FU NDAMENTALS OF X-RAY PRODUCTION
• The production of X Rays involves the
bombardment of a thick target with energetic
electrons. • Electrons undergo a complex sequence of collisions
and scattering processes during the slowing down
process which results in the production of
• Bremsstrahlung (continues radiation) and
• Characteristic radiation
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• Energetic Electrons are mostly slowed down in matter by:
• Collisions and
• Excitation interactions
• If an electron comes close to an atomic Nucleus the attractive Coulomb
forces causes a change of the electron’s  trajectory • An accelerated electron or an electron changing its direction emits
electromagnetic radiation  and given the name Bremsstrahlung
• The energy of the emitted photon is subtracted from the kinetic energy of the
electron • The Energy of the Bremsstrahlung photon depends  on the
• Attractive  Coulomb forces and hence on the • Distance of the electron from the nucleus
• The total x-ray energy emitted per second depends on the atomic number Z of the
target material and on the x-ray tube current. This total x-ray intensity is given by:
  I cont = AiZV2
A  – constant i – tube current (measure of the number of electrons per second striking the target) Z- atomic number IA EA Diagnostic Radiology Physics: a
Handbook for Teachers and Students –
V- voltage
chapter 5, 4
FUNDAMENTALS OF X-RAY PRODUCTION • For each element binding energies and the Monoenergetic radiation resulting from such
interactions, are unique and Characteristic for that element. • The electrons are slowed down and stopped in the Target (within a range of a few tens of
µm). • X rays are not generated at the surface but within the target resulting in attenuation of
the X ray beam • Characteristic radiation shows up if the kinetic energy of the electron exceeds the
binding energies
Energies of characteristic X rays, keV
K-shell Ka1
Ka2 Kb1 Kb2
Element W Mo Rh
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to an electron which is ejected radiation from the shell (Auger Electron)  production probability decreases with Z
FUNDAM ENTALS OF X-RAY PRODUCTION
• L-Radiation is totally absorbed by a typical filtration of 2.5
mm Al • The K-Edge in the photon attenuation of tungsten can be
noticed as a drop of the continuum at the binding energy of
69.5 keV • Efficiency for the conversion of electrical power to
Bremsstrahlung radiation is proportional to U·Z
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• At 100 kV the efficiency is as low as ~0.8% • This is the cause for most of the technical problems in
the design of XRTs as practically all electrical power
applied in the acceleration of electrons is converted to
Heat
Components of the X Ray Tube
• The production  of both Bremsstrahlung and Characteristic Radiation requires energetic electrons
hitting a target • Principle components of an X ray tube are an Electron Source from a heated tungsten filament with a
focusing cup serving as the tube Cathode, an Anode or Target and a Tube Envelope to maintain an
interior vacuum • The Filament is heated by a current that controls the thermionic emission of electrons,  which in turn
determines the number of electrons flowing from cathode to anode (Tube or Anode Current) e.g. 1000 mA in single exposures
• The accelerating  Potential Difference  applied between cathode and anode controls both X ray
energy and yield e.g. 40 to 150 kV for general diagnostic radiology and 25 to 40 kV in mammography • Thus two main circuits operate  within the XRT:
• Filament circuit • Tube voltage  circuit
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Diagnostic Radiology Physics: a
Handbook for Teachers and Students –
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X-RAY TUBES
Cathode
• The Spiral-Wound filament is typically  made from tungsten wire of 0.2 to 0.3 mm diameter and operates  at around
2700oK=2426oC. • To minimise the Evaporation  of tungsten  from the hot surface, the filament temperature is kept at a lower level
except  during exposure  when it is raised to operational  levels. • Thermionic Emission  of electrons  increases  with temperature (Richardson’s  law) and produces  a cloud of electrons
(Space Charge) enclosing  the filament.
Anode
• For such anodes X ray spectra show less contribution by Bremsstrahlung but rather dominant Characteristic X
rays of the anode materials • Allows a more satisfactory optimization of image quality and patient dose • In Digital Mammography these advantages are less significant, and some manufacturers prefer tungsten anodes
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• For common radiographic applications, a high Bremsstrahlung yield is mandatory requiring materials with high atomic
numbers (Z) • Due to the low efficiency of X ray production, it is essential that the thermal properties such as Maximum Useful
Temperature determined by melting point and vapor pressure, heat conduction, specific heat and density are also
considered • Tungsten (Z=74) is the optimum choice • For Mammography other anode materials such as molybdenum (Z=42) and rhodium (Z=45) are frequently used
Line-focus principle (anode angle) • For measurement purposes,  the focal spot size is defined
along the central beam projection
• For  the  sake  of  high  anode  currents  the  area  of  the  anode  hit
by  the  electrons  should  be  as  large  as  possible  to  keep  power
density within acceptable limits
• The size of the focal spot of an XRT is given for the central
beam in the X ray field running perpendicular to the electron
beam or the tube axis
• The  actual  focal  spot  size  depends  on  the  position  within  the
field of view increasing from the anode side of the tube to the
cathode
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Handbook for Teachers and Students –
chapter 5, 9
Line-Focus Principle (Anode Angle) • In addition to X rays  produced  in the primary focus, some Off- Focus Radiation results from
electrons scattered from the anode which are then accelerated  back and hit the anode outside of
the focal area • Extra Focal Radiation can contribute up to ~10% of the primary X ray intensity • Since the effective focal spot size for off-focus radiation is substantially Larger than for the
primary focus it has an impact on image quality such as background  fog and blurring
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Stationary & Rotating Anodes • For X ray examinations that require only a low anode current or infrequent low power
exposures  (e.g. dental units, portable X ray units and portable  fluoroscopy systems) an X ray
tube with a Stationary Anode  is applicable • A small tungsten block serving  as the target is  Brazed to a copper block to dissipate the heat
efficiently to the surrounding  cooling medium • As the focal spot is Stationary the maximum loading is determined by anode  temperature  and
temperature gradients
Stationary & Rotating Anodes • Most X ray examinations  need photon  fluences  which Cannot be obtained
with stationary anodes  as bombarding the same spot with higher  anode
currents  leads to Melting and Destruction of the anode • In a tube with a Rotating Anode  a tungsten disk rotates during an
exposure  thus effectively  increasing the area bombarded  by the electrons
to the circumference of a Focal Track • The energy is dissipated to a much larger volume as it is Spread Over the
anode disk
• The Rotational  Speed of the anode  is determined by the frequency
of the power  supply and the number of active windings  in the stator
• Speed can be varied  between  high  (9000-10000  rpm) and low speed
(3000-3600  rpm)
• Rotor Bearings are critical components of a rotating  anode tube and
along with the whole assembly,  cycling  over a large temperature
range  results in high thermal stresses
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Thermal Properties
• The Limiting Factor in the use of X ray tubes is given
mainly by the thermal loading capacity of the anode • The Nominal Power is determined for an exposure time of
0.1 s • Within the First 0.1 s, the maximum load  is determined
by mechanical stress in the anode material developing
from temperature gradients  near the surface of the focal
spot (A) • As a consequence  cracks can develop  leading to an
increase in anode surface roughness • Maximum  Permissible Tube Load vs. time for a
single  exposure,  constant current, 100  kV tube
• This effect can be reduced by:
voltage and a 50 kW tube
• Use of a more ductile alloy as the focal track (e.g.
Tungsten/Rhenium alloys)  or • An increase in the size of the focal spot or the
rotational speed of the anode
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Handbook for Teachers and Students –
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Thermal Properties
• In CT and fluoroscopic  procedures  Longer  exposure  times are needed (10  s to >200 s)
• Here the dissipation  of heat across the Entire anode disk becomes  important • The important physical  properties  are then the Heat Conduction  and Heat  Capacity  of the anode  disk.
• The Heat Capacity  is the energy  stored in the anode  disk with the  anode  at its maximum permissible
temperature
• It depends  on the Specific Heat and Mass of the anode materials • Molybdenum is superior to Tungsten in this respect • Increasing  the mass of the anode  (diameter, thickness)  has its limitations as balancing  the  rotating anode
becomes difficult for the wide range  of temperatures  occurring • Since Graphite has a higher  specific heat at higher temperatures than molybdenum  or tungsten  the heat
capacity can be increased  by attaching  graphite  heat sinks to the back of the anode  disk Graphite enhances
the dissipation of heat by Black-Body Thermal Radiation
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Tube Envelope
• The tube envelope maintains the required Vacuum in the XRT • A Failing vacuum due to leakage or degassing of the materials
causes increased ionization of the gas molecules which slows down
the electrons • Further, a current of Positive Ions flowing back could impair or
destroy the cathode filament • The envelope is commonly made of glass but high performance
tubes increasingly have Glass/Metal or Ceramic/Metal envelopes • The X ray beam exits the tube through a Window in the envelope Typical housing assembly for a general purpose XRT
• To reduce absorption the Thickness of the glass is reduced in this
area • If low-energy X rays are used as in mammography, the exit port is a
Beryllium window which has less absorption than glass due to its
low atomic number
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The X Ray Generator
The essential components are: • a Filament Heating circuit to determine anode
current • a High Voltage supply • a Motor Drive circuit for the stator windings
required for a rotating anode tube • an Exposure Control providing the image
receptor dose required an Operational Control
IA EA Diagnostic Radiology Physics: a
Handbook for Teachers and Students –
Sc hematic diagram of a basic X ray generator
chapter 5, 15
• Provides all electrical power sources
and signals required for the operation
of the X ray tube • Controls the operational conditions of
X ray production
CO LLIMATION & FILTRATION Collimator & Light Field
The limitation of the X ray field to the size required for an examination is accomplished with Collimators
The benefits of collimating the beam are Twofold:
§ Reduction of patient dose
§ Improvement of image contrast due to reduced
scattered radiation
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Diagnostic Radiology Physics: a Handbook for Teachers and Students –  chapter 5, 16
Collimator & Light Field
• A Collimator Assembly is typically attached to the tube port
defining the field size with adjustable parallel-opposed lead
Diaphragms or blades • Visualization of the X ray field is achieved by a mirror
reflecting the light from a bulb • The light field then mimics the actual X ray field
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