Physics of Radiotherapy Lecture II: Interaction of Ionizing Radiation With Matter
Charge Particle Interaction Energetic charged particles interact with matter by electrical forces and lose kinetic energy via: Excitation Ionization Radiative losses (Bremsstrahlung Production) ~ 70% of charged particle energy deposition leads to non-ionizing excitation
Specific Ionization Number of primary and secondary ion pairs produced per unit length of charged particle s path is called specific ionization Expressed in ion pairs (IP)/mm Increases with electrical charge of particle (more for alpha as compare to electron) Decreases with incident particle velocity
Linear Energy Transfer (Stopping Power of The Medium) Amount of energy deposited per unit path length (ev/cm) is called the linear energy transfer (LET) and is also known as stopping power of the medium LET of a charged particle is proportional to the square of the charge and inversely proportional to its kinetic energy High LET radiations (alpha particles, protons, etc.) are more damaging to tissue than low LET radiations (electrons, gamma and x-rays)
Electron Interaction As an energetic electron traverses matter, it undergoes Coulomb interactions with absorber atoms, i.e., with: Atomic orbital electrons Atomic nuclei Through these collisions the electrons may: Lose their kinetic energy (collision and radiation loss). Change direction of motion (scattering).
Energy losses are described by stopping power (LET). Scattering is described by angular scattering power. Collision between the incident electron and an absorber atom may be: Elastic Inelastic
In elastic collision the incident electron is deflected from its original path but no energy loss occurs. In an inelastic collision with orbital electron the incident electron is deflected from its original path and loses part of its kinetic energy (collisional loss). In an inelastic collision with nucleus the incident electron is deflected from its original path and loses part of its kinetic energy in the form of bremsstrahlung (radiative loss)
The energy loss by incident electron through inelastic collisions is described by the total linear stopping power S tot which represents the kinetic energy E K loss by the electron per unit path length x: S tot =de K /dx MeV/cm
Mass Stopping Power Total mass stopping power is defined as the linear stopping power divided by the density of the absorbing medium. It has two parts, collisional and radiative
Electrons traversing an absorber lose their kinetic energy through ionization collisions and radiation collisions. The rate of energy loss per gram and per cm 2 is called the mass stopping power and it is a sum of two components: Mass collision stopping power Mass radiation stopping power The rate of energy loss for a therapy electron beam in water and water-like tissues, averaged over the electron s range, is about 2 MeV/cm.
Photon Interactions Probability chance of event happening can be mathematically expressed example: The probability of a woman experiencing breast cancer in her lifetime is 1:9 x-ray interactions are chance events relative predictions can be made energy of the photons type of matter the x rays are passing through cannot predict how one photon will interact
Photon Interactions Probability of photon interaction depends on Energy of Incident Photon The type of traversing matter
Photon Interactions Transmitted through matter (unchanged) Change direction with no energy loss 1.Classical Scattering (Coherent Scattering) Change direction and lose energy 2.Compton Scattering Deposit all energy in the matter 3.Photoelectric Effect 4.Pair Production 5.Photodisintegration
Classical Scattering (Coherent or Elastic) Occurs at low energy (< 10 kev) Atom first excited by photon Then releases (radiates) photon of same kev & New photon travels in different direction from original photon but usually forward (small scatter angle) Coherent Scattering is further classified as Rayleigh Scattering If interaction occurs with whole atom Thompson Scattering If interaction occurs with shell e -
Photoelectric Effect (Complete absorption) The orbital electron is ejected from the atom with kinetic energy E K =hν-e B where E B is the binding energy of the orbital electron. The ejected orbital electron is called a photoelectron. When the photon energy hν exceeds the K-shell binding energy E B of the absorber atom, the photoelectric effect is most likely to occur with a K-shell electron in comparison with higher shell electrons.
Photoelectric Effect Electrons in higher energy shells cascade down to fill energy void of inner shell Characteristic radiation
Photoelectric interaction probability inversely proportional to cube of photon energy low energy event proportional to cube of atomic number P.E ~ Z 3 /E 3 More likely with inner (higher) shells tightly bound electrons Interaction much more likely for low energy photons high atomic number elements
Photon Energy Threshold binding energy of orbital electron binding energy depends on atomic number higher for increasing atomic number shell lower for higher (outer) shells most likely to occur when photon energy & electron binding energy are nearly the same
Photoelectric interactions decrease with increasing photon energy BUT When photon energies just reaches binding energy of next (inner) shell, photoelectric interaction now possible with that shell shell offers new candidate target electrons Causes step increases in interaction probability as photon energy exceeds shell binding energies
Interaction Probability L-shell binding energy K-shell binding energy L-shell interactions possible K-shell interactions possible Photon Energy
Compton Scattering Source of virtually all scattered radiation Process incident photon (relatively high energy) interacts with free (loosely bound) electron some energy transferred to recoil electron electron liberated from atom (ionization) emerging photon has less energy than incident new direction - Electron out (recoil electron) Photon in Photon out
What is a free electron? low binding energy outer shells for high Z materials all shells for low Z materials - Electron out (recoil electron) Photon in Photon out
Incident photon energy split between electron & emerging photon Fraction of energy carried by emerging photon depends on incident photon energy angle of deflection similar principle to billiard ball collision
higher incident energy = less photon deflection high energy (1MeV) photons primarily scatter forward diagnostic energy photons scatter fairly uniformly forward & backward at diagnostic energy photons lose very little energy during Compton Scattering At therapy energy level, photons lose most of energy through Compton scattering higher deflection = less energy retained - Electron out (recoil electron) deflection angle Photon in Photon out
h ' 1 cos mc e λ is wavelength of scattered photon and λ is the wavelength of incident photon Ee max hf 2 1 2 (E e ) Max is maximum energy transfer to recoil electron and α=hf/m e c 2 (rest mass energy of electron
Interaction Probability is independent of atomic number (except for hydrogen) Proportional to electron density (electrons/gram) fairly equal for all elements except hydrogen (~ double)
Interaction Probability decreases with increasing photon energy decrease much less pronounced than for photoelectric effect Interaction Probability Compton Photoelectric Photon Energy
Pair Production (Complete absorption) Exist at high photon energy Ei > 1.022 MeV (e- rest mass energy =.511 MeV) Photon interacts with nuclear force field uses 1.022 MeV to produce pair of electron like particles e+ (positron) & e- (negatron) Photon ceases to exist E = 1.022 MeV + E e+ke + E e-ke
Photon Interaction Probabilities 100 Photoelectric Pair Production Z COMPTON 10 0.01 0.1 1.0 10 100 Energy (MeV)
Linear Attenuation Coefficient The most important parameter used for characterization of x-ray or gamma ray penetration into absorbing media is the linear attenuation coefficient μ The linear attenuation coefficient depends upon: Energy of the photon beam Atomic number Z of the absorber The linear attenuation coefficient may be described as the probability per unit path length that a photon will have an interaction with the absorber This interaction may be any one of the interactions discussed so for (PE,CS PP etc.)
For collimated beam of monoenergetic photons, the intensity of photon beam after passing through thickness x of some homogenous medium is
Several thicknesses of special interest are defined as parameters for mono-energetic photon beam characterization in narrow beam geometry: Half-value layer (HVL1 or x1/2) Absorber thickness that attenuates the original intensity to 50%. Mean free path (MFP ) Absorber thickness which attenuates the beam intensity to 1/e = 36.8%. Tenth-value layer (TVL or x1/10) Absorber thickness which attenuates the beam intensity to 10%.
In medical physics photon interactions fall into four groups: Interactions of major importance Photoelectric effect Compton scattering by free electron Pair production (including triplet production) Interactions of moderate importance Rayleigh scattering Thomson scattering by free electron Interactions of minor importance Photonuclear reactions Negligible interactions Thomson and Compton scattering by the nucleus
For a given hν and Z: Linear attenuation coefficient μ is sum of all interaction probabilities, mostly μ = PE Cross-section + Scattering Crosssection + PP Cross-section