Exciting advances in physics and technology in this century will likely result from the precision measurement and engineering of quantum states. This includes applications such as GPS, atomic clocks and quantum computing. Fundamental to this technology revolution is the science of the interaction of light with atoms, molecules and solids. Using these interactions we can study the detailed structure of these quantum systems.  We can also use these interactions to manipulate the quantum states of both light and matter.  An example of the former is the laser; examples of the latter are laser cooling of atoms, Bose Einstien condensates and quantum computing.

In this course students will first learn about the classical and quantum nature of laser light, the quantum description of atoms molecules.  We will then learn about the interactions between light and atoms and the technques to study these effects in the laboratory.  The fundamental models that underpin this active area of research and how to relate these models to current and future technologies will be investigated.  The concepts and theory developed in lectures will be directly enhanced by laboratory experiments. The laboratory is equipped with state of the art lasers, optics and expert instruction from leading practitioners in the field. 

On satisfying the requirements of this course, students will have the knowledge and skills to:

1. Understand the theory of atomic structure including fine and hyperfine structure

2. Understand the theory of the structure and dynamics of simple molecules.

3. Understand the classical and quantum theories of atom-light interactions.

4. Apply these theories to the solution of topical problems in modern physics.

5. Describe the state of the art in experimental quantum mechanics.

6. Develop advanced laboratory and report writing skills.

• Examinations to benchmark students' understanding of course material via a final examination: the exam will test students grasp of fundamental concepts (LO 1, 2, 3) and their grasp of the applications of fundamental principles (LO 3) (40% in total)
• Weekly assignments, in conjunction with tutorials, to show students understand the techniques required to solve and understand relevant problems (20% in total; LO 1-4)
• Laboratory reports of a closely supervised advanced course: students are led through the design, construction and understanding of a modern atomic physics experiment, and are required to write a report in LaTeX in the form of a journal article on their findings (30%; LO 1, 4, 5, 6)
• Short synopsis on a published research paper, selected from a group of papers relevant to the course. (10%: LO 5) 

A total of 26 lectures, 12 hours laboratory work and 10 tutorial hours.

PHYS3001