^-31
E = 2mc^2
= 2 X 9.11X10^-31 X (3X10^8)^2
= 1.64 X 10^-13 J

f = E / h
=1.64X10^-13 / 6.63X10^-34
= 2.47 X 10^20 Hz

Question 37

what is annihilation

Answer 37

when a particle meets an antiparticle, all the mass of them both gets converted to energy, in the form of a pair of photon.

Question 38

A neutron and antineutron collide and annihilate.
Calculate the minimum energy of one of the photons produced.

(mass of a neutron = 1.675 X 10^-27 kg)

Answer 38

E = mc^2

=1.675X10^-27 X (3X10^8)^2
= 1.51 X 10^-10J

Question 39

what is quark confinement

Answer 39

you can’t get a quark by itself
if you blasted a proton with lots of energy, a single quark wouldn’t be removed
the energy that you supplied would just get changed into a quark-anti-quark pair

Question 40

what is the proton number

what is its symbol

Answer 40

the number of protons in an atom’s nucleus
aka atomic number
symbol Z

Question 41

what is the nucleon number

what is its symbol

Answer 41

aka mass number
symbol A
how many protons and neutrons are in the nucleus

Question 42

what are isotopes

Answer 42

atoms with the same number of protons but different number of neutrons
this affects the stability of the nucleus

Question 43

what does this equation mean

R = r_0A^1/3

Answer 43

nuclear radius = the constant r_0 X nucleon number ^ 1/3

Question 44

how would you work out the mean nuclear density

Answer 44

density = mass / volume
volume = 4/3πr^3

Question 45

what does the constant r_0 equal

Answer 45

1. 4 fm

1. 4X 10^-15 m

Question 46

why is the weak nuclear force important in terms of quarks

Answer 46

it’s an interaction that can change one flavour of quark into another

Question 47

define radioactive decay

Answer 47

when an unstable nucleus attempts to reach a more stable state through the release of excess energy

Question 48

why is nuclear decay spontaneous

Answer 48

• the decay of a particular nucleus is not affected by the presence of other nuclei
• the decay of nuclei cannot be affected by chemical reactions or external forces eg. temperature & pressure

Question 49

why is nuclear decay random

Answer 49

• cannot predict when particular nuclei in a sample will decay
• each nucleus in the sample has the same chance of decaying per unit time

Question 50

what happens to the mass and atomic number during alpha decay

Answer 50

mass number decreases by 4

atomic number decreases by 2

Question 51

what is an alpha particle

Answer 51

a helium nucleus

consists of 2 protons and 2 neutrons

Question 52

how is a beta particle formed

Answer 52

very fast moving electron that is formed when a neutron decays
the neutron produces a proton and a electron
the proton is held in the nucleus but the electron is ejected (making a beta particle)

Question 53

what happens to the mass and atomic number during beta minus decay

Answer 53

mass number doesn’t change

atomic number increases by 1

Question 54

how could a nucleus become unstable

Answer 54

• too many neutrons
• too few neutrons
• too many nucleons (too heavy)
• too much energy in the nucleus

Question 55

describe the two types of beta radiation

Answer 55

beta minus - electron with a negative charge is produced

beta plus - electron with a positive charge (positron) is produced

Question 56

what is a positron and what happens when it collides with an electron

Answer 56

annihilation

their mass is converted into electromagnetic energy in the form of 2 gamma photons

Question 57

create a quark model for beta minus decay

Answer 57

udd -> uud + (the electron is fundamental so isn’t made of quarks
the ud can cancel on both sides

so
d -> u + e^- + anti-electron neutrino

Question 58

give examples of hadrons

what forces are they subject to

Answer 58

protons and neutrons

strong nuclear force and the weak nuclear force

Question 59

what force are leptons subject to

Answer 59

weak nuclear force

Question 60

what is background radiation

where does it come from

Answer 60

low level of radiation that surrounds us at all times

made from naturally occurring isotopes, cosmic radiation from space and man-made sources from industry or medicine

Question 61

when investigating radiation, what precautions should you take

Answer 61

• radioactive substance should be kept in a lead-lined box when not being used
• only pick up radioactive substance using long-handled tongs or forceps
• do not point substance at anyone and keep a safe distance away

Question 62

how do you measure the count rate of a radioactive source

Answer 62

1) calculate the background count rate over 30s
2) Place radioactive source in front of Geiger-Muller tube so a high number of counts are detected
3) Take 3 sets of count measurements for three 30s intervals and find the mean
4) Subtract the background count rate from the value to get the count rate of the source

Question 63

what’s the decay equation for beta plus decay

Answer 63

proton -> neutron + positron + neutrino

Question 64

what is being decayed in beta minus decay vs beta plus decay

Answer 64

beta minus is a neutron decaying

beta plus is a proton decaying

Question 65

put beta plus decay in a quark model

Answer 65

uud -> udd +positron +neutrino

u -> d + positron + neutrino

Question 66

what fundamental forces are involved in beta decay

Answer 66

The weak interaction is responsible for beta decay.

It changes one flavour of quark into another.

Question 67

what is gamma radiation

how does it change the mass and atomic number

Answer 67

Does NOT change mass or atomic number

they are high frequency EM waves

Question 68

describe the ability to penetrate matter for alpha, beta and gamma radiation

Answer 68

alpha - 1 sheet of paper, a few cm of air or skin

beta - approx. 1m of air or a few mm of aluminium

gamma - approx., a few cm of lead or several m of concrete

Question 69

what is ionisation ability and which radiation is the most/least ionising

Answer 69

ionisation ability - the ability to knock electrons off an atom

alpha - highly ionising
beta- moderate (low mass:charge ratio)
gamma - very low (has no charge and no mass)

Question 70

describe the nature of alpha, beta plus, beta minus and gamma radiation

Answer 70

alpha - helium nucleus (2 protons and 2 neutrons)
beta minus - fast moving electron
beta plus - fast moving positron
gamma - high energy EM wave

Question 71

describe the deflection due to E-fields in alpha, beta minus, beta plus and gamma radiation

Answer 71

alpha - slightly deflected towards negative charge
beta minus - greatly deflected towards positive charge
beta plus - greatly deflected towards negative charge
gamma - no deflection

Question 72

describe the deflection due to B-fields in alpha, beta minus, beta plus and gamma radiation

Answer 72

alpha - deflection opposite to beta minus but not as great

beta - greatly deflected. minus and plus in opposite directions

gamma - no deflection

Question 73

define half life

Answer 73

the time it takes for half the radioactive nuclei in a sample to decay

Question 74

define decay constant

Answer 74

the probability that an individual nucleus will decay per unit time interval

Question 75

define activity

Answer 75

the rate at which nuclei decay

units Bq which is equivalent to s^-1

Question 76

what does the equation A = λN mean

Answer 76

activity = decay constant X number of undecayed nuclei

Question 77

what does the equation A = A_0e^-λt mean

Answer 77

activity after time t = start activity X e^-decay constant X time

make sure units are in seconds

Question 78

what does the equation N = N_0e^-λt mean

Answer 78

number of undecayed nuclei = start number of undecayed nuclei X e^-decay constant X time

Question 79

what does the equation T_0.5 = ln2 / λ mean

Answer 79

half life = ln2 / decay constant

Question 80

a radioactive source emits beta particles
it has activity of 2.8X10^7 Bq
estimate the number emitted in the time interval 2 mins

state one assumption made

Answer 80

1Bq = 1s^-1
2mins = 120s
N = At
= 2.8X10^7 X 120 = 3.36 X 10^9

Assumption: the beta particles are emitted constantly

Question 81

describe the technique of radioactive dating

Answer 81

High speed protons in cosmic rays from space collide with atoms in the upper atmosphere to produce neutrons.
These neutrons collide with nitrogen-14 nuclei in the atmosphere to form carbon-14 nuclei.
C-14 eventually emit beta minus particles and become N-14 again so amount of N-14 in the atmosphere is replenished.

Question 82

what are the limitations of radioactive dating

Answer 82

assumes ratio of C14 atoms to C12 atoms remains constant over time
increased emission of CO2 may have reduced the ratio as would other events such as volcanic eruptions, nuclear weapon testing and nuclear disasters

Question 83

the half life of an isotope is 60 minutes. Calculate how long it takes for the activity to fall to 70% of its original value

Answer 83

let A_0 = 1 
so A = 0.7

λ = ln2 / 60 = 0.01155

A=A_0e^-λt
0.7 = e^-0.01155t
ln0.7 = -0.01155t
t = 30.87
= 31 mins

Question 84

How do you date rocks?

why can’t you use carbon

Answer 84

Can’t use carbon because it’s half life isn’t long enough

Instead you use Rb-87 which emits beta minus and decays to stable Sr-87 (strontium)

(the half life for Rb is 49 billion years)

Question 85

in nuclear reactions, what quantities must be conserved

Answer 85

proton number
nucleon number (mass number)
energy/mass

Question 86

the mass of the constituent parts of the nucleus (protons and neutrons) is always ________ than the mass of the nucleus

Answer 86

greater

Question 87

why is energy/mass conserved in nuclear reactions

Answer 87

work is done to separate the nucleons

this energy is converted into the gain in mass

Question 88

define the unified atomic mass unit

Answer 88

unit of MASS (u)
one twelfth of the mass of an atom of carbon 12

in equation sheet

Question 89

What does the equation E = mc^2 tell us about the relationship between the mass and energy of a system

Answer 89

The mass increases when energy is supplied to it

Energy is released when the mass decreases

Question 90

what does mass defect mean

how do you work it out

Answer 90

reduction in mass

mass of individual nucleons - mass of nucleus

Question 91

Calculate the mass defect of a helium nucleus
It's made of 2 protons and 2 neutrons 
u = 1.661 X 10^-27
mass of proton = 1.673 X 10^-27 kg
mass of neutron = 1.675 X 10 ^-27 kg

Answer 91

mass of nucleus = (protons+neutrons)u
= 4 X 1.661X10^-27 = 6.644 X 10^-27

mass of nucleons
2 X protons = 2 X 1.673 X 10^-27 = 3.346 X 10^-27
2 X neutrons = 2 X 1.675 X 10^-27 = 3.35 X 10^-27
mass of nucleons = 3.346 X 10^-27 + 3.35 X 10^-27 = 6.696 X 10^-27 kg

mass defect = 6.696 X10^-27 - 6.644 X 10^-27 = 5.2 X 10^-29 kg

Question 92

define binding energy

Answer 92

energy needed to separate neutrons and protons from the nucleus

Question 93

what does the equation ∆E=∆mc^2 stand for in terms of binding energy

Answer 93

binding energy = mass defect X speed of light ^2

Question 94

how do you work out binding energy per nucleon

Answer 94

binding energy of nucleus / number of nucleons

Question 95

Calculate the binding energy per nucleon for Iron in mega electronvolts. It has 26 protons and 30 neutrons.
mass of neutron = 1.675 X 10^-27 kg
mass of proton = 1.673 X 10^-27 kg
mass of iron nucleus = 9.288 X 10^-26

Answer 95

Mass of nucleons = (26 X 1.673 X10^-27) + (30 X 1.675 X10^-27) = 9.3748 X 10^-26

mass defect = 9.3748X10^-26 - 9.288X10^-26 = 8.68X10^-28 kg

binding energy = 8.68X10^-28 X (3X10^8)^2 = 7.812 X10^-11 J

there are 56 nucleons so binding energy per nucleon = 7.812X10^-11 / 56 = 1.4 X10^-12 J

= 8.7 MeV

Question 96

what does the graph look like for binding energy per nucleon (y axis) and mass number (x axis)

Answer 96

steep line upwards up until mass number = 56

then gradual line downwards

Question 97

explain the binding energy graph

Answer 97

the first part of the graph which is increasing is nuclear fusion
this leads up to mass number of 56 which is iron. this is the most stable isotope.
the downwards part of the graph is nuclear fission. the arrow points upwards to 56Fe

energy is released in both nuclear fission and fusion

Question 98

Explain why energy is released if 2 light nuclei combine to produce a heavier one. What is the process called?

Answer 98

this is nuclear fusion
If 2 light nuclei fuse, final binding energy per nucleon is greater than the original nuclei therefore energy is released

Question 99

Explain why energy is released is a heavy nucleus splits into 2 lighter ones. What is this process called?

Answer 99

this is nuclear fission
A large nucleus splits into 2 fragments which have a greater binding energy per nucleon than the original nucleus so again energy is released

Question 100

why doesn’t nuclear fission occur when the mass number is lower than 56 and fusion when the mass number is greater than 56?

Answer 100

The products will have a smaller binding energy per nucleon so would require an input of external energy.

Question 101

in nuclear fission how many neutrons are released

Answer 101

2 or 3

Question 102

why is nuclear fission said to have a 1-to-1 relationship

how the reaction controlled

Answer 102

1 neutron will get absorbed by 1 uranium nucleus

it is a controlled chain reaction
it is controlled by control rods made of boron

Question 103

name 2 fissile materials

Answer 103

uranium-235

plutonium-239

Question 104

why is a chain reaction formed in a fission reactor

Answer 104

the fission reactions produce neutrons which then induce other nuclei to fission, which produce more neutrons which induce more fission and so on

Question 105

what is the importance of a moderator in a fission reactor

Answer 105

fuel rods need to be placed in a moderator to slow down and/or absorb neutrons
keeps reaction going at a steady rate

Question 106

what is the critical mass in a fission reactor

Answer 106

the amount fuel you need for a chain reaction to continue at a steady rate

Question 107

how do control rods control a nuclear fission chain reaction

what are they made of

Answer 107

they limit the number of neutrons in the reactor
they absorb neutrons so that the rate of fission is controlled
usually made of boron

Question 108

what is the use of the coolant in a fission reactor

Answer 108

it transfers heat in the reactor

heat is transferred to another coolant, usually water, which produces steam

Question 109

how is high level waste dealt with from a fission reactor

Answer 109

These products are very hot and highly radioactive.

The material is placed in a cooling pond until the temp falls to a safe level. It’s then stored in sealed containers in specialist facilities which are deep underground. It’s kept there until its activity has fallen sufficiently for it to be considered safe.

Question 110

why is a leak of radioactive material from a fission reactor dangerous for us and the environment

Answer 110

it could enter our water supply and food chain
if radiation reaches a cell it can ionise atoms inside it which can kill the cell
it can also cause a mutation in the cell’s DNA which can result in cancer

Question 111

define thermal neutron

Answer 111

a neutron in a nuclear reactor that has been slowed down enough by a moderator that it can be captured by uranium nuclei (or other fissionable nuclei)

Question 112

what happens during nuclear fusion

what conditions have to be present in order for it to happen

Answer 112

Two nuclei combine to make a larger nucleus.
The nuclei have to be moving very fast to overcome the electrostatic repulsion between them and get close enough for the strong interaction to bind them.
This means there has to be much higher temperatures and higher pressures.

Question 113

give an example of a nuclear fusion reaction that happens in the sun (hydrogen to helium)

Answer 113

2,1 H + 1,1 H -> 3,2 He + energy

(deuterium + hydrogen -> helium isotope + energy

Question 114

why is lots of energy released during nuclear fusion

Answer 114

the new, heavier nucleus has a much higher binding energy per nucleon

Question 115

what types of neutrons are needed to cause fission of uranium-235 and why

Answer 115

thermal neutrons because otherwise they are travelling too fast and bounce off

Question 116

what’s the reaction when deuterium and tritium fuse

Answer 116

forms helium + neutron + energy

Question 117

what extreme conditions exist in the sun to allow for fusion to happen

Answer 117

temperature of the core is very high (15 million kelvin)

extremely high density (150,000 kgm^-3)

Question 118

define the decay constant

Answer 118

the probability of decay of a nucleus per unit time