Nuclear engineering is the application of the breakdown of atomic nuclei and/or other sub-atomic physics, based on the principles of nuclear physics. It includes, but is not limited to, the interaction and maintenance of nuclear fission systems and components— specifically, nuclear reactors, nuclear power plants, and/or nuclear weapons. The field may also include the study of nuclear fusion, medical and other applications of (generally ionizing) radiation, nuclear safety, heat/thermodynamics transport, nuclear fuel and/or other related (e.g., waste disposal) technology, nuclear proliferation, and the effect of radioactive waste or radioactivity in the environment.
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The following is the typical coursework included in most U.S. nuclear engineering degree programs.
As with any engineering discipline, college preparation should include mathematics training through the beginnings of calculus, as well as introductory courses in physics and chemistry.
Undergraduate coursework should begin with a good foundation in mechanics and dynamics of particle motion, thermodynamics, introductory computer programming, college level physics and chemistry, and a rigorous training in mathematics through differential equations.
Midway through undergraduate training a nuclear engineer must choose a specialization within their field for further study. Upper level coursework in a nuclear engineering program includes but is not limited to fluid mechanics, reactor physics, quantum mechanics, thermal hydraulics, linear circuits, radiation effects, and neutron transport. Multi-energy neutron transport is taught at most universities offering degrees in nuclear engineering, but typically only at the graduate level.
Specialization in fission includes the study of nuclear reactors, fission systems, and nuclear power plants. Primary instruction deals with neutronics and thermal-hydraulics for nuclear generated electricity. A firm foundation in thermodynamics and fluid mechanics in addition to hydrodynamics is a must.
Specialization in nuclear fusion includes electrodynamics and plasmas. This area is very much research oriented and training often terminates with a graduate level degree.
Specialization in nuclear medicine includes courses dealing with doses and absorption of radiation in bodily tissues. Those who gain competency in this area usually move into the medical field. Many nuclear engineers in this specialization go on to become board licensed medical physicists or go to medical school and become a radiation oncologist. Remaining in academia in a research capacity is also a common choice for graduates.
The US Navy runs a program called Naval Nuclear Power School to train both officers and enlisted sailors for nuclear plant operation. While some officers have undergraduate backgrounds in nuclear engineering, any officers who take the requisite math and science classes are also accepted, whereas most of the enlisted students hold no college degrees at all. Despite this, they are prepared, through a rigorous training program (lasting between 65 weeks for Machinist's Mates and eighteen months for Electronics Technicians and Electrician's Mates), to operate the nuclear and steam plants aboard the navy's submarines and aircraft carriers. This training does not carry a Department of Energy certification, although many sailors choose to work at civilian power plants after their six-year obligations are completed.
Nuclear fission is the disintegration of a fissionable atom's nucleus into two or more different elements nuclei. An approximate number of ~2.4 neutrons are scattered around per fission. There are two types of nuclear fission. 1-Fast Fission 2-Thermal fission
Generally, thermal fission is used in commercial reactors, if we disregard the Fast Breeder Type of Nuclear Reactors.
The United States gets about 20% of its electricity from nuclear power. This is a massive industry and keeping the supply of nuclear engineers plentiful will ensure its stability. Nuclear engineers in this field generally work, directly or indirectly, in the nuclear power industry or for government labs. Current research in industry is directed at producing economical, proliferation resistant reactor designs with passive safety features. Although government labs research the same areas as industry, they also study a myriad of other issues such as: nuclear fuels and nuclear fuel cycles, advanced reactor designs, and nuclear weapon design and maintenance. A principal pipeline for trained personnel for US reactor facilities is the Navy Nuclear Power Program.
Research areas in nuclear fusion and plasma physics include high-temperature, radiation-resistant materials, and plasma dynamics. Internationally, research is currently directed at building a prototype tokamak called ITER. The research at ITER will primarily focus on instabilities and diverter design refinement. Researchers in the USA are also building an inertial confinement experiment called the National Ignition Facility or NIF. NIF will be used to refine neutron transport calculations for the US stockpile stewardship initiative.
An important field is nuclear medicine. From x-ray machines to MRI to PET, among many others, nuclear medicine provides most of modern medicine's diagnostic capability along with providing many treatment options.
Nuclear materials research focuses on two main subject areas, nuclear fuels and irradiation-induced modification of materials. Improvement of nuclear fuels is crucial for obtaining increased efficiency from nuclear reactors. Irradiation effects studies have many purposes, from studying structural changes to reactor components to studying nano-modification of metals and semiconductors using ion-beams or particle accelerators.
Nuclear engineers and radiological scientists are interested in the development of more advanced ionizing radiation measurement and detection systems, and using these to improve imaging technologies. This includes detector design, fabrication and analysis, measurements of fundamental atomic and nuclear parameters, and radiation imaging systems, among other things.
| College | Department (external links) | Degrees offered |
|---|---|---|
| University of Ontario Institute of Technology, Oshawa | Nuclear Engineering | B.Eng, M.Eng |
| McMaster University, Hamilton | Engineering Nuclear Physics | B.Eng.Phys., Dipl.Nuc.Tech, M.Eng, M.A.Sc, Ph.D. |
| Royal Military College of Canada, Kingston | Department of Chemistry and Chemical Engineering | M.Sc, M.A.Sc, M.Eng, PhD |
| College | Department (external links) | Degrees offered |
|---|---|---|
| Lancaster University | Nuclear engineering | M.Eng |
| College | Department (external links) | Degrees offered |
|---|---|---|
| Indian Institute of Technology, Kanpur | Nuclear Engg and Technology | M.Tech,PhD |
| College | Department (external links) | Degrees offered |
|---|---|---|
| Hacettepe University | Department of Nuclear Engineering | BS,MS,PhD |
| College | Department (external links) | Degrees offered |
|---|---|---|
| Pakistan Institute of Engineering and Applied Sciences, Islamabad | Department of Nuclear Engineering | MS,PhD |
| Kannup Institute of Nuclear Power Engineering,Karachi | Department of Nuclear Engineering | MS |
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