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Measurement of Absorbed Dose (4)

Measurement of Absorbed Dose (4). 參考資料: 1. The Physics of Radiation Therapy. Faiz M. Khan 2. Introduction to Radiological Physics and Radiation Dosimetry. Frank H. Attix. STOPPING POWER.

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Measurement of Absorbed Dose (4)

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  1. Measurement of Absorbed Dose (4) 參考資料:1. The Physics of Radiation Therapy.Faiz M. Khan2. Introduction to Radiological Physics and Radiation Dosimetry. Frank H. Attix

  2. STOPPING POWER • The expectation value of the rate of energy loss per unit of path length x by a charged particle of type Y and kinetic energy T, in a medium of atomic number z, • MeV/cm or J/m • 1 MeV/cm = 1.602 X 10-11 J/m

  3. STOPPING POWER • mass stopping power (dT/ρ dx) • MeV cm2 / g or J m2 / kg • 1 MeV cm2 / g = 1.602 X 10-l4 J m2 / kg • collision stopping power • the rate of energy loss resulting from the sum of the soft and hard collisions, which are conventionally referred to as "collision interactions.“ • radiative stopping power • owing to radiative interactions, bremsstrahlung

  4. STOPPING POWER • Energy spent in radiative collisions is carried away from the charged-particle track by the photons, • while that spent in collision interactions produces ionization and excitation contributing to the dose near the track.

  5. STOPPING POWER • Types of charged-particle coulomb-force interactions

  6. STOPPING POWER • "Soft" Collisions (b >> a) • When a charged particle passes an atom at a considerable distance, the influence of the particle's Coulomb force field affects the atom as a whole, thereby distorting it, exciting it to a higher energy level, and sometimes ionizing it by ejecting a valence shell electron. The net effect is the transfer of a very small amount of energy (a few eV) to an atom of the absorbing medium

  7. STOPPING POWER • Hard (or "Knock-On") Collisions (b~a) • the incident particle will interact primarily with a single atomic electron, which is then ejected from the atom with considerable kinetic energy and is called a delta (δ) ray. • δ-ray dissipates its kinetic energy along a separate track (called a "spur") from that of the primary charged particle.

  8. STOPPING POWER • mass collision stopping power • where subscripts c indicate collision interactions, s being soft and h hard.

  9. STOPPING POWER • Dependence on the stopping medium • decrease the mass collision stopping power as Z is increased

  10. STOPPING POWER • Dependence on particle velocity • decrease the mass collision stopping power as particle velocity increases. • The stopping power gradually flattens to a broad minimum of 1-2 MeV cm2 /g at T/m0c2 ≒ 3, and then slowly rises again with further increasing T.

  11. STOPPING POWER • Dependence on particle charge • Z2 , a doubly charged particle of a given velocity has 4 times the collision stopping power as a singly charged particle of the same velocity in the same medium. • an a-particle would have a mass collision stopping power of 200 MeV cm2 / g, compared with the 50 MeV cm2 / g shown for a singly charged heavy particle in water. • Dependence on particle mass • There is none.

  12. STOPPING POWER • Restricted Stopping Power • The mass collision stopping power expresses the average rate of energy loss by a charged particle in all hard, as well as soft, collisions. • The δ-rays resulting from hard collisions may be energetic enough to carry kinetic energy a significant distance away from the track of the primary particle.

  13. STOPPING POWER • Restricted Stopping Power • More importantly, if one is calculating the dose in a small object or thin foil transversed by charged particles, the use of the mass collision stopping power will overestimate the dose, unless the escaping δ-rays are replaced.

  14. STOPPING POWER • Restricted Stopping Power • The restricted stopping power is that fraction of the collision stopping power that includes all the soft collisionsplus those hard collisions resulting in δ rays with energies less than a cutoff value Δ. • symbolized here as

  15. STOPPING POWER • Restricted Stopping Power • An alternative and very important form of restricted stopping power is known as the linear energy transfer, LET, symbolized as LΔ ( ICRU, 1980) • LET is of greatest relevance in radiobiology and microdosimetry.

  16. STOPPING POWER • Restricted Stopping Power • If the cutoff energy Δ is increased to equal Tmax then

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