- Concentrations and course offerings may vary by campus and/or by program modality. Please consult with your advisor or admissions coach for the course availability each term at your campus or within your program modality.
- Certain options within the program may be required at certain campuses or for certain program modalities. Please consult with your advisor or admissions coach for requirements at your campus or for your program modality.
Complete all courses and requirements listed below unless otherwise indicated.
Core Requirements
Code | Title | Hours |
---|---|---|
NanoSystems | ||
Complete one of the following: | 4 | |
Solid State Devices | ||
Analog Integrated Circuit Design and Lab for EECE 7240 | ||
Introduction to Microelectromechanical Systems (MEMS) | ||
or ME 6260 | Introduction to Microelectromechanical Systems (MEMS) | |
Manufacturing | ||
Complete one of the following: | 4 | |
Micro- and Nanofabrication | ||
Properties and Processing of Electronic Materials | ||
Nano- and Microscale Manufacturing | ||
Innovation | ||
Complete four semester hours from the following. Students may not meet this requirement solely with directed study coursework: | 4 | |
Entrepreneurial Ecosystems | ||
Leading Global Virtual Innovation Teams | ||
Directed Study | ||
Customer-Driven Technical Innovation for Engineers | ||
Product Development for Engineers | ||
Enterprise Growth and Innovation | ||
Directed Study |
Concentrations
Complete one of the following concentrations:
Program Credit/GPA Requirements
32 total semester hours required
Minimum 3.000 GPA required
Devices and NanoSystems
Code | Title | Hours |
---|---|---|
Complete two of the following not used to complete other requirements of this program: | 8 | |
Micro- and Nanofabrication | ||
Introduction to Photonic Devices | ||
Solid State Devices | ||
Analog Integrated Circuit Design and Lab for EECE 7240 | ||
Introduction to Microelectromechanical Systems (MEMS) | ||
or ME 6260 | Introduction to Microelectromechanical Systems (MEMS) | |
Power Management Integrated Circuits | ||
VLSI Design | ||
Complete one of the following options for 12 semester hours: | 12 | |
Coursework Option | ||
Complete 12 semester hours from the restricted electives course list. | ||
Project Option | ||
Master’s Project | ||
Complete 8 semester hours from the restricted electives course list. | ||
Thesis Option | ||
Master’s Project | ||
Thesis | ||
Complete 4 semester hours from the restricted electives course list. |
Materials and Manufacturing Concentration
Code | Title | Hours |
---|---|---|
Complete two of the following not used to complete other requirements of this program: | 8 | |
Materials Characterization Techniques | ||
Engineering Probability and Statistics | ||
Intelligent Manufacturing | ||
Properties and Processing of Electronic Materials | ||
Mechatronic Systems | ||
Fundamentals of Advanced Materials | ||
Nano- and Microscale Manufacturing | ||
Complete one of the following options for 12 semester hours: | 12 | |
Coursework Option | ||
Complete 12 semester hours from the restricted electives course list. | ||
Project Option | ||
Master’s Project | ||
or CHME 7945 | Master's Project | |
or IE 7945 | Master’s Project | |
Complete 8 semester hours from the restricted electives course list. | ||
Thesis Option | ||
Master’s Project | ||
or CHME 7945 | Master's Project | |
or IE 7945 | Master’s Project | |
Thesis | ||
or CHME 7990 | Thesis | |
or IE 7990 | Thesis | |
Complete 4 semester hours from the restricted electives course list. |
Restricted Electives Course List
Any course in the following elective lists will fulfill the restricted elective requirement, provided the course has not already been applied to fulfill core requirements of this program and provided the student satisfies prerequisites. Students can take electives outside of these lists with prior approval from the faculty advisor.
Code | Title | Hours |
---|---|---|
Elective Courses in Engineering and Science | ||
Materials Characterization Techniques | ||
Fundamentals in Process Safety Engineering | ||
Electrochemical Engineering | ||
Photochemistry Fundamentals and Applications and Photochemistry Lab | ||
Introduction to Polymer Science | ||
Special Topics in Chemical Engineering (BioMEM Systems) | ||
Special Topics in Chemical Engineering (Carbon Capture Storage and Utilization) | ||
Chemical Engineering Kinetics | ||
Micro- and Nanofabrication | ||
Magnetic Materials for Next-Generation Electronics | ||
Statistical Inference: An Introduction for Engineers and Data Analysts | ||
Introduction to Machine Learning and Pattern Recognition | ||
Nanophotonics | ||
Design of Analog Integrated Circuits with Complementary Metal-Oxide-Semiconductor Technology | ||
Introduction to Photonic Devices | ||
Microwave Circuits and Systems | ||
Special Topics in Electrical and Computer Engineering (Biomedical Microsystems) | ||
Special Topics in Electrical and Computer Engineering (Introduction to Quantum Engineering) | ||
Solid State Devices | ||
Analog Integrated Circuit Design and Lab for EECE 7240 | ||
Integrated Circuits for Mixed Signals and Data Communication | ||
Introduction to Microelectromechanical Systems (MEMS) | ||
or ME 6260 | Introduction to Microelectromechanical Systems (MEMS) | |
Microwave Circuit Design for Wireless Communication | ||
Radio Frequency Integrated Circuit Design | ||
Power Management Integrated Circuits | ||
Electronic Materials | ||
VLSI Design | ||
High-Level Design of Hardware-Software Systems | ||
Advanced Special Topics in Electrical and Computer Engineering (Advanced Radio Frequency Passive Tech) | ||
Advanced Special Topics in Electrical and Computer Engineering (Low Power Integrated Circuits Design) | ||
Lean Concepts and Applications | ||
Computational Modeling in Industrial Engineering | ||
Engineering Probability and Statistics | ||
Manufacturing Methods and Processes | ||
Data Management for Analytics | ||
Supply Chain Engineering | ||
Intelligent Manufacturing | ||
Statistical Methods in Engineering | ||
Statistical Quality Control | ||
Reliability Analysis and Risk Assessment | ||
Soft Matter | ||
Fundamentals of Nanostructured Materials | ||
Properties and Processing of Electronic Materials | ||
Computer Aided Design and Manufacturing | ||
Mechatronic Systems | ||
Robot Mechanics and Control | ||
Fundamentals and Applications of Optics and Photonics | ||
Materials Processing and Process Selection | ||
Fundamentals of Advanced Materials | ||
Nano- and Microscale Manufacturing | ||
Additive Manufacturing | ||
Environmental Issues in Manufacturing and Product Use | ||
Physics and Applications of Quantum Materials | ||
Advanced Quantum Mechanics | ||
Introduction to Nanoscience and Nanotechnology | ||
Principles of Experimental Physics | ||
Quantum Computation and Information | ||
Elective Courses in Innovation | ||
A maximum of 4 semester hours may be taken from the following: | ||
Foundations of Accounting and Finance | ||
Customer-Driven Technical Innovation for Engineers | ||
Engineering Product Design Methodology | ||
Iterative Product Prototyping for Engineers | ||
Product Development for Engineers | ||
Managing People and Organizations | ||
Leading a Diverse and Inclusive Organization | ||
The Human Side of Innovation | ||
Enterprise Growth and Innovation | ||
Managing Ethics in the Workplace and Marketplace | ||
Sustainability and Leadership | ||
Sustainability and the Business Environment | ||
Creating and Sustaining Customer Markets | ||
FINA, HRMG, INNO, MGMT, and MKTG courses listed above are 3 semester hours, so students may take one additional 1 semester hour of courses from the list below for a total of 4 semester hours: | ||
Entrepreneurial Ecosystems | ||
Leading Global Virtual Innovation Teams | ||
Directed Study | ||
Directed Study |