ELEMENTARY PARTICLE PHYSICS (MOD. A+B)
(objectives)
module A: acquiring the fundamental knowledge on the phenomenological bases of the Standard Model of Elementary Particles and on the principles of particle detection
module B: acquiring in-depth knowledge of modern data detection and analysis techniques and the current phenomenological framework in the various sectors of Elementary Particle Physics with and without accelerators
|
Code
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20402217 |
Language
|
ITA |
Type of certificate
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Profit certificate
|
Module:
(objectives)
module A: acquiring the fundamental knowledge on the phenomenological bases of the Standard Model of Elementary Particles and on the principles of particle detection
module B: acquiring in-depth knowledge of modern techniques for revealing and analyzing data and the current phenomenological framework in the different sectors of Physics of Elementary Particles with and without accelerators
|
Code
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20402217-2 |
Language
|
ITA |
Type of certificate
|
Profit certificate
|
Credits
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6
|
Scientific Disciplinary Sector Code
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FIS/04
|
Contact Hours
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52
|
Type of Activity
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Core compulsory activities
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Teacher
|
SALAMANNA GIUSEPPE
(syllabus)
SECTION A a) intro and formal tools: - Relativistic equations, selection rules, cross sections and resonances - Invariance principles and conservation rules, continuous and discrete transformations, Parity, Charge conjugation, Time inversion
b) early phenomenology, hadrons: - Strong isospin, Strangeness - Dalitz plots and their interpretation - Quark model, mentions - Parton model, quark and anti-quark density
c) Electro-weak interactions, decays, flavour mixing - Hamiltonian and phenomenology of weak interazions. Cabibbo angle, GIM mechanism. Discovery of the charm quark and tau lepton. - Standard model of electro-weak interactions and their experimental confirmations: discovery of neutral currents, W and Z bosons - CP violation, meson mixing - Evolution of events at hadronic colliders, parton shower, jet alorithms and related measurements - Neutrino physics from the Fermi theory to the current day: particularly neutrino oscillations
d) QCD: anatomy and at work at modern colliders: - QCD, colour, gluons, confinement, DIS
e) Intro to experimental tools, also useful for theorists - Radiation - matter interactions. Basics of particle detection techniques
SECTION B - Elements of statistical analysis applied to particle physics experiments - Experiments and results at LEP - Higgs boson searches and mentions of BSM searches at colliders - Examples of experimental neutrino physics and Dark Matter searches - b-jet identification and top quark measurements - Complex detectors: magnetic spectrometers, particle identification, large detectors - Scintillators and optical devices (PMT, APD, SiPM). Solid state detectors. Multi-wire proportional chambers. - E.m. and hadronic calorimetry - Trigger systems and menucs at modern experiments - ROOT analysis software tutorial
(reference books)
TEXTS: (Leo W.R.)Techniques for Nuclear and Particle Physics Experiments [Springer-Verlag 1994] (Perkins D.H.)Introduction to High Energy Physics, 4th edition, [Cambridge University Press, 2000] (Cahn R.N. and Goldhaber G.)The experimental Foundations of Particle Physics [Cambridge University Press, 1989] (Halzen F., Martin A.D.) Quarks and leptons [Wiley]
Additional slides and papers will be uploaded on the Course web page
|
Dates of beginning and end of teaching activities
|
From to |
Delivery mode
|
Traditional
|
Attendance
|
not mandatory
|
Evaluation methods
|
Oral exam
|
Teacher
|
PETRUCCI FABRIZIO
(syllabus)
SECTION A a) intro and formal tools: - Relativistic equations, selection rules, cross sections and resonances - Invariance principles and conservation rules, continuous and discrete transformations, Parity, Charge conjugation, Time inversion
b) early phenomenology, hadrons: - Strong isospin, Strangeness. Pion isospin and its expt. determination - Dalitz plots and their interpretation. Theta-tau puzzle. - Quark model, mentions - Parton model, quark and anti-quark density
c) Electro-weak interactions, decays, flavour mixing - Hamiltonian and phenomenology of weak interazions. Experimental constraints from Wu (P violation) and Goldhaber (neutrino helicity) - Cabibbo angle, GIM mechanism. Discovery of the charm quark and tau lepton. The 1974 "November revolution" - Standard model of electro-weak interactions and their experimental confirmations: discovery of neutral currents, Gargamelle expt. W and Z bosons discovery and UA1,2 - CP violation, meson mixing. Mentions to B-factories and measurement of CKM angles from B mesons - Evolution of events at hadronic colliders, parton shower, jet alorithms and related measurements - Neutrino physics from the Fermi theory to the current day: particularly neutrino oscillations
d) QCD: anatomy and at work at modern colliders: - QCD, colour, gluons, confinement, DIS - Evolution of events at hadron colliders, parton showers, algorithms, measurements with jets at Tevatron.
e) Intro to experimental tools, also useful for theorists - Radiation - matter interactions. Basics of particle detection techniques
SECTION B - Elements of statistical analysis applied to particle physics experiments - Experiments and results at LEP - Higgs boson searches and mentions of BSM searches at colliders - Examples of experimental neutrino physics and Dark Matter searches - b-jet identification and top quark measurements - Complex detectors: magnetic spectrometers, particle identification, large detectors - Scintillators and optical devices (PMT, APD, SiPM). Solid state detectors. Multi-wire proportional chambers. - E.m. and hadronic calorimetry - Trigger systems and menucs at modern experiments - ROOT analysis software tutorial
(reference books)
TEXTS: (Leo W.R.)Techniques for Nuclear and Particle Physics Experiments [Springer-Verlag 1994] (Perkins D.H.)Introduction to High Energy Physics, 4th edition, [Cambridge University Press, 2000] (Cahn R.N. and Goldhaber G.)The experimental Foundations of Particle Physics [Cambridge University Press, 1989] (Halzen F., Martin A.D.) Quarks and leptons [Wiley]
Additional slides and papers will be uploaded on the Course web page
|
Dates of beginning and end of teaching activities
|
From to |
Delivery mode
|
Traditional
|
Attendance
|
not mandatory
|
Evaluation methods
|
Oral exam
|
|
|
Module:
(objectives)
module A: acquiring the fundamental knowledge on the phenomenological bases of the Standard Model of Elementary Particles and on the principles of particle detection
module B: acquiring in-depth knowledge of modern techniques for revealing and analyzing data and the current phenomenological framework in the different sectors of Physics of Elementary Particles with and without accelerators
|
Code
|
20402217-1 |
Language
|
ITA |
Type of certificate
|
Profit certificate
|
Credits
|
6
|
Scientific Disciplinary Sector Code
|
FIS/04
|
Contact Hours
|
52
|
Type of Activity
|
Core compulsory activities
|
Teacher
|
SALAMANNA GIUSEPPE
(syllabus)
SECTION A a) intro and formal tools: - Relativistic equations, selection rules, cross sections and resonances - Invariance principles and conservation rules, continuous and discrete transformations, Parity, Charge conjugation, Time inversion
b) early phenomenology, hadrons: - Strong isospin, Strangeness. Pion isospin and its expt. determination - Dalitz plots and their interpretation. Theta-tau puzzle. - Quark model, mentions - Parton model, quark and anti-quark density
c) Electro-weak interactions, decays, flavour mixing - Hamiltonian and phenomenology of weak interazions. Experimental constraints from Wu (P violation) and Goldhaber (neutrino helicity) - Cabibbo angle, GIM mechanism. Discovery of the charm quark and tau lepton. The 1974 "November revolution" - Standard model of electro-weak interactions and their experimental confirmations: discovery of neutral currents, Gargamelle expt. W and Z bosons discovery and UA1,2 - CP violation, meson mixing. Mentions to B-factories and measurement of CKM angles from B mesons - Evolution of events at hadronic colliders, parton shower, jet alorithms and related measurements - Neutrino physics from the Fermi theory to the current day: particularly neutrino oscillations
d) QCD: anatomy and at work at modern colliders: - QCD, colour, gluons, confinement, DIS - Evolution of events at hadron colliders, parton showers, algorithms, measurements with jets at Tevatron.
e) Intro to experimental tools, also useful for theorists - Radiation - matter interactions. Basics of particle detection techniques
SECTION B - Elements of statistical analysis applied to particle physics experiments - Experiments and results at LEP - Higgs boson searches and mentions of BSM searches at colliders - Examples of experimental neutrino physics and Dark Matter searches - b-jet identification and top quark measurements - Complex detectors: magnetic spectrometers, particle identification, large detectors - Scintillators and optical devices (PMT, APD, SiPM). Solid state detectors. Multi-wire proportional chambers. - E.m. and hadronic calorimetry - Trigger systems and menucs at modern experiments - ROOT analysis software tutorial
(reference books)
TEXTS: (Leo W.R.)Techniques for Nuclear and Particle Physics Experiments [Springer-Verlag 1994] (Perkins D.H.)Introduction to High Energy Physics, 4th edition, [Cambridge University Press, 2000] (Cahn R.N. and Goldhaber G.)The experimental Foundations of Particle Physics [Cambridge University Press, 1989] (Halzen F., Martin A.D.) Quarks and leptons [Wiley]
Additional slides and papers will be uploaded on the Course web page
|
Dates of beginning and end of teaching activities
|
From to |
Delivery mode
|
Traditional
|
Attendance
|
not mandatory
|
Evaluation methods
|
Oral exam
|
Teacher
|
PETRUCCI FABRIZIO
(syllabus)
SECTION A a) intro and formal tools: - Relativistic equations, selection rules, cross sections and resonances - Invariance principles and conservation rules, continuous and discrete transformations, Parity, Charge conjugation, Time inversion
b) early phenomenology, hadrons: - Strong isospin, Strangeness. Pion isospin and its expt. determination - Dalitz plots and their interpretation. Theta-tau puzzle. - Quark model, mentions - Parton model, quark and anti-quark density
c) Electro-weak interactions, decays, flavour mixing - Hamiltonian and phenomenology of weak interazions. Experimental constraints from Wu (P violation) and Goldhaber (neutrino helicity) - Cabibbo angle, GIM mechanism. Discovery of the charm quark and tau lepton. The 1974 "November revolution" - Standard model of electro-weak interactions and their experimental confirmations: discovery of neutral currents, Gargamelle expt. W and Z bosons discovery and UA1,2 - CP violation, meson mixing. Mentions to B-factories and measurement of CKM angles from B mesons - Evolution of events at hadronic colliders, parton shower, jet alorithms and related measurements - Neutrino physics from the Fermi theory to the current day: particularly neutrino oscillations
d) QCD: anatomy and at work at modern colliders: - QCD, colour, gluons, confinement, DIS - Evolution of events at hadron colliders, parton showers, algorithms, measurements with jets at Tevatron.
e) Intro to experimental tools, also useful for theorists - Radiation - matter interactions. Basics of particle detection techniques
SECTION B - Elements of statistical analysis applied to particle physics experiments - Experiments and results at LEP - Higgs boson searches and mentions of BSM searches at colliders - Examples of experimental neutrino physics and Dark Matter searches - b-jet identification and top quark measurements - Complex detectors: magnetic spectrometers, particle identification, large detectors - Scintillators and optical devices (PMT, APD, SiPM). Solid state detectors. Multi-wire proportional chambers. - E.m. and hadronic calorimetry - Trigger systems and menucs at modern experiments - ROOT analysis software tutorial
(reference books)
TEXTS: (Leo W.R.)Techniques for Nuclear and Particle Physics Experiments [Springer-Verlag 1994] (Perkins D.H.)Introduction to High Energy Physics, 4th edition, [Cambridge University Press, 2000] (Cahn R.N. and Goldhaber G.)The experimental Foundations of Particle Physics [Cambridge University Press, 1989] (Halzen F., Martin A.D.) Quarks and leptons [Wiley]
Additional slides and papers will be uploaded on the Course web page
|
Dates of beginning and end of teaching activities
|
From to |
Delivery mode
|
Traditional
|
Attendance
|
not mandatory
|
Evaluation methods
|
Oral exam
|
|
|
|