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PHYC/ECE 564 Lasers II

NOTE: This course is offered as PHYC 569, Advanced Optics in Modern Optics


Prof. Mansoor Sheik-Bahae

To see me in my office, please make an appointment (call or email)

Class meeting times

Tu, Th, 5:30-6:45 Physics and Astronomy, Room 184

Reference Textbooks

  • Laser Electronics by J.T. Verdeyen
  • Optical Electronics in Modern Communications by Amnon Yariv
  • Physics of Optoelectronic Devices by S. L. Chuang
  • Lasers by Milonni and Eberly
  • Photonics by Saleh and Teich
  • Theory of Optical Properties in Semiconductors by P. K. Basu


Advanced Optics, Laser Physics I, (Check UNM Catalog for more details). Basic knowledge of Quantum Mechanics is also required.

Teaching Assistant

Chi Feng Wang


Homework problem sets will be assigned on a regular basis throughout the semester.

Assignment #Due DateDescriptionSolution
1Sept. 6pdf


2Sept. 20pdf



Oct. 4




Nov. 3



Take Home Exam

Nov. 22

10 am-to front office




   Happy Thanksgiving 


Wed. May 14 (5:30-..)

Potential Topics for Final Projects (Submit a title and an abstract by May 1st.)You may choose from the following list or suggest your own topic

Physics and Properties of Semiconductor Devices

  • Semiconductor Quantum Dot Lasers
  • Optically Pumped Semiconductor Lasers
  • Quantum Cascade Lasers
  • Pushing the modulation BW of diode lasers


  • PW Femtosecond Systems and Applications
  • Kerr Combs
  • Advances in Attosceince and HHG
  • Ultrafast Characterization
  • High Intensity Interactions (e.g. Relativistic)
  • THz Frontiers


  • Metamaterials
  • New Frontiers in Optical Telecom

Please let me know the title of your final presentation no later than Nov. 28

Final Presentations

Wed. Dec. 7 (4 pm-6 pm) Room 1131

Thu . Dec. 8 (4 pm-6 pm) Room 184

  • An oral presentation ( maximum of 18 minutes) is expected on each subject
  • There will be an additional 3-5 minutes for question and answer at the end of each presentation
  • All students enrolled are required to attend every presentation by their fellow classmates and preferably participate in the discussions
  • The presentations should be clear and understandable by all the students. Use equations sparingly (only if needed) and avoid crowded viewgraphs. Remember that you are responsible for making the class understand the topic. Do not try to cover to much material

Useful Tips and Articles for Student Presentations

Project Title



Hollow-Core Optical Fiber Gas Lasers

Beygi Azar A, Farzin


Quantum Cascade Lasers (QCL)

Giannini, Nathan


Ultrafast Optical Parametric Amplifiers

Khabbazi Oskouei, Amir


Self-referencing Frequency Combs

Meng, Junwei


ML Lasers (Numerical Analysis)

Rostami, Saeid


HHG and Attoscience

Sukeert, Sukeert


Quantum Dot (QD) Lasers

Taghipour, Zahra


Optically Pumped Semiconductor Lasers (OPSL)

Wyman, Keith A



There will be one midterm exam and a final presentation.

Midterm Test Date

Check the UNM's Office of Registrar for possible changes in the Final exam schedule.


(subject to change): The final grade is weighted as follows:

  • Midterms: 40%
  • Final Presentation and Term Paper: 40%
  • Homework: 20%

Some of the topics covered in this course may vary depending on the overall students' interests and requests.

  • Review of laser principles (1-2 lectures)
  • Semiconductor Lasers (11 lectures)
  • Review of band-theory
  • k.p theory and effective mass approximation
  • Derivation of optical transitions and gain in semiconductors
  • Optical propagation in dielectric waveguides
  • Heterojunction lasers
  • Quantum-confined structures, multiple quantum well (MQW) lasers
  • Vertical cavity surface emitting lasers (VCSEL)
  • Optically Pumped Semiconductors Lasers
  • Quantum-cascade lasers
  • Optical Detectors and Detection Techniques (3 lectures)
  • Statistical Optics (2 lectures)
  • Topics in Ultrafast Phenomena (Femtosecond Metrology, Extreme Nonlinear Optics & Atto-Science) (5-6 lectures)
  • Terahertz radiation (T-rays) and applications (2-3 lectures)

Other topics may include:

  • NanoOptics, Plasmonics
  • Unstable resonators and applications
  • Maxwell-Bloch equations, coherent transient effects

Class handout


Physics and Properties of Semiconductor Devices