First cycle
degree courses
Second cycle
degree courses
Single cycle
degree courses
School of Science
Course unit
SCP7081740, A.A. 2019/20

Information concerning the students who enrolled in A.Y. 2019/20

Information on the course unit
Degree course Second cycle degree in
SC2382, Degree course structure A.Y. 2017/18, A.Y. 2019/20
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Degree course track NuPhys - NUCLEAR PHYSICS [004PD]
Number of ECTS credits allocated 6.0
Type of assessment Mark
Website of the academic structure
Department of reference Department of Physics and Astronomy
Mandatory attendance No
Language of instruction English
Single Course unit The Course unit can be attended under the option Single Course unit attendance
Optional Course unit The Course unit can be chosen as Optional Course unit

Teacher in charge MARCO MAZZOCCO FIS/01
Other lecturers SANDRA MORETTO FIS/01

Course unit code Course unit name Teacher in charge Degree course code

ECTS: details
Type Scientific-Disciplinary Sector Credits allocated
Core courses FIS/04 Nuclear and Subnuclear Physics 6.0

Course unit organization
Period Second semester
Year 1st Year
Teaching method frontal

Type of hours Credits Teaching
Hours of
Individual study
Practice 2.0 16 34.0 4
Lecture 4.0 32 68.0 No turn

Start of activities 02/03/2020
End of activities 12/06/2020
Show course schedule 2019/20 Reg.2017 course timetable

Prerequisites: The student must have attended the courses of "Introduction of Nuclear Physics" and "Nuclear Physics"
Target skills and knowledge: Introduction to "contemporary" Nuclear Physics. The main fields of research on experimental Nuclear Physics will be presented, and particular attention will be paid to the experimental activity presently going on at the Laboratori Nazionali di Legnaro and to experiments performed with Radioactive Ion Beams.
Examination methods: Oral examination. The student will be asked some questions concerning the different topics presented during the lectures. It is also foreseen a detailed analysis of one of the arguments by the student.
Assessment criteria: Knowledge of the student.
Clarity of the oral exposition.
Degree of personal detailed study.
Course unit contents: Radioactive decays. Summaries of the interaction of charged and neutral particles with matter in the energy range of nuclear physics and detection techniques.
Low energy nuclear energy: Ion accelerators: ion source, beam transport, magnetic analysis. Magnetic spectrometers, neutron detectors, charged particles and gamma radiation.
Dynamics of heavy ion reactions: the different types of nuclear reactions from elastic diffusion to complete fusion. Identification Techniques of Reaction Products, Detector Telescopes. Measurements of cross-section at energies around the Coulomb barrier. Angular distributions and excitation functions.
Gamma spectroscopy: energy calibration of gamma spectra, efficiency evaluation, activity computation. Angular distribution, multipolarity and polarization. Angular correlation and nuclear state description with statistical tensor. Average lifetime of excited states: electronic method, plunger, DSAM, Mossbauer.
Radioactive Beams: Production Methods "ISOL" and "IN-FLIGHT": Reactions with Secondary ISOL Beams: Coulombian excitation, nucleon transfer. Reactions with relativistic secondary beams: Coulombian and inelastic excitation, knock-out, charge exchange. Beta Decay: Measurements with Isol and In-flight beams, Total absorption spectrometry. Beta-delayed neutron emission.
Nuclear astrophysics: Exploring the nuclear reactions in the stars and the synthesis of elements, Gamow peak, S-factor. Deriving the thermonuclear reaction rate. Dependence on the temperature of the nuclear reaction rate. Combustion cycles: Combustion of hydrogen through the p-p chain and the CNO cycle. Helium combustion with 3-alpha and alpha + C reactions. Advanced nuclear combustion reactions. Relevant cross section measurements: direct underground measurements, indirect Trojan-horse measures, etc.
Low radioactivity techniques: The problem of environmental radioactivity, a good shielding material, a screening of shielding materials (lead, iron, OFHC copper, mercury). The Rn as contaminant in low radioactivity measures. Intrinsic Detector Radioactivity. Effects of cosmic radiation.
Applications: Date with radionuclides. Radionuclides in nuclear medicine. The melting of light nuclei for energy production. About nuclear reactors. Mass spectrometry with accelerators for trace analysis. Non destructive analysis with neutron activation.
Planned learning activities and teaching methods: Lectures will be given by using slides and, in case, the blackboard.
Additional notes about suggested reading: Review articles and scientific publications provided by the teacher during the lectures. Slides of the lectures.
Textbooks (and optional supplementary readings)
  • Krane, Kenneth S., Introductory nuclear physicsKenneth S. Krane. Hoboken: NJ, Wiley, 1987. Cerca nel catalogo
  • Knoll, Glenn F., Radiation detection and measurementGlenn F. Knoll. New York \etc.!: Wiley & Sons, --. Cerca nel catalogo