Semiconductor Engineering, MS (Boston)

The Master of Science in Semiconductor Engineering, offered by the Institute for NanoSystems Innovation—along with the Department of Electrical and Computer Engineering, the Department of Mechanical and Industrial Engineering, and the Department of Chemical Engineering in the College of Engineering—and the D’Amore-McKim School of Business, is designed to meet the burgeoning demand for skilled professionals in the semiconductor industry. This cutting-edge program aims to equip students with the knowledge and skills necessary to excel in this rapidly evolving field.

The national landscape is witnessing a significant uptick in interest in expanding the talent pool within the semiconductor sector, particularly following the enactment of the U.S. CHIPS and Science Act of 2022. This pivotal legislation has catalyzed a marked increase in the demand for engineers, drawing considerable attention from a wide array of companies to the semiconductor industry. There is a need for skilled workers to build new plants to increase and localize manufacturing capacity, design chips, and the tools that make the chips. This program is strategically positioned to address this growing need, offering a comprehensive educational experience that prepares our graduates to lead and innovate in this critical domain.

Complete all courses and requirements listed below unless otherwise indicated.

Core Requirements

Course List

Code	Title	Hours
Analog/Digital Circuits and Nanosystems
Complete one of the following:		4
EECE 5649	Design of Analog Integrated Circuits with Complementary Metal-Oxide-Semiconductor Technology
EECE 7240 and EECE 7248	Analog Integrated Circuit Design and Lab for EECE 7240
EECE 7244	Introduction to Microelectromechanical Systems (MEMS)
or ME 6260	Introduction to Microelectromechanical Systems (MEMS)
EECE 7353	VLSI Design
Materials, Devices, and Manufacturing
Complete one of the following:		4
EECE 5161	Thin Film Technologies
EECE 5606	Micro- and Nanofabrication
EECE 7201	Solid State Devices
MATL 7365	Properties and Processing of Electronic Materials
ME 5630	Nano- and Microscale Manufacturing
Innovation
Complete four semester hours from the following. Students may not meet this requirement solely with directed study coursework:		4
CHME 5976	Directed Study
EECE 6400	Special Problems in Electrical and Computer Engineering
GE 5010	Customer-Driven Technical Innovation for Engineers
GE 5100	Product Development for Engineers
INNO 6200	Enterprise Growth and Innovation
ME 5976	Directed Study

Concentrations

Complete one of the following concentrations:

• Devices and NanoSystems
• Materials and Manufacturing 

Optional Co-op Experience

Course List

Code	Title	Hours
Complete the following. Students must complete ENCP 6100 to qualify for co-op experience:
ENCP 6100	Introduction to Cooperative Education	1
ENCP 6964	Co-op Work Experience	0
or ENCP 6954	Co-op Work Experience - Half-Time
or ENCP 6955	Co-op Work Experience Abroad - Half-Time
or ENCP 6965	Co-op Work Experience Abroad

Program Credit/GPA Requirements

32 total semester hours required (33 with optional co-op)
Minimum 3.000 GPA required

---

Concentration in Devices and NanoSystems

Course List

Code	Title	Hours
Complete two of the following not used to complete other requirements of this program:		8
EECE 5161	Thin Film Technologies
EECE 5606	Micro- and Nanofabrication
EECE 5649	Design of Analog Integrated Circuits with Complementary Metal-Oxide-Semiconductor Technology
EECE 5651	Introduction to Photonic Devices
EECE 7201	Solid State Devices
EECE 7240 and EECE 7248	Analog Integrated Circuit Design and Lab for EECE 7240
EECE 7244	Introduction to Microelectromechanical Systems (MEMS)
or ME 6260	Introduction to Microelectromechanical Systems (MEMS)
EECE 7250	Power Management Integrated Circuits
EECE 7352	Computer Architecture
EECE 7353	VLSI Design
MATL 7365	Properties and Processing of Electronic Materials
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
EECE 7945	Master’s Project
Complete 8 semester hours from the restricted electives course list.
Thesis Option
EECE 7945	Master’s Project
EECE 7990	Thesis
Complete 4 semester hours from the restricted electives course list.

Concentration in Materials and Manufacturing

Course List

Code	Title	Hours
Complete two of the following not used to complete other requirements of this program:		8
CHME 5105	Materials Characterization Techniques
EECE 5161	Thin Film Technologies
EECE 7244	Introduction to Microelectromechanical Systems (MEMS)
IE 6200	Engineering Probability and Statistics
IE 7270	Intelligent Manufacturing
MATL 7365	Properties and Processing of Electronic Materials
ME 5245	Mechatronic Systems
ME 5620	Fundamentals of Advanced Materials
ME 5630	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
ME 7945	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
ME 7945	Master’s Project
or CHME 7945	Master's Project
or IE 7945	Master’s Project
ME 7990	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.

Course List

Code	Title	Hours
Elective Courses in Engineering and Science
CHME 5105	Materials Characterization Techniques
CHME 5510	Fundamentals in Process Safety Engineering
CHME 5621	Electrochemical Engineering
CHME 5642 and CHME 5643	Photochemistry Fundamentals and Applications and Photochemistry Lab
CHME 5683	Introduction to Polymer Science
CHME 5699	Special Topics in Chemical Engineering (BioMEM Systems)
CHME 5699	Special Topics in Chemical Engineering (Carbon Capture Storage and Utilization)
CHME 7340	Chemical Engineering Kinetics
EECE 5606	Micro- and Nanofabrication
EECE 5608	Magnetic Materials for Next-Generation Electronics
EECE 5612	Statistical Inference: An Introduction for Engineers and Data Analysts
EECE 5644	Introduction to Machine Learning and Pattern Recognition
EECE 5647	Nanophotonics
EECE 5649	Design of Analog Integrated Circuits with Complementary Metal-Oxide-Semiconductor Technology
EECE 5651	Introduction to Photonic Devices
EECE 5652	Microwave Circuits and Systems
EECE 5698	Special Topics in Electrical and Computer Engineering (Biomedical Microsystems)
EECE 5698	Special Topics in Electrical and Computer Engineering (Introduction to Quantum Engineering)
EECE 5698	Special Topics in Electrical and Computer Engineering (Tapeout a CMOS Chip)
EECE 5698	Special Topics in Electrical and Computer Engineering (Test and Validate a CMOS Chip)
EECE 5698	Special Topics in Electrical and Computer Engineering (Silicon Photonics)
EECE 5698	Special Topics in Electrical and Computer Engineering (Semiconductor Packaging)
EECE 5698	Special Topics in Electrical and Computer Engineering (Superconducting Quantum Devices)
EECE 7201	Solid State Devices
EECE 7240 and EECE 7248	Analog Integrated Circuit Design and Lab for EECE 7240
EECE 7244	Introduction to Microelectromechanical Systems (MEMS)
or ME 6260	Introduction to Microelectromechanical Systems (MEMS)
EECE 7245	Microwave Circuit Design for Wireless Communication
EECE 7247	Radio Frequency Integrated Circuit Design
EECE 7250	Power Management Integrated Circuits
EECE 7296	Electronic Materials
EECE 7352	Computer Architecture
EECE 7353	VLSI Design
EECE 7368	High-Level Design of Hardware-Software Systems
EECE 7390	Computer Hardware Security
EECE 7398	Advanced Special Topics in Electrical and Computer Engineering (Advanced Radio Frequency Passive Tech)
EECE 7398	Advanced Special Topics in Electrical and Computer Engineering (Low Power Integrated Circuits Design)
IE 5617	Lean Concepts and Applications
IE 5137	Computational Modeling in Industrial Engineering
IE 6200	Engineering Probability and Statistics
IE 6300	Manufacturing Systems Design
IE 6700	Data Management for Analytics
IE 7200	Supply Chain Engineering
IE 7270	Intelligent Manufacturing
IE 7280	Statistical Methods in Engineering
IE 7285	Statistical Quality Control
IE 7290	Reliability Analysis and Risk Assessment
MATL 6250	Soft Matter
MATL 7365	Properties and Processing of Electronic Materials
ME 5240	Computer Aided Design and Manufacturing
ME 5245	Mechatronic Systems
ME 5250	Robot Mechanics and Control
ME 5520	Fundamentals and Applications of Optics and Photonics
ME 5600	Materials Processing and Process Selection
ME 5620	Fundamentals of Advanced Materials
ME 5630	Nano- and Microscale Manufacturing
ME 5640	Additive Manufacturing
PHYS 5114	Physics and Applications of Quantum Materials
PHYS 5125	Advanced Quantum Mechanics
PHYS 5260	Introduction to Nanoscience and Nanotechnology
PHYS 5318	Principles of Experimental Physics
PHYS 5352	Quantum Computation and Information
Elective Courses in Innovation
A maximum of 4 semester hours may be taken from the following:
FINA 6309	Foundations of Accounting and Finance
GE 5010	Customer-Driven Technical Innovation for Engineers
GE 5020	Engineering Product Design Methodology
GE 5030	Iterative Product Prototyping for Engineers
GE 5100	Product Development for Engineers
INNO 6200	Enterprise Growth and Innovation
MKTG 6200	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:
BUSN 6379	Entrepreneurial Ecosystems
BUSN 6389	Leading Global Virtual Innovation Teams
CHME 5976	Directed Study
ME 5976	Directed Study