x ray beam production Flashcards
what are the three interactions that happen between the filament electrons and the tungsden atoms on the anode side
between the filament electrons and the outer shells of the target atoms
between filament electrons and the nuclei of target atoms
between filament electrons and the inner shells of target atoms
describe the interaction between filament electrons and the outer shell of target atoms
the negative filament electron is repelled by the outer shell electron of the target atom causing the filament electron to deviate from its original path
this also results in a loss of kinetic energy which is emmited as a photon of electromagnetic radiation and theis photon of energy falls into the infrared part of the electromagnetic spectrum producing heat to the target material
why is the interaction between the filament electron and the outer shell of the target atom the most common interaction
this is due to the high atomic number of tungsden (74) this means there are 74 electrons orbiting the nucleus. this means more outer shell reactions will be involved
describe the interaction between filament electrons and the inner shell electrons of target atoms
these filament electrons interact with the electrons orbiting the K or L shells of target atoms
when the filament electron strikes the electron of the inner shell of the target atom. it strikes it with enough energy to eject it from its shell
this ejected electrong then goes and interacts with other atoms until it has lost all of its energy
after this electron has been ejected, there is now a vacancy in the k shell of the target electron that needs to be filled so an electron further away from the nucleus drops down to fill it losing energy in the process
this loss of energy is emmited ans a photon of electromagnetic radiation
explain the xray photon energy produced when a filament electron interacts with the inner shell of tungsten
when the vacancy in the k shell of a target electron is filled, the xray photon energy would be a sum of the binding energy of the recieving shell minus the binding energy of the donating shell
tungsten k shell binding energy is 69.5 and the binding energy of the L shell is 10.2 so when the electron from the L shell is donated to the K shell, the xray photon energy would equal 59.3kev
these energies differ between different materials which is why it is called characteristic radiation
how are k-alpha xray photona and k-beta xray pohotons produced
k-alpha xray photons are produced when an electron from the L-shell of a target atom is donated to the K-shell of a target atom
k-beta xray photons are produced when an electron from the M-shell of a target atom is donated to the K-shell of a target atom
what are the two types of interactions that take place between the filament electrons and the nuclei of target atoms
inelastic and elastic interactions
explain elastic interactions between the filament electrons and the nuclie of target atoms
the incoming filament electron is attracted by the nuclei of the target atom and the closer the electron gets to the nucleus, the further it is deviated from its original path
this serves to provide the elctron with a more complex path without much energy transfer or lost energy
explain the inelastic interaction between the filament electron and the nuclei of the target atom
(bremsstraluhng radiation)
the incoming filament electron passes closely to the nucleus causing it to experience a force of attraction causing it to move towards the nucleus deviating it fromits original path
this deviation causes there to be a disruption in the electromagnetic field which causes an x ray photon to be emitted
the filament electron continues on its course at a reduced speed due to a loss in kinetic energy
what happens if a filament electron comes into full contact with the nucleus
100% of its kinetic energy is emitted as an x ray photon
why is a beam of bremsstralung radiation reffered to as a heterogenous beam
because it contains photons of differing energies
why are beams of characteristic radiation reffered to as homogenous beams
because they contain photons that all have the same energy
which factors affect the xray photon energy produced during an inelastic interaction between the nucleus and the filament electron
the closer the filament electron travels towards the nucleus the stronger the force of attraction will be meaning the xray photon energy produced will be greater
