Advanced Microelectronics Fabrication Graduate Academic Certificate
All required coursework must be completed with a grade of B or better (O-10-b).
| Code | Title | Hours |
|---|---|---|
| ECE 565 | Introduction to Microelectronics Fabrication | 3 |
| Select one of the following: | 3 | |
| Quantum Mechanics for Electrical Engineers | ||
| Solid State Physics | ||
| Select two from the following: 1 | 6-7 | |
| Surfaces and Colloids | ||
| Electrochemistry | ||
| Introduction to Electronic Packaging | ||
| Quantum Mechanics for Electrical Engineers | ||
| Principles of Electron Microscopy | ||
| Corrosion | ||
| Fundamentals of Thin Film Fabrication | ||
| Finite Element Applications | ||
| Advanced Physics Lab | ||
| Optics | ||
| Solid State Physics | ||
| Introduction to SAS/R Programming | ||
| SAS Programming | ||
| R Programming | ||
| Statistical Analysis | ||
| Total Hours | 12-13 | |
- 1
Courses chosen must be different from the core courses. At least one course must be 500-level.
Courses to total 12 credits for this certificate
1. An ability to identify, formulate, and solve advanced microelectronics fabrication problems by applying principles of engineering, science, and mathematics.
2. An ability to communicate effectively on topics related to advanced microelectronics fabrication concepts and technologies with a range of audience.
3. An ability to develop and conduct appropriate advanced microelectronic fabrication experimentation, analyze and interpret data, and use engineering judgment to draw conclusions about microelectronics fabrication.
Overall, these learning outcomes demonstrate that students who have completed a certificate in advanced microelectronics fabrication have acquired the knowledge, skills, and abilities necessary to succeed in various fields of the advanced microelectronics fabrication industry. The students are well-prepared to pursue further education or employment in the advanced microelectronics fabrication field.