When will I have access to the lectures and assignments?

To access the course materials, assignments and to earn a Certificate, you will need to purchase the Certificate experience when you enroll in a course. You can try a Free Trial instead, or apply for Financial Aid. The course may offer 'Full Course, No Certificate' instead. This option lets you see all course materials, submit required assessments, and get a final grade. This also means that you will not be able to purchase a Certificate experience.

What will I get if I subscribe to this Specialization?

When you enroll in the course, you get access to all of the courses in the Specialization, and you earn a certificate when you complete the work. Your electronic Certificate will be added to your Accomplishments page - from there, you can print your Certificate or add it to your LinkedIn profile.

Is financial aid available?

Yes. In select learning programs, you can apply for financial aid or a scholarship if you can’t afford the enrollment fee. If fin aid or scholarship is available for your learning program selection, you’ll find a link to apply on the description page.

Nanophotonics and Detectors

4 days left! Save on skills that make you shine with 40% off 3 months of Coursera Plus. Save now

Nanophotonics and Detectors

This course is part of Active Optical Devices Specialization

Instructor: Juliet Gopinath

6,578 already enrolled

Included with

Learn more

6 modules

Gain insight into a topic and learn the fundamentals.

26 reviews

Advanced level

Designed for those already in the industry

Flexible schedule

2 weeks at 10 hours a week

Learn at your own pace

Build toward a degree

Learn more

6 modules

Gain insight into a topic and learn the fundamentals.

26 reviews

Advanced level

Designed for those already in the industry

Flexible schedule

2 weeks at 10 hours a week

Learn at your own pace

Build toward a degree

Learn more

What you'll learn

Use nanophotonic effects (low dimensional structures) to engineer lasers
Apply low dimensional structures to photonic device design
Select and design optical detector for given system and application

Skills you'll gain

Details to know

Shareable certificate

Add to your LinkedIn profile

Assessments

12 assignments

Taught in English

See how employees at top companies are mastering in-demand skills

Learn more about Coursera for Business

logos of Petrobras, TATA, Danone, Capgemini, P&G and L'Oreal

Build your subject-matter expertise

This course is part of the Active Optical Devices Specialization

When you enroll in this course, you'll also be enrolled in this Specialization.

Learn new concepts from industry experts
Gain a foundational understanding of a subject or tool
Develop job-relevant skills with hands-on projects
Earn a shareable career certificate

There are 6 modules in this course

This course can also be taken for academic credit as ECEA 5606, part of CU Boulder’s Master of Science in Electrical Engineering degree.

Nanophotonics and Detectors Introduction This course dives into nanophotonic light emitting devices and optical detectors, including metal semiconductors, metal semiconductor insulators, and pn junctions. We will also cover photoconductors, avalanche photodiodes, and photomultiplier tubes. Weekly homework problem sets will challenge you to apply the principles of analysis and design we cover in preparation for real-world problems. Course Learning Outcomes At the end of this course you will be able to… (1) Use nanophotonic effects (low dimensional structures) to engineer lasers (2) Apply low dimensional structures to photonic device design (3) Select and design optical detector for given system and application

Module details

The course covers the basics of nanophotonic light emitting devices and optical detectors, including metal semiconductor, metal semiconductor insulator, and pn junctions, photoconductors, avalanche photodiodes and photomultiplier tubes. Low dimensional structures enable an entirely new class of devices. Join me on a journey to understand how this happens and explore powerful examples of successful technologies such as the quantum cascade laser.Module 1 will cover the quantum cascade laser, a laser design based on intersub-band transitions, that enables very long wavelength lasers. It will also talk about lasers that operate on intraband transitions, using low dimensional structures, which enable further control over carrier concentrations.

What's included

6 videos5 readings2 assignments1 discussion prompt

6 videosTotal 21 minutes

Intro to Nanophotonics and Detectors2 minutes
Intro to Quantum Cascade Lasers and Low-Dimensional Structures1 minute
Intro to Quantum Cascade Lasers7 minutes
Density of States in Low Dimensional Structures3 minutes
Quantum Dots, Part I6 minutes
Quantum Dots, Part II1 minute

5 readingsTotal 31 minutes

Course Updates and Accessibility Support1 minute
Non-Credit Students: Welcome and Where to Find Help10 minutes
References5 minutes
Reference Values and Equations10 minutes
Accessing MATLAB 5 minutes

2 assignmentsTotal 90 minutes

Quantum Cascade Lasers and Low-Dimensional Structures60 minutes
Quantum Cascade Lasers and Low-Dimensional Structures Practice30 minutes

1 discussion promptTotal 10 minutes

Introductions10 minutes

In this unit, we will learn how to confine photons just as we do with electrons. This gives us power over the allowed modes of emission, allowing us to enhance the performance of lasers as well as develop 'threshold-less' lasers. I hope you enjoy this exciting topic as much as I do.

What's included

8 videos2 readings2 assignments

8 videosTotal 31 minutes

Confined Photons2 minutes
Photon Confinement5 minutes
Photon Density of States, Part I5 minutes
Photon Density of States, Part II2 minutes
Spontaneous Emission Enhancement4 minutes
Micropillar Laser4 minutes
Whispering Gallery Mode4 minutes
Photonic Crystals5 minutes

2 readingsTotal 15 minutes

References5 minutes
Reference Values and Equations10 minutes

2 assignmentsTotal 60 minutes

Confined Photons30 minutes
Confined Photons Practice30 minutes

In this module, you will learn about the basics of detection and the key performance metrics that are used to evaluate detectors including noise equivalent power and detectivity. This lays the building blocks for fundamental understanding, design, and use of different photonic detection technology. This is core information that should be in the wheelhouse of any photonics researcher or engineer.

What's included

5 videos2 readings2 assignments

In this unit, you will learn about the fundamentals of how metal insulator semiconductor devices operate, their advantages and challenges they face. This information is particularly useful for understanding the operation of charge-coupled devices, discussed in the next section.

What's included

10 videos2 readings2 assignments

10 videosTotal 57 minutes

Introduction to Metal Insulator Semiconductor Structures1 minute
Metal Semiconductor Junction8 minutes
Metal Semiconductor Junction Under Bias5 minutes
Schottky Diode8 minutes
Metal Insulator Semiconductor Devices4 minutes
Surface States in Metal Insulator Semiconductor Devices12 minutes
MIS Operation vs. Bias4 minutes
MIS Devices5 minutes
Calculation of Charge Storage Time5 minutes
Dark Current5 minutes

2 readingsTotal 15 minutes

References5 minutes
Reference Values and Equations10 minutes

2 assignmentsTotal 150 minutes

Metal Insulator Semiconductor Structures90 minutes
Metal Insulator Semiconductor Structures Practice60 minutes

In this module, you will learn about two powerful detection technologies: charge coupled devices (CCDs) based on metal insulator semiconductor structures and photoconductors. These technologies are very useful for photonic systems.

What's included

5 videos2 readings2 assignments

5 videosTotal 29 minutes

Introduction to CCDs and Photoconductors1 minute
Charge Coupled Devices8 minutes
Photoconductors, Part I12 minutes
Photoconductors, Part II4 minutes
Metal Semiconductor, Metal Photoconductor4 minutes

2 readingsTotal 15 minutes

References5 minutes
Reference Values and Equations10 minutes

2 assignmentsTotal 90 minutes

Charge Coupled Devices (CCDs) and Photoconductors60 minutes
Charge Coupled Devices (CCDs) and Photoconductors Practice30 minutes

In this module, you will learn about another very important detector technology: p-n junctions. These junctions can be used to be photodiodes as well as avalanche photodiodes. We will learn these important technologies function, with applications ranging from microscopy to light detection and ranging (LIDAR).

What's included

12 videos2 readings2 assignments

12 videosTotal 68 minutes

Introduction to P/N Junctions and Avalanche Photodiodes1 minute
Photodiode5 minutes
Avalanche Photodiode4 minutes
Lucky Electron Theory, Part I7 minutes
Lucky Electron Theory, Part II5 minutes
Diffusion Theory7 minutes
New Theory of Impact Ionization2 minutes
Current Response of Avalanche Photodiode, Part I12 minutes
Current Response of Avalanche Photodiode, Part II3 minutes
Excess Noise Factor3 minutes
Superlattice APD, Part I7 minutes
Superlattice APD, Part II11 minutes

2 readingsTotal 15 minutes

References5 minutes
Reference Values and Equations10 minutes

2 assignmentsTotal 105 minutes

P/N Junctions and Avalanche Photodiodes (APDs)60 minutes
P/N Junctions and Avalanche Photodiodes (APDs) Practice45 minutes

Earn a career certificate

Add this credential to your LinkedIn profile, resume, or CV. Share it on social media and in your performance review.

Build toward a degree

This course is part of the following degree program(s) offered by University of Colorado Boulder. If you are admitted and enroll, your completed coursework may count toward your degree learning and your progress can transfer with you.¹