18: Looking Inside the Atom

Question 1

Rutherford experiment disproved which model for the atom?

Answer 1

The Thompson model or plum pudding model

Question 2

What is the plum pudding model?

Answer 2

The model said the atoms were made up of a globule of positive charge, with negatively charged electrons sprinkled in it, like fruit and a plum pudding.

Question 3

Describe Rutherford’s experiment

Answer 3

A stream of alpha particles from a radioactive source was fired at a very thin gold foil.
Then recorded of the number of alpha particles scattered at different angles.

Question 4

What is another name for Rutherford’s model of the atom?

Answer 4

The nuclear model

Question 5

What could Rutherford conclude after his experiment?

Answer 5

The atom is mainly empty space.
The centre of the atom must have a large, positive charge. Rutherford named this the nucleus.
The nucleus must be tiny, but massive (mass).

Question 6

In Rutherford’s experiment, what was the evidence to suggest that the atom is mainly empty space?

Answer 6

Most of the fast, charged alpha particles went straight through the foil

Question 7

What did Rutherford discover about charge at the centre of the atom? How did he know?

Answer 7

He discovered the nucleus. Some of the alpha particles were deflected through large angles, so the centre of the atom must have a large positive charge to repel them.

Question 8

What are alpha particles?

Answer 8

Particles made up of two protons and two neutrons, so they have an overall positive charge

Question 9

Describe what happens when an alpha particle get close enough to the nucleus

Answer 9

The electrostatic force between the positively charged nucleus and the positively charged alpha particle results in a repulsion between the two. This is what causes some of the alpha particles to scatter

Question 10

What are the nucleons?

Answer 10

Protons and neutrons

Question 11

What value do you need when you are estimating the distance of closest approach of an alpha particle that has been fired at a gold nucleus?

Answer 11

The alpha particles initial kinetic energy

Question 12

Describe what happens when an alpha particle is deflected through 180° when fired at a gold nucleus

Answer 12

It will have momentarily stopped a short distance from the nucleus. It does this at the point where it’s electric potential energy equals its initial kinetic energy

Question 13

What value do you need to find the charge of the nucleus?

Answer 13

The atom‘s proton number, Z

Question 14

What charge does a proton have?

Answer 14

+e. Where e is the size of the charge on an electron

Question 15

What is the general formula for the charge of a nucleus?

Answer 15

+Ze

Question 16

What is the charge on an alpha particle?

Answer 16

+2e

Question 17

What holds the nucleus together? What stops the nucleus flying apart due to the overall positive charge?

Answer 17

The strong interaction force

Question 18

What are hadrons?

Answer 18

Particles feel the strong interaction e.g. protons and neutrons

Question 19

What are hadrons made of?

Answer 19

Fundamental particles called quarks. Must be more than one quark

Question 20

Name four different hadrons

Answer 20

Protons, neutrons, sigmas, mesons

Question 21

Which particle is the only stable hadron?

Answer 21

The proton

Question 22

What will all hadrons, except for protons, do?

Answer 22

Decay into other particles

Question 23

What does the neutron decay into?

Answer 23

It is an unstable particle that decays into a proton

Question 24

A neutron decaying into a proton is an example of what kind of decay? what is this caused by?

Answer 24

It is an example of beta minus decay which is caused by the weak interaction

Question 25

What is the half life of a free neutron?

Answer 25

Half life of 15 minutes

Question 26

What is a free neutron?

Answer 26

A neutron that isn’t held in the nucleus

Question 27

Describe leptons

Answer 27

They are fundamental particles that don’t feel that strong interaction. They interact with other particles via the week interaction and gravity (and the electromagnetic force if they’re charged)

Question 28

What are the two types of lepton we need to know about and what are the symbols?

Answer 28

Electrons and neutrinos

e and ν (nu)

Question 29

Describe neutrinos

Answer 29

They have zero, or almost 0, mass and zero electric charge – so they don’t do much. Neutrinos only take part in week interactions. They can pass right through Earth without anything happening to it

Question 30

What is lepton number?

Answer 30

The number of leptons

Question 31

What is conserved in a particle reaction?

Answer 31

Lepton number and baryon number

Energy, charge and momentum

Question 32

Classifying particles: if there is only one fundamental particle what can it be?

Answer 32

A fermion or a boson

Question 33

Classifying particles: if the are more than one fundamental particle what is the particle?

Answer 33

Composite

Question 34

Classifying particles: what two types of fermion can you have?

Answer 34

Leptons and quarks

Question 35

Classifying particles: What is a composite particle composed of quarks called?

Answer 35

Hadron

Question 36

Classifying particles: what two types of hadrons are there? What is the difference between the two?

Answer 36

If there are two quarks it is a meson

If there are three quarks it is a baryon

Question 37

What are the six different quarks?

Answer 37

Up and down
Charm and strange
Top and bottom

Question 38

What are the six types of leptons?

Answer 38

Electron neutrino, muon neutrino, tau neutrino

Electron, muon, tau

Question 39

What are the four types of bosons?

Answer 39

Week force, strong force, photon, gluon

Question 40

What is a positron?

Answer 40

Positrons have identical mass to electrons but they carry a positive charge
An anti-electron

Question 41

Does every particle have an anti-particle? Describe the mass and charge of the antiparticle?

Answer 41

Yes (but not bosons). Same mass, but with opposite charge

Question 42

What has a baryon number of +1?

Answer 42

Matter baryons

Question 43

What has a baryon number of -1?

Answer 43

Anti-matter baryons

Question 44

What has a baryon number of zero?

Answer 44

Anything that isn’t a baryon

Question 45

What has a lepton number of +1?

Answer 45

Matter leptons

Question 46

What has a lepton number of -1?

Answer 46

Antimatter leptons

Question 47

What has a lepton number of zero?

Answer 47

Anything that isn’t a Lepton

Question 48

What is the relative charge of a proton, neutron, electron, neutrino?

Answer 48

Proton +1
Neutron 0
Electron -1
Neutrino 0

Question 49

What is the relative charge of the antiproton, antineutron, positron, antineutrino?

Answer 49

Antiproton -1
Anti-neutron 0
Positron +1
Antineutrino 0

Question 50

What can you assume about neutrinos in particle collisions?

Answer 50

That they have zero mass and zero charge

Question 51

From energy you can create matter and what?

Answer 51

Antimatter

Question 52

What happens when energy is converted into mass?

Answer 52

You get equal amounts of matter and antimatter

Question 53

What is pair production?

Answer 53

When you fire two protons at each other at high-speed and you’ll end up with a lot of energy at the point of impact. This energy might be converted into more particles.
If an extra proton is formed then there will always be in antiproton to go with it. It’s called pair production

Question 54

What is each particle antiparticle pair produced from?

Answer 54

A single photon

Question 55

When/where does pair production happen?

Answer 55

If one gamma ray photon has enough energy to produce that much mass. It also tends to happen in a nucleus, which helps conserve momentum

Question 56

What is the most common pair to be produced in a proton collision? Why?

Answer 56

Electron positron pairs because they have a relatively low rest mass

Question 57

How can you calculate the minimum energy, and therefore the minimum frequency and maximum wavelength, a photon must have a pair production to occur?

Answer 57

Use E equals MC squared

Question 58

What is the opposite of pair production?

Answer 58

Annihilation

Question 59

When does annihilation occur?

Answer 59

When a particle meets it antiparticle

Question 60

Describe annihilation

Answer 60

All the mass of the particles and antiparticles gets converted to energy, in the form of a pair of identical photons

Question 61

Why do we not see many antiparticles?

Answer 61

Generally they can only exist for a fraction of a second before they annihilate

Question 62

How can you work out the minimum energy of each photon produced in annihilation? What assumption do you have to make?

Answer 62

The combined energy of the photons will be equal to the combined energy of the particles, so 2 E = 2MC²
Assume that the particles have negligible kinetic energy

Question 63

What can you use to observe the pair production and annihilation?

Answer 63

A cloud chamber

Question 64

What is a cloud chamber?

Answer 64

A large box filled with alcohol, or water, vapour

Question 65

Explain how you can use a cloud chamber to observe pair production and annihilation

Answer 65

When a high energy particles passed through the cloud chamber, they ionised alcohol particles along their path
The vapour in the cloud chamber condenses around these ions, forming a trail of alcohol droplets (a ‘cloud’) along the path of the charged particle

Question 66

Most cloud chambers include a magnetic field at right angles to the direction of particle motion. Why?

Answer 66

A moving charge in a magnetic field experiences a force, so the path of charged particles, like electrons and positrons, will bend as they pass through the chamber. Positively and negatively charged particles are deflected in opposite directions.

Question 67

What happens to a particle speed as it travels through the cloud chamber? What does this mean about the shape of their trail?

Answer 67

They slow down, as ionising alcohol particles uses energy.

This means the paths of charged particles when the magnetic field is present are spirals, rather than circles

Question 68

Which photons don’t produce trails? Why?

Answer 68

Gamma ray photons are only weekly ionising – they pass through the alcohol of the cloud chamber without interacting with it very much

Question 69

Describe and explain what happens when antiproton enters a cloud chamber

Answer 69

The antiproton and proton collide. Hadrons are created and shoot off from the point of collision
There are an equal number of clockwise and anticlockwise hadron tracks because charge is conserved

Question 70

What are the antiparticles of hadrons made up from?

Answer 70

Anti quarks

Question 71

Which quarks are protons and neutrons made up from?

Answer 71

Up (u) and down (d)

Question 72

What is the relative charge of an up and a down quark?

Answer 72

Up +2/3

Down -1/3

Question 73

What is the relative charge of an anti-up and an anti-down quark?

Answer 73

Anti-up -2/3

Anti-down +1/3

Question 74

Where did evidence for quarks come from?

Answer 74

Came from hitting protons with high energy electrons.

The way the electrons scattered showed that there were three concentrations of charge (quarks) inside the proton

Question 75

What 3 quarks are a proton made up of? An anti-proton?

Answer 75

Proton: up, up, down

Anti-proton: anti-up, anti-up and an anti-down

Question 76

What 3 quarks are neutrons made from? Antineutrons?

Answer 76

Neutrons: up, down, down
Anti: anti-up, anti-down and an anti-down

Question 77

If you blasted a proton with enough energy, could you separate out the quarks? Why?

Answer 77

No. The energy just gets changed into more quarks and anti-quarks. It’s pair production and it makes mesons

Question 78

What is quark confinement?

Answer 78

The fact that you can never get free quarks. Adding energy to try and split the quarks in a proton up, just makes a new quark, anti-quark pair. Eg. A new meson

Question 79

Gluons provide force between…

Answer 79

Quarks

Question 80

What are gauge bosons?

Answer 80

Exchange particles. Virtual particles which are used to let one particle ‘know’ that another one is there

Question 81

What are the four fundamental forces?

Answer 81

Strong, electromagnetic, weak, gravity

Question 82

What are the gauge bosons for each force?

Answer 82

Strong: gluon
Electromagnetic: photon
Weak: W-, W+, Z0
Gravity: Graviton?? No evidence yet for it

Question 83

Which particles are effected by each force?

Answer 83

Strong: hadrons only
Electromagnetic: charged particles only
Weak: all types
Gravity: all types

Question 84

Because gluons cause a force, you can think of them as [ ] as well as particles

Answer 84

Fields

Question 85

What happens as you try and separate quarks? In terms of gluons. What happens if you keep pulling?

Answer 85

You increase the energy of the gluon field, increasing the attraction between them

If you keep pulling, eventually the energy in the gluon field will be enough that it produces a quark-antiquark pair

Question 86

Particle accelerators cause…

Answer 86

High energy collisions

Question 87

What is a linear accelerator?

Answer 87

A particle accelerator that is a long straight tube containing a series of electrodes

Question 88

Describe how a linear accelerator works

Answer 88

Alternating current is applied to the electrodes so that their charge continuously changes between positive and negative
The ac-current is timed so that the charged particles are always attracted to the next electrode in the accelerator and repelled from the previous one
A particle’s speed will increase each time it passes and electrode – so if the accelerator is long enough particles can be made to approach the speed of light
The high energy particles leaving a linear accelerator collide with a fixed target at the end of the tube

Question 89

What is a cyclotron?

Answer 89

It is a circular particle accelerator

Question 90

How do cyclotrons work?

Answer 90

A cyclotron uses 2 semicircular electrodes to accelerate protons or other charged particles across the gap
An alternating potential difference is applied between the electrodes – as the particles are accelerated from one side to the other their energy increases, i.e. they are accelerated.
A magnetic field is used to keep the particles moving in a circular motion
The combination of the electric and magnetic fields makes the particles spiral outwards as the energy increases

Question 91

What is the advantage of a synchrotron compared with a cyclotron or a linear accelerator ?

Answer 91

A synchrotron can produce particle collisions with much higher energies than either a linear accelerator or cyclotron

Question 92

What keeps the particles moving in a circular path in focused beams in a synchrotron?

Answer 92

Electromagnets

Question 93

How can synchrotrons produce particles with energy is reaching from 500 GeV to several TeV?

Answer 93

Are using electromagnets

Question 94

Explain how a synchrotron works

Answer 94

The beam travels around a very large circle.
The beam is accelerated by electrodes.
detectors are placed around the circle
Magnets are used to focus and deflect the beam
Two beams can be accelerated in opposite directions for collision beam experiments

Question 95

Which equation you can use to find a force experience by a particle, due to the magnetic field, in a synchrotron or a cyclotron?

Answer 95

F=qvB

Question 96

What is the disadvantage of a synchrotron?

Answer 96

They are really expensive to build and run, so they need to be funded internationally

Question 97

What are inertial frames?

Answer 97

Reference frames that aren’t accelerating. Einstein’s theory of special relativity only works in inertial frames

Question 98

No particle that has mass can…

Answer 98

Move at the speed greater than or equal to the speed of light, c

Question 99

Which two assumptions does Einstein’s theory of special relativity rely on?

Answer 99

Physical laws have the same form in all inertial frames

The speed of light in free space is invariant

Question 100

What happens when you increase the kinetic energy of a mass, like a particle in an accelerator?

Answer 100

The object becomes more massive

Question 101

What do particle accelerators have to do to compensate for the relativistic mass of the accelerating particles?

Answer 101

They have to alter their magnetic and electric fields

Question 102

Electrons in atoms have [ ] energy levels

Answer 102

Discrete

Question 103

Describe an electron on an energy level

Answer 103

Electrons in an atom can only exist in certain well-defined energy levels. Each level is given a number, called the principal quantum number of the electron in that state, with n=1 representing the electron’s lowest possible energy – its ground state

Question 104

Why are all the electron energies negative when talking about energy levels?

Answer 104

This is because of the way the zero energy is defined – it is the energy of an electron when it is not bound by an atom.
All electrons that are bound to the atom have negative energies.
The higher the energy level, i.e. the larger the value of n, the more energy in the electron has and the less negative the energy

Question 105

Relating to energy, when is an electron ionised?

Answer 105

An electron is “free“ and no longer bound to the atom when it has an energy of zero or more – the atom becomes ionised

Question 106

How can an electron moves down an energy level?

Answer 106

By emitting a photon

Question 107

When an electron moves down and energy level, what is the consequence of there being definite energy levels?

Answer 107

The energy of each photon emitted can only take certain values

Question 108

What is the energy carried by each emitted photon equal to?

Answer 108

The difference in energy is between the two levels that the electron has moved between

Question 109

What happens when an atom absorbs a photon?

Answer 109

An electron moves up to another energy level

Question 110

What two things are produced as a result of quantisation of electron energies?

Answer 110

Line emission and absorption spectra

Question 111

Why do you electrons, protons and neutrons obey the Pauli exclusion principle?

Answer 111

They are fermions

Question 112

What is the Pauli exclusion principle? What does this mean for electrons in energy levels?

Answer 112

This states that no to a fermions can be in exactly the same quantum state at the same time. In the context of energy levels, that means no more than two electrons can be in the same energy level at the same time.

Question 113

The spectrum for white light is [ ]

Answer 113

Continuous

Question 114

When do you get a line absorption spectrum?

Answer 114

When light with a continuous spectrum passes through a cool gas

Question 115

Which states will be electrons in a cool gas being?

Answer 115

At low temperatures, most of the electrons in the gas atoms will be in their ground states

Question 116

Which wavelengths are missing from the continuous spectrum when the light comes out the other side of the gas?

Answer 116

Photons of the correct wavelength are absorbed by the atoms to excite the electrons to high energy levels.
These wavelength and missing

Question 117

What shows that a wavelength has been absorbed in a spectrum?

Answer 117

Dark lines

Question 118

What do emission spectra show?

Answer 118

The wavelength of the photons emitted when an electron falls into a lower energy level

Question 119

What does an emission spectrum look like?

Answer 119

They are made up of a series of bright lines corresponding to the wavelength of the photons emitted

Question 120

If you compare the absorption and emission spectra of a particular gas, what will you see?

Answer 120

The dark lines in the absorption spectrum match up to the bright lines in the emission spectrum

Question 121

What are line spectra evidence for?

Answer 121

Energy levels

Question 122

What are fluorescent tubes evidence for?

Answer 122

Energy levels

Question 123

When thinking about electrons around a nucleus, what is the consequence of thinking of electrons as both a particle and a wave?

Answer 123

When they orbiting around a nucleus, they ought to behave like standing waves

Question 124

What should the wavelength of the electron waves do? When talking about energy levels

Answer 124

It should fit the circumference of the orbit a whole number of times

Question 125

What is equal to the number of complete waves that fit in the circumference at a certain energy level?

Answer 125

The principal quantum number

Question 126

Why can you think of electrons being standing waves between two fixed walls?

Answer 126

Because you can think of the electrons as being trapped by a potential well made by the nucleus

Question 127

When will an electron be able to escape the potential well of the nucleus?

Answer 127

When it has a total energy of zero or more

Question 128

How did Rutherford know that the nucleus was massive compared to electrons?

Answer 128

Most of the mass must be in the nucleus, since the fast alpha particles (with high momentum) are deflected by the nucleus

Question 129

What did Rutherford find out about the size of the nucleus? How did he know?

Answer 129

Very few particles are deflected by angles greater than 90°, So the nucleus must be tiny.

Question 130

How do you fluorescent tubes work? Quick step-by-step

Answer 130

Free electrons produced
They change energy levels, which results in the emission of UV photons
Phosphorous coating absorbs these, more electrons change energy levels, causing the emission of visible light photons

Question 131

What do fluorescent tubes do? (one sentence)

Answer 131

They use excited electrons to produce light.

Question 132

How do you fluorescent tubes work? (1):

First, more free electrons must be produced, how is this done?

Answer 132

A high voltage is applied across mercury vapour, which accelerates free electrons that ionise some of the mercury atoms, producing even more free electrons

Question 133

How do you fluorescent tubes work? (2):

What happens with the newly produced free electrons?

Answer 133

When the free electrons collide with electrons in other mercury atoms, the electrons in the mercury atoms are excited to high energy levels. When they return to their ground states, they emit UV photons

Question 134

How do you fluorescent tubes work? (3):

What happens to the UV photons, how does this lead to the emission of visible light?

Answer 134

A phosphorus coating inside the tube absorbs these photons, in turn exciting its electrons to much higher orbits. These electrons then cascaded down the energy levels, emitting photons in the form of visible light

Question 135

Where is the first minimum in electron scattering?

Answer 135

sinθ = 1.22λ/d
where λ is the de Broglie wavelength
and d = diameter of the nucleus

Question 136

Electron scattering:

On the graph of number of electrons scattered, against angle, how do you find the angle of the first minimum?

Answer 136

The first dip in the curve is the angle of the first minimum. You can use that angle for
sinθ = 1.22λ/d