FY541: Atomic physics

The Study Board for Science

Teaching language: English
EKA: N500041102
Assessment: Second examiner: Internal
Grading: 7-point grading scale
Offered in: Odense
Offered in: Autumn
Level: Bachelor

STADS ID (UVA): N500041101
ECTS value: 5

Date of Approval: 28-04-2023


Duration: 1 semester

Version: Approved - active

Comment

The course is identical to the previous course titled FY536 Quantum Optics (UVA N500020101). Last offered autumn 2018. This means that if you have previously taken exam attempts in FY536 Quantum Optics, these attempts will be transferred to this new course.

Entry requirements

The course cannot be followed by students who have passed FY536 Quantum Optics.

Academic preconditions

Students taking the course are expected to have knowledge of classical mechanics, electromagnetism, and introductory quantum mechanics.

Course introduction

Course introduction. This course provides an introduction to the fundamentals of atomic, molecular and optical (AMO) physics as well as a review of current “hot topics” in this field. At the end of the course the student will have a firm foundation in modern atomic physics as well as knowledge of the state-of-the-art in experimental quantum physics.
The course therefore establishes an important foundation for students who want to continue to study atomic, molecular, and optical physics at a higher level in both theory and experiment.

The course builds on the knowledge acquired in the courses: FT504: Electromagnetism and Optics (10 ECTS), Quantum mechanics I and II (FY544 and FY547) (2 x 5 ECTS), and gives an academic basis for studying the topics of modern quantum science, such as atomic & molecular physics, quantum optics, quantum information science and photonics.

The focus of the course is to:
  • Give the competence to handle complex problems and independently take part in interdisciplinary work and apply the course content to innovative problem solving.
  • Give skills to apply physical principles and mathematical tools to formulate and evaluate physical models.
  • Give knowledge and understanding of the fundamentals of quantum mechanics and their applications to atoms and light.

Expected learning outcome

The learning objectives of the course are that the student demonstrates the ability to:
  • Apply the formalism of quantum mechanics to describe atomic systems and their interaction with electromagnetic fields.
  • Understand the fundamentals of atomic physics as the core principle to explain the periodic system and the formation of matter.
  • Apply the principles of quantum mechanics to quantitatively describe the outcome of different state-of-the-art experiments.
  • Understand the implications of quantum mechanical phenomena in both fundamental science and technological applications.

Content

Subject overview: The following main topics are contained in the course:
  • Atomic structure – atomic physics beyond the hydrogen atom
  • Multi-electron atoms and molecules
  • Atoms in electromagnetic fields
  • Atom-light interaction
  • Ultracold atoms and ions
  • Nuclear magnetic resonance
  • Nano-optics

Literature

  • D. J. Griffiths, Introduction to Quantum Mechanics (3rd edition)
  • Christopher Foot: Atomic Physics

See itslearning for syllabus lists and additional literature references.

Examination regulations

Exam element a)

Timing

Autumn and January

Tests

Portfolio and test

EKA

N500041102

Assessment

Second examiner: Internal

Grading

7-point grading scale

Identification

Full name and SDU username

Language

Normally, the same as teaching language

Examination aids

All common aids are allowed e.g. books, notes and computer programmes which do not use internet etc. 

Internet is not allowed during the exam. However, you may visit the course site in itslearning to open system "DE-Digital Exam". If you wish to use course materials from itslearning, you must download the materials to your computer no later than day before the exam. During the exam you cannot be sure that all course materials is accessible in itslearning.    

ECTS value

5

Additional information

Portfolio consisting of two parts:
  1. Project reports (incl. NMR Lab report), which is placed during the course of the period
  2. Written exam, which is placed in the exam period
An assessment is made of the portfolio examination according to the 7-point grading scale based on the written exam. In order to obtain a passed grade for the written exam, 75% of the project reports etc. Under part 1 has to be approved.

Indicative number of lessons

42 hours per semester

Teaching Method

At the faculty of science, teaching is organized after the three-phase model ie. intro, training and study phase.
  • Intro phase (lectures): 28 hours (14 weeks with one lecture per week)
  • Skills training phase: 14 hours, hereof: 14 tutorials (one double lesson with tutorials every other week), including one lab session focused on nuclear magnetic resonance (NMR) spectroscopy.
Educational form: The intro phase consists of lectures in which the central topics of the course are reviewed. This is done both with general theory and via examples. Even though most of the teaching is based on lectures there is a strong focus on involving the students via questions and discussion.
In the tutorials, it is expected that the students develop their skills via problem solving and discussions with the teacher and among themselves. The students will solve problems at the blackboard based on initial preparation at home and with the help of everybody else. In the NMR lab, the students will get acquainted with measuring and analysing atomic spectra.

Activities during the study phase: Problem solving.

Teacher responsible

Name E-mail Department
Christos Tserkezis ct@mci.sdu.dk Center for Polariton-driven Light-Matter Interactions (POLIMA)
Joel Cox cox@mci.sdu.dk Center for Polariton-driven Light-Matter Interactions (POLIMA)

Timetable

Administrative Unit

Fysik, kemi og Farmaci

Team at Educational Law & Registration

NAT

Offered in

Odense

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Transition rules

Transitional arrangements describe how a course replaces another course when changes are made to the course of study. 
If a transitional arrangement has been made for a course, it will be stated in the list. 
See transitional arrangements for all courses at the Faculty of Science.