Expand mobile version menu
  Skip to main content

Metallurgical Engineering

Program Description

Just the Facts

Metallurgical Engineering. A program that prepares individuals to apply mathematical and metallurgical principles to the design, development and operational evaluation of metal components of structural, load-bearing, power, transmission, and moving systems; and the analysis of engineering problems such as stress, creep, failure, alloy behavior, environmental fluctuations, stability, electromagnetic and thermodynamic characteristics, optimal manufacturing processes, and related design considerations.

This program is available in these options:

  • Associate degree
  • Bachelor's degree
  • Graduate Certificate
  • Master's degree
  • Doctoral degree

High School Courses

See the high school courses recommended for programs in this career cluster:

See the high school courses recommended for programs in this pathway:


Related Careers

Check out related careers


Additional Information

A degree in metallurgical engineering involves the study, design, implementation and betterment of processes that transform raw materials like ore (rock with metal and minerals) into the various metal and mineral products that we use on a daily basis.

This program has three basic areas: mineral processing extractive metallurgy and physical metallurgy. Mineral processing consists of getting mineral products out of the earth's crust, and then separating them and reducing them in size. Extractive metallurgy involves the removal of metals and minerals from raw material such as ores. Physical metallurgy is the development of metal alloys that manufacturing and construction need for their work.

Steve Cockcroft, a professor of metals and materials engineering, says that his program "has all engineering students taking a common first year, after which they choose which program to enter into."

Courtney Young is head of metallurgical engineering at Montana Tech. She says that over the course of their studies, students can expect to take courses in mineral processing; extractive metallurgy; physical metallurgy and materials engineering; and welding metallurgy.

To be licensed as a professional engineer, you'll need at least a four-year bachelor's degree. Many of these degrees actually take five years if you choose to do a co-op program, which combines work terms with your class terms. Many engineers go on to pursue master's degrees as well.

"Prospective students must enjoy chemistry and math, and [must] have good grades, as well as good scores on ACT or SAT tests," says Young.

"It helps if the prospective student also has taken and done well in physics, but not all high schools offer physics."

She adds that taking AP courses, including English, is also useful.

Those who major in the sciences always have lab expenses in addition to the cost of tuition and textbooks.


Links

Occupational Outlook Handbook
For more information related to this field of study, see: Materials Engineers

Challenge of Materials
A look at materials, including metals

Principal Metals -- Properties
Information on more than 5,000 metals

Contact

  • Email Support

  • 1-800-GO-TO-XAP (1-800-468-6927)
    From outside the U.S., please call +1 (424) 750-3900

Support


Powered by XAP

OCAP believes that financial literacy and understanding the financial aid process are critical aspects of college planning and student success. OCAP staff who work with students, parents, educators and community partners in the areas of personal finance education, state and federal financial aid, and student loan management do not provide financial, investment, legal, and/or tax advice. This website and all information provided is for general educational purposes only, and is not intended to be construed as financial, investment, legal, and/or tax advice.