To be a radiochemist requires a specialized knowledge of radiation and chemistry, of nuclear reactions, decay modes, and the chemical properties of radioactive elements and isotopes. Currently, the need for radiochemists in the United States is urgent.
Radiochemistry is essential for:
- The production of radioisotopes for medical diagnosis and treatment, drug synthesis of radiopharmaceuticals, and development of reagents in nuclear medicine
- environmental chemistry and bioassay for radionuclides, including fission products and actinides, for the detection, measurement, and removal of radioactive materials
- the nuclear fuel cycle, including high-level, nuclear waste processing technology, nuclear waste management, and nuclear reactor facilities
- nuclear forensic science for homeland security related issues, including the detection of forensic signatures, and analysis of indicators and source attribution
- protection against nuclear threat and illicit transportation of radioactive materials, as well as emergency response
If you are a scientist interested in a career in nuclear medicine, homeland security, or environmental protection, apply to Illinois Tech’s brand new radiochemistry track, a specialization of Illinois Tech’s well-established Master of Health Physics program. Our radiochemistry specialization has the added advantage of access to the University of Missouri Research Reactor Center (MURR) where admitted students take a specially designed radiochemistry laboratory course taught by experts.
To earn the Master of Health Physics with Specialization in Radiochemistry degree, students must satisfactorily complete a minimum of 32 credit hours, maintain a minimum grade point average (GPA) of 3.0, and pass a final comprehensive exam. For more information see our FAQ »
Announcing the radiochemistry specialization at the Annual Health Physics Society Meeting in Raleigh, NC, July 2017, are, from left to right: alumnus Patrick Haan (’17), program director SY Chen, and current students Erin Evans and John Edwards.
To be considered for admission, applicants must have completed coursework in calculus and a calculus-based general physics sequence. A course in modern physics, including some basic quantum mechanics, is strongly recommended.
Students are required to hold a bachelor's degree in physics, biology, chemistry, or engineering, with a GPA of at least 3.0/4.0 from an accredited institution of higher education and a minimum GRE score of 304 [quantitative + verbal] and 2.5 [analytical writing]. The GRE requirement may be waived at the director’s discretion.
Course of Study
|PHYS 561||Radiation Biophysics||3|
|PHYS 571||Radiation Physics||3|
|PHYS 573||Standards, Statutes, and Regs.||3|
|PHYS 575||Case Studies in Health Physics||3|
|PHYS 580||Introduction to Radiochemistry||3|
|PHYS 581||Radiochemistry Laboratory||3|
|PHYS 582||Application of Radiochemistry||3|
|PHYS 574||Introduction to Nuclear Fuel Cycle||2|
|CHEM 512||Spectroscopy II Inorganic||2|
|CHEM 509/PHYS 539||Physical Methods of Characterization||3|
|MATH 525||Statistical Models and Methods||3|
|SCI 522||Public Engagement for Scientists||3|
|SCI 511||Project Management||3|
|Total 11 Courses||32|
All of the courses listed above are offered online except for PHYS 550 – Instrumentation and PHYS 581 - Radiochemistry Laboratory. All students in the radiochemistry track are required to complete the instrumentation class before taking the radiochemistry lab component. Each of these two courses is offered in the summertime and consists of one week of intensive, hands-on training. Instrumentation is held on Illinois Tech’s main campus in Chicago while the radiochemistry lab is offered at MURR in Columbia, Missouri.
S.Y. Chen, Ph.D., CHP
Department of Physics
Illinois Institute of Technology
Director, Professional Master's Programs and New Initiatives
Elizabeth Friedman, Ph.D.
College of Science
Illinois Institute of Technology