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1 FK7003 Lecture 17 – Interactions in Matter ● Electromagnetic interactions in material ● Hadronic interactions in material ● Electromagnetic and hadronic showers
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2 FK7003 Why we can neglect weak interactions 10 3 10 6 10 9 110 3 10 6 E (TeV) Neutrino interaction lengthi In water/km Probability of interaction ~ 10 -5 / km water at 100 TeV energy 100 billion neutrinos pass through your thumbnail each second but only 1-2 will interact in your body during your lifetime. From lecture 3 Mean distance between interactions of neutrino + water molecule as neutrinos pass through water (interaction length).
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3 FK7003 Strategy Energy loss of particles in matter Electromagnetic energy loss ● Energy loss through collisions (ionisation) ● Radiation loss ● Electromagnetic shower Hadronic energy loss ● Energy loss through nuclear collisions ● Hadronic shower
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4 FK7003 Ionisation energy loss M
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5 FK7003 M l Semi-classical derivation (skip)
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6 FK7003
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7 M
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10 FK7003 Interaction between two particles
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11 FK7003 Bethe-Bloch formula (17.23)
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12 FK7003 Bethe-Bloch formula
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13 FK7003 Measurements of ionisation energy loss e
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14 FK7003 Strategy Energy loss of particles in matter Electromagnetic energy loss ● Energy loss through collisions (ionisation) ● Radiation loss ● Electromagnetic shower Hadronic energy loss ● Energy loss through nuclear collisions ● Hadronic shower
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15 FK7003 Radiation energy loss E0E0 x
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16 FK7003 Energy loss of an electron in copper ECEC
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17 FK7003 Question
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18 FK7003 Strategy Energy loss of particles in matter Electromagnetic energy loss ● Energy loss through collisions (ionisation) ● Radiation loss ● Electromagnetic shower Hadronic energy loss ● Energy loss through nuclear collisions ● Hadronic shower
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19 FK7003 Photons
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20 FK7003 Photon absorption in lead Lead
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21 FK7003 1997
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22 FK7003 2007 (i) (ii)
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23 FK7003 Electromagnetic shower E0E0 E 0 /2 E 0 /4 t=No. X 0 No. e + No. e - No. No. particles 00101 10112 21214 32338
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24 FK7003 Electromagnetic shower Observed electromagnetic shower (next lecture)
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25 FK7003 Strategy Energy loss of particles in matter Electromagnetic energy loss ● Energy loss through collisions (ionisation) ● Radiation loss ● Electromagnetic shower Hadronic energy loss ● Energy loss through nuclear collisions ● Hadronic shower
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26 FK7003 Hadronic energy loss p xx
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27 FK7003 Nuclear shower EM Cascade Nuclear cascade
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28 FK7003 A simple model for hadronic scattering in material p p L 1 2 3 xx
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29 FK7003 p L Interaction Length xx 1 23 p
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30 FK7003 Proton-nucleon cross sections p p
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31 FK7003 Nuclear interaction length
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32 FK7003 Stopping in iron
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33 FK7003 Strategy Energy loss of particles in matter Electromagnetic energy loss ● Energy loss through collisions (ionisation) ● Radiation loss ● Electromagnetic shower Hadronic energy loss ● Energy loss through nuclear collisions ● Hadronic shower
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34 FK7003 Energy loss mechanisms Important energy loss mechanisms for collider experiments (next lecture). ParticleIonisation energy loss Radiation energy loss Hadronic energy loss e + e - pair production e-e- Important only for low energies (<30 MeV) † xx Important only at high energies (E >several hundred GeV ) † xx Charged hadrons (p, K …) Important only at high energies (E > several hundred GeV: K - ; E> 1 TeV: p ) † x Neutral hadrons (n,K 0 ) xx x Photon xxx † Not important for these lectures
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35 FK7003 Summary ● Interactions of particle in material ● Electromagnetic and hadronic energy loss Ionisation and radiation energy loss (em) Hadronic energy loss (strong) ● Now ready to design an detector for a collider experiment (next lecture).
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