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Transcript
Interactions of Photons with Matter – Coherent Scatter (Part 1) George Starkschall, Ph.D. Lecture Objectives • Identify and describe the process of coherent scatter • Calculate the cross sections for coherent scatter Description • Classically: Electromagnetic wave passing near atom excites electrons to oscillate • Oscillating electrons accelerated, emitting energy • Angle of scatter is small • Scatter interactions are with electrons – scatter from nuclei relatively infrequent 1 Thomson scatter • First theoretical treatment of classical scatter • Did not agree with experiment, but Thomson scatter cross section included in all scattering equations – provides good start Scatter cross section • Look upon differential scatter cross section as related to the probability that an incident photon produces scattered photon at specified solid angle • Units of cross section are [m2 electron(atom)-1 steradian-1] Scatter cross section • From differential scatter cross section we can calculate fraction of energy scattered in any direction • Fraction of energy scattered = scattering cross section × electron(atom) areal density × angle subtended by detector 2 Scatter cross section • So, to calculate a scattering cross section, we need to determine the fraction of energy scattered per electron (atom) areal density per solid angle subtended by detector Follow the energy! Thomson scatter • Start with classical description of electromagnetic wave – E and B at right angles moving with velocity c – E unpolarized, components E1 and E2 • Interaction with atom: Electric field causes electron to accelerate • Electron acceleration induces electric field • Fraction of energy scattered related to induced electric field Thomson scatter • Consider electric field interacting with free electron • Force on free electron due to electric field Fi = keEi Where – e: – E: – i: – k: electron charge electric field (in same direction of force) = 1 or 2 same constant as in Coulomb force equation (8.988 109 Nt m2/C2) 3 Thomson scatter • The electron will accelerate in the same direction of the force: F = ma • Solve for the acceleration of an electron due to an electric field ai = keEi/m0 • From classical E & M, the accelerated charge will radiate energy in an electromagnetic wave • This is the scattered radiation whose intensity we need to calculate Thomson scatter • Look at the electric field vector at point Q due to accelerated charge at origin Thomson scatter r – distance PQ - angle between E1 and PQ 4 Thomson scatter • Define the classical electron radius by • Note: This is a very small number. The diameter of a nucleus is 10-13 m • Then Thomson scatter • Similarly, the component E2 will give rise to electric field component (note that is parallel to • The electric vector of a radiated wave is a very small fraction of the electric vector of the incident wave (r0 very small) 5
