An Introduction To Particle Accelerators
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Transcript An Introduction To Particle Accelerators
An Introduction To Particle
Accelerators
A-Level Physics
A Question
Q. Where is the nearest particle
accelerator to this classroom?
A.
Accelerating with high voltages
Particles can be accelerated to high
speeds and thus high energy
The energy is measured in electron-Volts
1 eV = 1.602x10-19 J
An industrial sized Van de Graaff
generator can accelerate electrons up to a
few Mega electron-Volts
The Van de Graaff Generator
This shows Robert Van de Graaff’s original high voltage generator at
MIT in 1933
Why do we need particle accelerators?
If particles have large velocity, the
wavelength decreases. So they can be
used to study atomic spacing.
High energy particles can be smashed into
each other, allowing other particles to be
studied!
How do accelerators work?
Electric fields (creating electromagnetic
waves) attract charged particles and
speed them up.
Magnetic fields can be used to change
their direction.
Obtaining particles to accelerate
Electrons: Heating a metal
causes electrons to ‘boil off’ –
thermionic emission.
Protons: They can easily be
obtained by ionizing hydrogen.
Antiparticles: High energy
particles are collided with solid
materials and antiparticles are
ultimately produced.
Accelerating Particles
In a Linear
Accelerator (Linac), a
carefully selected
frequency of
alternating voltage is
placed across a
series of cylindrical
electrodes to
accelerate a particle.
Linac Game
Accelerating Particles 2
The particles can also be considered to be
‘surfing’ the electromagnetic wave…
Accelerator Design
There are two main types of accelerator
experiment:
Fixed Target
- e.g. Rutherford’s
alpha scattering
experiment.
Colliding Beams
- can use much
more energy!
Linac or Synchrotron?!
Linear accelerators (Linacs) are used for
fixed-target experiments, as injectors to
circular accelerators, or as linear colliders.
A Linac at the
University of
California
Linac or Synchrotron?!
The largest Linac is at Stanford University,
USA.
It can accelerate particles up to 50 GeV
Particle energy at Fermilab, USA:
Linac or Synchrotron?!
Vaan de Graaf:
Linac:
The
H- ions to about 1 MeV
- ions to about 500 MeV
H
beams
particle
fromsynchrotron:
a circular protons to about 10 GeV
Booster
accelerator
Main
injector:
protons to about 150 GeV
(synchrotron) can be
Tevatron synchrotron
protons (and p-) to 1 TeV
used for particle
colliding experiments
or extracted from the
ring for fixed-target
experiments.
This is the European
Synchrotron Radiation Facility
(ESRF) in Grenoble, France
CERN
Accelerators at CERN
LINAC2+3 – Hadron Linacs
PSB – Proton Synchrotron Booster
PS – Proton Synchrotron
SPS – Super Proton Synchrotron
LHC – Large Hadron Collider
Other things
AD – Antiproton Decelerator
CMS – Compact Muon Solenoid
ALICE – A Large Ion Collider Experiment
What can they do?
Linacs and Synchrotrons can be used
together or alone:
Accelerating Particles 3
Heat energy provides the work function for
thermionic emission.
Electric fields accelerate particles:
Accelerating electrons
PE lost = KE gained
qV = ½ mv2
e.g. A thermionic diode has a p.d. of 5kV
placed across its electrodes. Calculate the
maximum velocity of the electrons.
v = (2qV/m) ½
v = (2 x 1.6x10-19 x 5000 / 9.1x10-31) ½
v = 4.2x107 ms-1
Accelerating electrons
The greater the acceleration of the electron, the
greater its energy.
KE = ½ mv2
Q. What happens when velocity approaches the
speed of light?
A. Mass increases! (Velocity can never equal the
speed of light).
KE = ½ mv2 still applies.
Bending Beams of Particles
For a beam of particles to move
through a circular path, they must
each experience a centripetal
force.
Q. Does this force increase the
energy of the particles?
The centripetal force is provided by
a magnetic field perpendicular to
the direction of the particles.
Demo: Bending a beam of electrons
in a CRT monitor or Teltron tube.
The Cyclotron
Cyclotrons accelerate
particles in a circular path
up to around 10MeV.
They are relatively small
and so can be used in
hospitals to provide
beams of (deuterons
creating) neutrons for
cancer therapy.
http://www.nscl.msu.edu/t
ech/accelerators/index.ht
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