Introduction to Nuclear and Particle Physics
Course content
The purpose of this course is to introduce the physics of the strong and electroweak interactions. These fundamental forces describe nature's smallest components: elementary particles and atomic nuclei.
The course will cover the theoretical and experimental advances which have led to the current understanding of physics at the subatomic scale. The course will outline the currently open questions in subatomic physics and may also address selected topics of current interest.
More specifically, the course will cover the following topics:
 Symmetries and conservation laws in nuclear and particle physics.
 Relativistic kinematics and applications in highenergy reactions.
 The Standard Model theory: fundamental matter particles and their interactions by strong and electroweak forces.
 The Higgs and the origin of mass.
 Neutrino oscillations and masses.
 Ultrarelativistic nucleus collisions, quarkgluon plasma in the early universe and in the laboratory.
 Nuclear models (liquid drop, shell and collective model).
 The nucleonnucleon interaction.
 Models of alpha, beta and gamma decay, fission.
 Nuclear astrophysics, primordial and stellar nucleosynthesis.
The course forms the basis for future studies or projects in particle physics or nuclear physics.
BSc Programme in Physics
At the end of the course the student is expected to be able to:
Skills
 Determine which nuclear and particle processes are allowed by conservation laws.
 Calculate the outcome of highenergy collisions with relativistic kinematics.
 Estimate the rates and cross sections of particle physics
processes, e.g. beta decay or neutrino scattering, with the concept
of Feynman diagrams.
Knowledge
 Recall the basics of the Standard Model theory for particle physics and basic models describing atomic nuclei.
 Give an account of nuclear and particle phenomenology in terms of subatomic particles and interactions and demonstrate understanding of relevant energy scales and quantum numbers.
 Describe atomic nuclei as a quantummechanical manybody system bound by an effective strong interaction.
 Describe properties of nuclear reactions and radioactivity in terms of effective models (alpha, beta, and gamma decays).
 Describe experimental methods of nuclear and particle physics.
 Recall essential experimental results which have led to the formulation of the Standard Model.
 Relate length and time scales, relevant for particle
interactions and decays, to characteristic mass scales of nuclear
and particle physics.
Competences
 Apply basic knowledge of e.g. quantum mechanics and special relativity, gained in previous courses, to describe subatomic phenomena.
 Explain the important properties of elementary particles and their interactions in the Standard Model of particle physics.
 Explain nuclear excitations and decays in terms of nuclear models.
 Estimate decay rates and characteristics of fusion and fission reactions.
 Formulate the basic elements of calculations of cross sections and decay rates in particle physics.
 Explain how nuclear and particle physics phenomena contribute to the evolution of the universe, from the Big Bang to present day processes in stars.
Lectures and exercises
For final course literature see Absalon.
The following is an example of suggested course literature:
B.R. Martin. Nuclear and particle physics. Wiley, 3rd ed.
Good level of Classical mechanics, Electromagnetism, Quantum Mechanics, Special Relativity (corresponding to the mandatory courses of the physics B.Sc.).
 ECTS
 7,5 ECTS
 Type of assessment

Continuous assessmentThe exam consists of two parts:
1) two takehome exams during the course
2) continuous exercises and quizzes
Each student has a choice between two levels of problem sets for takehome exams and exercises:
• standard problem sets with detailed questions and hints
• advanced problem sets with open questions
The grade combines the grade from takehome exercises (35% each) and the combined grade from continuous exercises and quizzes (30% total).
Each part of the exam has to be passed separately in order to pass the course.  Aid
 All aids allowed
 Marking scale
 7point grading scale
 Censorship form
 No external censorship
Several internal examiners
Criteria for exam assessment
See "Learning Outcome".
Single subject courses (day)
 Category
 Hours
 Lectures
 40
 Preparation
 54
 Exercises
 48
 Exam
 64
 English
 206
Kursusinformation
 Language
 English
 Course number
 NFYB13008U
 ECTS
 7,5 ECTS
 Programme level
 Bachelor
 Duration

1 block
 Schedulegroup

C
 Capacity
 no limit
 Studyboard
 Study Board of Physics, Chemistry and Nanoscience
Contracting department
 The Niels Bohr Institute
Contracting faculty
 Faculty of Science
Course Coordinator
 Jørgen Beck Hansen (4676a68704573676e33707a336970)
Teacher
Jørgen Beck Hansen
Ian Bearden
Markus Tobias Ahlers
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