PHYSICS 757 : Quantum Optics and Quantum Information

Science

2025 Semester Two (1255) (15 POINTS)

Course Prescription

The nonrelativistic quantum treatment of electromagnetic radiation (light) and its interaction with matter (atoms, quantum dots, superconducting qubits) is presented. Emphasis is placed on what is strictly quantum mechanical about light compared with a description in terms of Maxwell waves, and on the concepts and methods underlying modern advances in quantum measurement theory and quantum technologies, e.g., quantum communication/cryptology and quantum simulation/computation.

Course Overview

This course provides an advanced treatment of the nonrelativistic quantum mechanics of photons and their interaction with matter. Beginning with the quantization of Maxwell's electromagnetic waves, it moves on to the preparation of quantum mechanical states of the electromagnetic field, their unique properties and their applications. The course aims to bring students with a firm grounding in the Dirac formulation of quantum mechanics to a level where they are competent to tackle current research papers in quantum optics and quantum information as well as the related areas of atomic and condensed matter physics. It is a recommended course for students planning postgraduate research in these fields.

Course Requirements

Restriction: PHYSICS 760

Capabilities Developed in this Course

Capability 3: Knowledge and Practice
Capability 4: Critical Thinking
Capability 5: Solution Seeking
Capability 6: Communication
Graduate Profile: Master of Science

Learning Outcomes

By the end of this course, students will be able to:
  1. Outline Dirac quantization of the electromagnetic field (Capability 3 and 6)
  2. Discuss the quantum mechanics of the harmonic oscillator as it relates to photons: energy spectrum, number, creation and annihilation operators; provide appropriate derivations. (Capability 3 and 6)
  3. Review the properties of quantum states of the electromagnetic field: thermal states, coherent states, squeezed states; provide appropriate derivations. (Capability 3 and 6)
  4. Define and use the P, Q, and Wigner representations of the electromagnetic field. (Capability 3, 4, 5 and 6)
  5. Derive and solve the Jaynes-Cummings model of quantized radiation interacting with matter (Capability 3 and 5)
  6. Solve problems in quantum damping theory employing master equations, quantum Langevin equations, inputs and outputs, correlation functions and quantum regression. (Capability 3, 4 and 5)
  7. Discuss resonance fluorescence as an example of quantum damping theory: Mollow spectrum, photon antibunching. (Capability 3, 4 and 6)
  8. Discuss and review applications of the above in quantum information science. (Capability 3 and 6)
  9. Devise an appropriate mathematical strategy to solve a problem set out in physical terms, possibly consulting online resources and/or fellow students. (Capability 4, 5 and 6)
  10. Present written solutions to assigned problems in a thoroughly argued manner, setting out the method used and all essential steps in a logical sequence. (Capability 4, 5 and 6)

Assessments

Assessment Type Percentage Classification
Assignments 40% Individual Coursework
Final Exam 60% Individual Examination
Assessment Type Learning Outcome Addressed
1 2 3 4 5 6 7 8 9 10
Assignments
Final Exam

Special Requirements

None.

Workload Expectations

This course is a standard 15-point course and students are expected to spend 10 hours per week involved in each 15-point course that they are enrolled in.

For this course, a typical weekly workload includes:

  • 2 hours of lectures
  • A 1-hour tutorial
  • 2 hours of reviewing the course content
  • 5 hours of work on assignments and/or test preparation

Delivery Mode

Campus Experience

Attendance is expected at scheduled activities including tutorials to complete components of the course.
The course will not include live online events.
Attendance on campus is required for the exam.
The activities for the course are scheduled as a standard weekly timetable.

Learning Resources

Course materials are made available in a learning and collaboration tool called Canvas which also includes reading lists and lecture recordings (where available).

Please remember that the recording of any class on a personal device requires the permission of the instructor.

Course Notes:
  • Lecture notes will be provided as pdfs available on Canvas
Recommended Readings:
  • D.F. Walls and G.J. Milburn, Quantum Optics, 2nd Ed. (2008)
  • H.J. Carmichael, Statistical Methods in Quantum Optics 1: Master Equations and Fokker-Planck Equations (1999)
  • H.J. Carmichael, Statistical Methods in Quantum Optics 2: Non-Classical Fields (2007)
  • C.W. Gardiner and P. Zoller, The Quantum World of Ultra-Cold Atoms and Light, Book I: Foundations of Quantum Optics (2014)
  • C.W. Gardiner and P. Zoller, The Quantum World of Ultra-Cold Atoms and Light, Book II: The Physics of Quantum-Optical Devices (2015)
  • L. Mandel and E. Wolf, Optical Coherence and Quantum Optics (1995)

Student Feedback

During the course Class Representatives in each class can take feedback to the staff responsible for the course and staff-student consultative committees.

At the end of the course students will be invited to give feedback on the course and teaching through a tool called SET or Qualtrics. The lecturers and course co-ordinators will consider all feedback.

Your feedback helps to improve the course and its delivery for all students.

More example calculations will be presented in tutorials.

Academic Integrity

The University of Auckland will not tolerate cheating, or assisting others to cheat, and views cheating in coursework, tests and examinations as a serious academic offence. The work that a student submits for grading must be the student's own work, reflecting their learning. Where work from other sources is used, it must be properly acknowledged and referenced. A student's assessed work may be reviewed against electronic source material using computerised detection mechanisms. Upon reasonable request, students may be required to provide an electronic version of their work for computerised review.

Class Representatives

Class representatives are students tasked with representing student issues to departments, faculties, and the wider university. If you have a complaint about this course, please contact your class rep who will know how to raise it in the right channels. See your departmental noticeboard for contact details for your class reps.

Copyright

The content and delivery of content in this course are protected by copyright. Material belonging to others may have been used in this course and copied by and solely for the educational purposes of the University under license.

You may copy the course content for the purposes of private study or research, but you may not upload onto any third party site, make a further copy or sell, alter or further reproduce or distribute any part of the course content to another person.

Inclusive Learning

All students are asked to discuss any impairment related requirements privately, face to face and/or in written form with the course coordinator, lecturer or tutor.

Student Disability Services also provides support for students with a wide range of impairments, both visible and invisible, to succeed and excel at the University. For more information and contact details, please visit the Student Disability Services’ website http://disability.auckland.ac.nz

Special Circumstances

If your ability to complete assessed coursework is affected by illness or other personal circumstances outside of your control, contact a member of teaching staff as soon as possible before the assessment is due.

If your personal circumstances significantly affect your performance, or preparation, for an exam or eligible written test, refer to the University’s aegrotat or compassionate consideration page https://www.auckland.ac.nz/en/students/academic-information/exams-and-final-results/during-exams/aegrotat-and-compassionate-consideration.html.

This should be done as soon as possible and no later than seven days after the affected test or exam date.

Learning Continuity

In the event of an unexpected disruption we undertake to maintain the continuity and standard of teaching and learning in all your courses throughout the year. If there are unexpected disruptions the University has contingency plans to ensure that access to your course continues and your assessment is fair, and not compromised. Some adjustments may need to be made in emergencies. You will be kept fully informed by your course co-ordinator, and if disruption occurs you should refer to the University Website for information about how to proceed.

The delivery mode may change depending on COVID restrictions. Any changes will be communicated through Canvas.

Student Charter and Responsibilities

The Student Charter assumes and acknowledges that students are active participants in the learning process and that they have responsibilities to the institution and the international community of scholars. The University expects that students will act at all times in a way that demonstrates respect for the rights of other students and staff so that the learning environment is both safe and productive. For further information visit Student Charter https://www.auckland.ac.nz/en/students/forms-policies-and-guidelines/student-policies-and-guidelines/student-charter.html.

Disclaimer

Elements of this outline may be subject to change. The latest information about the course will be available for enrolled students in Canvas.

In this course you may be asked to submit your coursework assessments digitally. The University reserves the right to conduct scheduled tests and examinations for this course online or through the use of computers or other electronic devices. Where tests or examinations are conducted online remote invigilation arrangements may be used. The final decision on the completion mode for a test or examination, and remote invigilation arrangements where applicable, will be advised to students at least 10 days prior to the scheduled date of the assessment, or in the case of an examination when the examination timetable is published.

Published on 06/11/2024 09:04 a.m.