presentation by sarim saleem on particle accelerator

Particle Accelerators
By Stephen Lucas
The subatomic Shakespeare of St.Neots

 To be able to explain how different particle
accelerators work.
 To be able to explain the role of magnetic fields in
particle accelerators.
 How the magnetic force provides the centripetal
force in particle accelerators.
Purposes of this presentation…

Why have particle accelerators?
They enable similarly charged particles to get close to each
other - e.g. Rutherford blasted alpha particles at a thin piece of gold
foil, in order to get the positively charged alpha particle near to the
nucleus of a gold atom, high energies were needed to overcome the
electrostatic force of repulsion.
The more energy given to particles, the shorter their de Broglie
wavelength (λ = h/mv), therefore the greater the detail that can
be investigated using them as a probe e.g. – at the Stanford
Linear Accelerator, electrons were accelerated to high energies and
smashed into protons and neutrons revealing charge concentrated at
three points – quarks.
E = mc2
Colliding particles together, the energy is re-distributed
producing new particles. The higher the collision energy the
larger the mass of the particles that can be produced.

The types of particle accelerator
Linear Accelerators or a LINAC
Cyclotron
Synchrotron

Basic Principles
All accelerators are based on the same
principle. A charged particle accelerates
between a gap between two electrodes
when there is a potential difference
between them.
Energy transferred, Ek = Charge, C x p.d, V
Joules (J) Coulombs (C) Volts (V)
Ek = QV

Converting to electron volts
1 eV is the energy transferred to an
electron when it moves through a potential
difference of 1V.
So if a gas molecule has kinetic energy
6.21 x 10-21 J, what is its energy in
electron volts?
1eV = 1.60 x 10-19J
1) First, using E = QV, we know that E = 6.21 x 10-21J, and that
the charge of an electron is 1.6 x 10-19 C
2) If we divide energy by the charge of an electron, we will
have the energy in terms of electron volts.
Therefore: 6.21 x 10-21J = 0.0388eV = 3.88 x 10-2eV
1.6 x 10-19 C

The Linear Accelerator
In a Linac, there are a series of tubular electrodes connected to an alternating
voltage. The alternating voltage ensures that the voltage of each electrode
switches back and forth between positive and negative.
1) When the first electrode is oppositely charged
to the entering particle (i.e. an electron or a
proton), the particle accelerates towards it.
2) There is no electric field inside the tubes, as
they are hollow conductors. When the particle
enters the first tube, the voltage is switched so
that the next tube is oppositely charged,
therefore it accelerates to the next electrode.
3) Each time, the same magnitude of voltage is
applied and so the energy of the particle
E = n x q x V, is built up in steps without
needing to increase the voltage.
^^ An alpha particle
being accelerated
through a linear
accelerator

Because reading is less fun…
Since the
frequency of the
oscillating voltage
is kept constant,
the electrode drift
tubes must get
longer so that the
particle takes the
same time to
travel through
each electrode.

The advantages of a linear
accelerator
It makes use of an alternating voltage, which means it
can easily be stepped up and down using transformers.
It is easier and cheaper to build since it does not
require magnets to produce a centripetal force by
interacting with the charged particle.
If it is used in fixed target experiments, the likelihood of
collisions is far greater.
It does not require the use of high voltages which
could cause sparks to jump between the electrodes.

The disadvantages of a linear
accelerator
The kinetic energy transferred to the particles is limited since
particles can only travel through the accelerating sections
once. In order for high energies to be obtained the machines
must be made longer and longer and this has cost
implications.
If the linear accelerator is used to accelerate particles at a
fixed target, only the accelerating particle has momentum
and kinetic energy. As momentum is always conserved the
total momentum cannot be zero before the collision, so the
created particles must be moving. This means energy is
used up as the kinetic energy of the new particles, rather
than the energy used to create the new particle’s mass.

The Cyclotron
The Cyclotron uses a magnetic field to bend charged particles into a
circular path so that they can be repeatedly accelerated by the same
electric field.

The Cyclotron
1) Protons leaving the centre are attracted to the
negative electrode.
2) The magnetic field bends the proton into a
semi-circle.
3) While the proton is travelling this semi-
circular path the polarity of the electrodes
reverses. When the proton reaches the gap, the
electric field accelerates the proton forwards
(because it is oppositely charged).
4) As protons complete each semi-circle, and are accelerated across the gap, they gain
more and more kinetic energy.
5) The radius of the proton’s path increases in proportion to r = mv/BQ, since it
travels faster, the radius of its path increases, and so despite travelling faster, it takes
the same time to travel each semi-circle, so the alternating voltage can stay at the
same frequency.

The Advantages of a Cyclotron
Particles in a circular accelerator go round many times getting
multiple kicks of energy.
Higher energies can be achieved using the same voltage but the
metal dees do not need to be of great length – Ernest Lawrence
achieved a proton energy of 80keV using a cyclotron with a
diameter of 11cm!
The particles go around many times, so if
two oppositely charged particles are
accelerated in opposite directions, there are
many opportunities for collisions. Colliding
beam experiments also have the highest
possible collision energy.

The Disadvantages of a Cyclotron
The use of magnets has cost implications.
Einstein’s theory of special relativity states that as objects
get faster, they get heavier. Therefore if the particles
travel close to the speed of light, their mass will increase.
As r = mv/BQ, an increase in mass, will cause the particle
to have a circular path of a larger radius, therefore it will
take longer to reach the gap, making it out of step with
the alternating p.d.
If two particles of the same mass are accelerated in
opposite directions to the same speed, the total
momentum before the collision will equal zero, and since
Ek = p2/2m, there will be no energy left over for the
creation of new particles.

But where does the centripetal force
come from?
A particle of charge q, travelling at speed, v, in a magnetic
field of magnetic flux density B, perpendicular to the
direction of travel, experiences a force, F:
F= Bqvsinq
The direction of the force is given
by Fleming’s Left Hand Rule:

But why do the moving charges follow
a circular path?
v
F v
F
v
F
e-
e-
e-
e-
Here we have an electron moving in a
magnetic field, where the direction of
the magnetic field is into the board.
Using Fleming’s left hand rule we can
see that the force exerted on the
electron, where F = BQv, will act
downwards.
However, the force is always 90˚ to the
charges direction of motion, the force
will alter the charges direction of
motion, but not alter its speed. If the
direction of motion is changed, the
force will still act at 90 degrees to the
direction of motion, causing circular
motion.
The BQv force provides the centripetal force.

Centripetal Force
The equation for centripetal force is:
If the magnetic force provides the centripetal force then:
The equation for magnetic force is:
F = BQv
r
F = mv2
r
BQv
r
Therefore:
mv2
= = mv
BQ
= p
BQ
BQ
r = p

But how long does it take an
electron to make one rotation?
v = Δs
Δt
So: Δ t = Δs
v
distance
speed
=
The circumference of a circle is 2πr therefore distance = 2πr, and speed
is v
2πr
v
T =
But r also equals:
p
BQ
So T =
2 π
v
x
mv
BQ
2πm
BQ
=
So the time taken for an
electron to make one rotation
equals:
T = 2πm
BQ
As you can see, the time taken for an electron, or any charged particle to make
a complete rotation a magnetic field of constant magnetic flux density does not
depend on speed, a faster moving electron moves a circle of larger radius but
takes exactly the same time to complete a circle.

Worked Exam Question
In a cyclotron, protons are accelerated by a high frequency voltage. A uniform
magnetic field, of flux density 200mT, causes the protons to follow a circular path
that increases in radius as the protons gain kinetic energy. Immediately before the
protons leave the cyclotron, the radius of their circular arc is 1.5m.
Proton Charge = 1.6 x 10-19C
Proton Mass = 1.67 x 10-27kg
Magnetic flux density = 200 x 10-3 T
Radius = 1.5m
Q) Show that the speed of the proton is about 10% the speed
of light.
The speed of light is 3.0 x 108ms-1, so 10% of that = 0.1 x 3x108ms-1 =
3 x 107ms-1, so our answer should be close to this value.
r = mv
BQ
So v = rBQ
m
=1.5m x 200 x 10-3T x 1.6x10-19C
1.67 x 10-27kg
= 28742514.97ms-1 Close to 10% of the speed of light so it
is correct. Huzzah!

Radius = 1.5m
Q) Calculate the approximate time taken for the proton to
travel around the semicircular Dee.
The metal Dee is a semicircle, so its circumference is half 2πr, which
leaves πr. Distance is therefore πr.
Aforementioned, time = distance
velocity
= πr
v
T = π x 1.5m
28742514.97ms-1
= 1.64 x 10-7s
The time taken for the
proton to travel around one
of the semicircular dees is:
= 1.64 x 10-7s

Radius = 1.5m
Q) Calculate the frequency of the accelerating p.d.
Frequency = The number of cycles per second
= 1
T
If you’ve got any legs left, watch out for the mousetrap here,
so far we only have the time taken for half a cycle (180˚), so
we need to multiple our value of time by 2.
1
f =
2t
= 1
2 x 1.64 x 10-7s
= 3 x 106Hz

The Northern Lights
The ‘northern’ lights are
caused by charged particles
from outer space from solar
wind (streams of charged
particles expelled from the
Sun) being caught in the
Earth’s magnetic field and
colliding with particles in the
Earth’s upper atmosphere. A
charged particle in a magnetic
field experiences a force, and
this force provides the
centripetal force.
This causes the particles to spiral along the earths magnetic field. As the
magnetic field gets stronger at the poles, the radius of the spiralling circular
path decreases, since r = mv/BQ and, B is getting larger.

Radius = 9.3cm = 0.093m
B = 3.7 T
Mass of helium nucleus = 4u
BQ
r = p Ek = p2
2m

r = 0.093
B = 3.7T
Mass = 4u = 4 x 1.67 x 10-27
Charge = 2 x 1.6 x 10-19C
r = mv
BQ
v = BQr
m
v = 3.7T x (2 x 1.6 x 10-19C) x 0.093m
4 x 1.67 x 10-27kg
v = 16483832.34ms-1 = 1.64 x 107ms-1
Ek = ½ mv2
Ek = ½ x 6.68 x 10-27 x (1.64 x 107ms-1)2
Ek = 8.98 x 10-13J Divide by 1.6 x 10-19 to get into
electron volts: 5.61MeV

Synchrotron
At very high energies, the particles travel close to the speed of light and
their motion is now described by relativistic equations and their travel
time is no longer the same for each semi-circle.
To overcome this, careful synchronisation is needed to make the
electrodes change their polarity as the particles pass through each
acceleration section. The magnetic field is increased to keep the moving
particles in a moving circle of constant radius.

LHC
The LHC is an example of a synchrotron. It
accelerates protons to 99.9999% of the speed of
light, colliding them at high energies and
recording the results on huge computers.
But what is the LHC looking for?
• The Higgs Boson – this particle decays to produce matter and
antimatter. Particle Physicists also want to test the Higgs Mechanism,
a theory that suggests a ‘treacle’ fills the universe, slowing down
particles which makes them heavy, while not slowing down others
such as light. The Higgs mechanism explains how energy is
concentrated to produce mass (Sounds like a hump of crap to be
honest, who the hell decided this?).
• Being closer to the grand unified theory - At extremely high
energies (above 1014 GeV), the electromagnetic, weak nuclear, and
strong nuclear forces could be fused into a single unified field. So far,
physicists have been able to merge electromagnetism and the weak
nuclear force into the electroweak force. The LHC could reveal why
gravity is so weak in comparison to other fundamental force, or give
way to the graviton.
• The mystery of antimatter – the big bang should have created
matter and antimatter in equal amounts, and yet we are only surrounded
by matter. Why didn’t everything annihilate? Where did the antimatter
go?
•Is Science wrong? – If the LHC does not conclude any results as to the origin
of mass, Physicists will have to rethink the standard model and seek new ways of
testing the origin of mass. This is a good thing, as proving science wrong,
enabled Einstein to predict the perihelion of Mercury using general relativity,
where Isaac Newton’s theory of gravity did not work. Most great discoveries
were found by accident.
• Extra Dimensions – are there extra dimensions that we cannot see?
•Dark Matter – what is the nature of dark matter? Dark matter is
matter that does not interact with the electromagnetic force, but whose
presence can be inferred from gravitational effects on visible matter.

Disadvantages of the LHC
Huge cost implications, the maintenance of keeping supermagnets
at -270˚C, constructing tunnels of such length (circumference of
27km) and building a computer network to detect and store
information all caused the budget of the LHC to be between 3.2 –
6.4 billion Euros. This required international funding, causing
governments from all over the world contributing to the funding of
the LHC.
Although controversial and not regarded as a real threat, if any of the
collisions cause black holes, there is speculation that the earth could
be swallowed into a black hole.
There is a risk that the Higgs Boson will not be found, and even if it is,
there is no guarantee that this will have practical uses in the real world.

So how are the particles detected?
 A charged particle moving through matter
causes ionisation, the greater the ionisation, the
thicker the tracks and the slower the moving
particle.
 Positive and negative particles curve in
opposite directions when there is a magnetic
field perpendicular to the direction of travel.
 The greater the momentum, the less curved the
tracks. As particles lose energy they spiral
inwards. Measuring their curvature allows
momentum to be calculated.
 As particles collide, the ions produced can be
accelerated by electric fields and detected, so
the path of the particle can be detected.

So what have we learnt?
• To be a good physicist you need a good set of legs.
• If you get too close to god’s brain he will smite you.
E.g. Hawking

presentation by sarim saleem on particle accelerator

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