We may earn an affiliate commission when you visit our partners.

Semiconductor Device Engineer

Save

Semiconductor Device Engineers design, develop, and test semiconductor devices such as transistors, diodes, and integrated circuits (ICs). These devices are used in a wide range of electronic products, including computers, cell phones, and medical equipment.

What does a Semiconductor Device Engineer do?

Semiconductor Device Engineers typically work in research and development (R&D) labs, where they collaborate with other engineers and scientists to develop new semiconductor devices. They may also work in manufacturing facilities, where they oversee the production of semiconductor devices.

What is the day-to-day work of a Semiconductor Device Engineer like?

Semiconductor Device Engineers typically work in offices or laboratories. They may spend time in the lab working with semiconductor materials and devices. They may also spend time in front of a computer, designing and simulating semiconductor devices.

What are the challenges of being a Semiconductor Device Engineer?

Semiconductor Device Engineers face a number of challenges, including:

  • The need to keep up with the latest advances in semiconductor technology
  • The need to design and test semiconductor devices that meet specific requirements
  • The need to work in a clean and controlled environment
Read more

Semiconductor Device Engineers design, develop, and test semiconductor devices such as transistors, diodes, and integrated circuits (ICs). These devices are used in a wide range of electronic products, including computers, cell phones, and medical equipment.

What does a Semiconductor Device Engineer do?

Semiconductor Device Engineers typically work in research and development (R&D) labs, where they collaborate with other engineers and scientists to develop new semiconductor devices. They may also work in manufacturing facilities, where they oversee the production of semiconductor devices.

What is the day-to-day work of a Semiconductor Device Engineer like?

Semiconductor Device Engineers typically work in offices or laboratories. They may spend time in the lab working with semiconductor materials and devices. They may also spend time in front of a computer, designing and simulating semiconductor devices.

What are the challenges of being a Semiconductor Device Engineer?

Semiconductor Device Engineers face a number of challenges, including:

  • The need to keep up with the latest advances in semiconductor technology
  • The need to design and test semiconductor devices that meet specific requirements
  • The need to work in a clean and controlled environment

What are the projects a Semiconductor Device Engineer may take on?

Semiconductor Device Engineers may take on a variety of projects, including:

  • Designing and testing new semiconductor devices
  • Developing new manufacturing processes for semiconductor devices
  • Improving the performance of existing semiconductor devices

What are the personal growth opportunities for a Semiconductor Device Engineer?

Semiconductor Device Engineers can have a number of personal growth opportunities, including:

  • The opportunity to work on challenging and rewarding projects
  • The opportunity to learn about the latest advances in semiconductor technology
  • The opportunity to work with other talented engineers and scientists

What are the personality traits and personal interests of a Semiconductor Device Engineer?

Successful Semiconductor Device Engineers typically have the following personality traits and personal interests:

  • A strong interest in science and technology
  • A strong analytical mind
  • A good work ethic
  • The ability to work independently and as part of a team
  • The ability to communicate effectively

How to become a Semiconductor Device Engineer

To become a Semiconductor Device Engineer, you typically need a bachelor's degree in electrical engineering, materials science, or a related field. Some Semiconductor Device Engineers also have a master's degree or doctorate in semiconductor engineering or a related field.

In addition to formal education, Semiconductor Device Engineers typically need experience working with semiconductor materials and devices. This experience can be gained through internships, research projects, or work experience in a semiconductor manufacturing facility.

What are the job prospects for Semiconductor Device Engineers?

The job outlook for Semiconductor Device Engineers is expected to be good in the coming years. The demand for semiconductor devices is expected to continue to grow, and this growth is expected to create new jobs for Semiconductor Device Engineers.

Can online courses help me become a Semiconductor Device Engineer?

Online courses can be a helpful way to learn about the basics of semiconductor device engineering. However, online courses alone are not enough to become a Semiconductor Device Engineer. You will also need to gain experience working with semiconductor materials and devices.

Additional resources

  • Institute of Electrical and Electronics Engineers (IEEE)
  • American Physical Society (APS)
  • Materials Research Society (MRS)

Share

Help others find this career page by sharing it with your friends and followers:

Salaries for Semiconductor Device Engineer

City
Median
New York
$201,000
San Francisco
$218,000
Seattle
$176,000
See all salaries
City
Median
New York
$201,000
San Francisco
$218,000
Seattle
$176,000
Austin
$155,000
Toronto
$154,000
London
£72,000
Paris
€72,000
Berlin
€73,000
Tel Aviv
₪220,000
Singapore
S$85,000
Beijing
¥568,000
Shanghai
¥261,000
Shenzhen
¥458,000
Bengalaru
₹680,000
Delhi
₹789,000
Bars indicate relevance. All salaries presented are estimates. Completion of this course does not guarantee or imply job placement or career outcomes.

Path to Semiconductor Device Engineer

Take the first step.
We've curated 18 courses to help you on your path to Semiconductor Device Engineer. Use these to develop your skills, build background knowledge, and put what you learn to practice.
Sorted from most relevant to least relevant:

Reading list

We haven't picked any books for this reading list yet.
This classic textbook provides a comprehensive and up-to-date overview of semiconductor device physics and design. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
Provides a comprehensive introduction to the theory and operation of MOS capacitors, covering both the fundamentals and advanced topics.
Provides a comprehensive overview of modern VLSI devices, including MOSFETs and MOS capacitors, with a focus on device physics and fabrication.
This textbook provides a comprehensive and up-to-date overview of solid state electronic devices. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
This textbook provides a comprehensive and up-to-date overview of the physics of semiconductor devices. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
This textbook provides a comprehensive and up-to-date overview of semiconductor optoelectronics. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
This textbook provides a comprehensive and up-to-date overview of the fundamentals of photonics. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
This textbook provides a comprehensive and up-to-date overview of the semiconductor lasers. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
This textbook provides a comprehensive and up-to-date overview of the Oxford solid state basics. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
This textbook provides a comprehensive and up-to-date overview of the principles of electronic materials and devices. It is written in a clear and concise style, and is suitable for graduate students and practicing engineers.
Delves into the physics and operation of metal-oxide semiconductor (MOS) transistors, including MOS capacitors.
Explores advanced topics in MOS device physics, including the behavior and characterization of MOS capacitors.
Discusses the scaling and challenges of MOS transistors in the nanoscale regime, with emphasis on the impact on MOS capacitor behavior.
Focuses specifically on the physics of MOS insulators, providing an in-depth understanding of the materials and processes involved in MOS capacitor fabrication.
Examines the design and optimization of MOSFETs for high-speed applications, with a significant focus on MOS capacitor modeling and characterization.
A comprehensive handbook that covers a wide range of electronic topics, including SPICE simulation.
Save
A book that covers EDA tools for IC implementation, including SPICE simulation.
Our mission

OpenCourser helps millions of learners each year. People visit us to learn workspace skills, ace their exams, and nurture their curiosity.

Our extensive catalog contains over 50,000 courses and twice as many books. Browse by search, by topic, or even by career interests. We'll match you to the right resources quickly.

Find this site helpful? Tell a friend about us.

Affiliate disclosure

We're supported by our community of learners. When you purchase or subscribe to courses and programs or purchase books, we may earn a commission from our partners.

Your purchases help us maintain our catalog and keep our servers humming without ads.

Thank you for supporting OpenCourser.

© 2016 - 2024 OpenCourser