Equipment

Question 1

What does modulator consist of?

Answer 1

Pulse forming network
Thyratron
Circuit converting power supply to DC

Question 2

What is the pulse repetition frequency and the length of pulses?

Answer 2

200-300Hz, pulse of ~3micro s
(3-5ms pulse intervals)

Question 3

What first happens in modulator?

Answer 3

3 phase power supply converted to DC, supplies DC to PFN.

Question 4

What is PFN origin of and how does it work?

Answer 4

Origin of high voltage pulse
Circuit of capacitors in parallel, when they discharge they produce a high voltage pulse as close to a square pulse as possible.
Capacitor provides power to charge up PFN until it reaches the voltage it wants and circuit closes

Question 5

What does thyratron act as?

Answer 5

High voltage switch to rapidly discharge PFN and complete circuit to send pulse onwards

Question 6

In magnetron what does spreading out of electrons correspond to?

Answer 6

Magnitude of induced EF
Size of EF determines amplitude of RF wave

Question 7

In magnetron, what determines how tightly grouped electrons are?

Answer 7

Voltage between anode and cathode
(which is voltage of pulse from modulator)

Question 8

How do you change frequency in magnetron and klystron?

Answer 8

Magnetron: determined by resonance of cavities and plunger can fine tune this
Klystron: input microwaves

Question 9

Why is transmission waveguide filled with SF6 gas?

Answer 9

Reduce arching
Damage becomes antennae. Pit and peak.

Question 10

What are the types of accelerating waveguide

Answer 10

Standing or travelling

Question 11

What are MLC numbers and dimensions?

Answer 11

28-80 pairs
typically 0.5-1mm at isocentre
Shaped and angled to minimise inter-leaf leakage

Question 12

How is induced radioactivity created?

Answer 12

Neutrons ejected from nucleii. Hazardous due to different shielding requirements. Cause induced radioactivity - mostly neutron activation of metals in head of linac

Question 13

What is nuclear binding energy?

Answer 13

~9MeV

Question 14

Result of neutron flux

Answer 14

Neutron flux for beams over 10MV, must be checked when using 15MV beams
More shielding in maze as neutrons scatter more than photons (baffles or neutron absorbing material in door)
Contribute to patient dose - RBE of 20

Wall shielding for photons is acceptable

Question 15

Limits of leakage radiation

Answer 15

Max 5% of air kerma rate of useful beam at 1m from target
In patient, max 0.2% useful beam, mean 0.1%

Question 16

What are we trying to achieve with ionisation chamber?

Answer 16

Measure something that allows calculation of dose - ionisation good thing to measure.

Question 17

What do we need to decide when creating ionisation chamber?

Answer 17

Material for casing
Size of collecting volume
Polarising voltage
Polarity of voltage
Material for internal electrode
How to minimise extra-cameral current

Question 18

What is job of casing of ionisation chamber?

Answer 18

Define the cavity
Conduct electricity
Same attenuation/absorption characteristics as medium that it’s in (air kV, water/medium MV)

Question 19

What properties does casing of ionisation chamber need?

Answer 19

Conducting
Homogeneous
Water (medium) equivalent
Robust??
Waterproof?

Question 20

How do you decide on size of collecting volume?

Answer 20

What is requirement of ionisation chamber? Reference dosimetry, SRS, PDD, area scatter chamber.
Small in relation to dose gradient
Does it behave like Bragg_gray?

Question 21

Where does extra-cameral current come from?

Answer 21

Interactions in stem, cable, electronics
Leakage between currents (intrinsic leakage)
Charge accumulation in insulators (effects of irradiating plastic insulators is really complex)
Stressed cables

Question 22

Why do you get intrinsic leakage in ionisation chamber?

Answer 22

Two adjacent conductors at different potentials
Insulator not perfect
Dampness or surface contamination can enable current

Question 23

What is the job of the guard ring?

Answer 23

Ensure current only comes from defined volume
Thimble: avoid conduction through insulator
Plane-parallel: define volume for collection, exclude electrons scattered in from side walls

Question 24

What is the job of the polarising voltage in ionisation chamber?

Answer 24

Pull ions apart
collect ions to make a current
Need specific voltage - minimise recombination and avoid charge multiplication

Question 25

Why can we end up with proportionally more ions at higher voltage?

Answer 25

Electrons accelerate in electric field
E field strength increases close to central electrode
If V high enough, electrons can collide and generate more electrons
As voltage increases, electron multiplication increases

Question 26

Electric field strength in ionisation chamber

Answer 26

Depends on voltage accross gap
Increases close to central electrode

Question 27

What are requirements for central electrode of ionisation chamber?

Answer 27

Robust
Conducting
Same interactions as body

Question 28

What are interactions in mediums that could be used for internal electrode?

Answer 28

Steel: too much PE
Aluminium: mostly compton
Conducting plastic: can be made to be mostly Compton
Graphite: compton

Question 29

What are considerations of polarity of voltage in ionisation chamber?

Answer 29

Polarity can give different readings, although mostly negligible in high energy beams.
For relative measurements, use same polarity or calculate average or calculate kpol
For reference and x-calibrated, use same polarity as in chain

Question 30

What is the difference between a virtual and dynamic wedge?

Answer 30

Virtual: constant velocity & variable dose rate
Dynamic: variable dose rate and jaw speed

Question 31

What is role of cooling system?

Answer 31

Keep linac at optimum running temperature - this is 40 degrees. A lot of excess heat is generated which must be handled.

Question 32

What is role of vacuum pump?

Answer 32

Keep waveguide, standing or travelling, under constant vacuum. Electrons need a clear path.

Question 33

What is role of steering coils?

Answer 33

Change the path of electrons, angle, position and size of pulse.

Question 34

How does magnetron operate?

Answer 34

Thermionic emission from heated cathode
Electrons accelerated across from cathode to anode
Curved path due to magnetic field - form spokes
Electrons initiate oscillating E field as they cross cavity openings
E field feed back bunches electrons
These bunches amplify existing E field
Oscillation of E field produces microwaves are channelled to accelerating waveguide

Question 35

How does klystron operate?

Answer 35

Low power microwaves and electrons (from thermionic emission) injected into first cavity
Microwaves accelerate/decelerate electrons depending on phase at injection and bunches them
Get tightly bunched pulse of electrons travelling at same frequency as input microwaves
As electrons cross catcher cavity they induce electric field with same frequency as input MW but higher amplitude

Question 36

What is temperature of heater in electron gun?

Answer 36

1000oC

Question 37

What is potential of cathode, anode and grid in triode gun?

Answer 37

20kV cathode
Anode at ground
Grid has high speed switching of potential, held at higher -ve potential but pulsed to positive

Question 38

How does electron bunching work?

Answer 38

When electrons meet wave, can be in a favourable phase or not. Roughly half of electrons are scattered to walls and eliminated.
Others gather in bunches

Question 39

How does slalom bending magnet work?

Answer 39

Beam first bent 45 degrees, then another 45 degrees in opposite direction (to converge) then 112.5 degrees while converging so they exit bending magnet at same spot

Question 40

What are the properties of the photon target, type of target?

Answer 40

Transmission target
High Z (W-74 or steel)
High density
High melting point

Forward peaked beam, brem. radiation, high efficiency wrt reflection target. No characteristic radiation

Question 41

What are monitor chambers?

Answer 41

Transmission ionisation chambers which fully intercept treatment beam. More than one for redundancy.

Question 42

What do two chambers monitor?

Answer 42

Chamber 1: dose/dose rate
Chamber 2: dose/dose rate (redundancy), flatness/symmetry

Question 43

What are the two impacts of nuclear reactions form photons/electrons?

Answer 43

Neutron flux in beams greater than 10MV
Induced radioactivity

Question 44

What order of magnitude difference should there be between current and leakage?

Answer 44

Should be two orders of magnitude between current and leakage

Question 45

What is the difference between travelling and standing waveguides?

Answer 45

Travelling are longer and simpler
MW injected at end of travelling

Standing has side coupled cavities for nodes

Question 46

How do we decide on polarising voltage?

Answer 46

Depends on size of cavity: field strength depends on voltage across gap V/mm, so size of gap determines strength