NE300 |
FUNDAMENTALS OF NUCLEAR ENGR |
2022 |
1 |
Physics and Nuclear Engineering |
3.0
(BS=0.0,
ET=3.0,
MA=0.0)
|
This course provides the student with an understanding of the fundamental physical principles involved in radioactive decay, radiation interaction with matter, nuclear fission, and nuclear fuel material properties. The course covers neutron interactions with matter, fission, neutron lifecycle, neutron moderation, and reactor criticality. This course is essential for the nuclear engineer and is an excellent choice for the applied scientist. |
30 @ 75 min (2.000 Att/wk) |
0 @ 0 min |
|
None
|
NE300 |
FUNDAMENTALS OF NUCLEAR ENGR |
2019 |
2 |
Physics and Nuclear Engineering |
3.0
(BS=0.0,
ET=3.0,
MA=0.0)
|
This course provides the student with an understanding of the fundamental physical principles involved in radioactive decay, radiation interaction with matter, nuclear fission and the nuclear fuel cycle. The course covers neutron interactions with matter, fission, neutron diffusion, neutron moderation, and reactor criticality. This course is essential for the nuclear engineer and is an excellent choice for the applied scientist. |
30 @ 75 min (2.000 Att/wk) |
0 @ 0 min |
|
One research paper is included. |
NE300 |
FUNDAMENTALS OF NUCLEAR ENGR |
2014 |
1 |
Physics and Nuclear Engineering |
3.0
(BS=0.0,
ET=3.0,
MA=0.0)
|
This course provides the student with an understanding of the fundamental physical principles involved in radioactive decay, radiation interaction with matter, nuclear fission and the nuclear fuel cycle. The course covers neutron interactions with matter, fission, neutron diffusion, neutron moderation, and reactor criticality. This course is essential for the nuclear engineer and is an excellent choice for the applied scientist. |
40 @ 55 min (2.500 Att/wk) |
0 @ 0 min |
|
One research paper is included. |
NE300 |
FUNDAMENTALS OF NUCLEAR ENGR |
2012 |
1 |
Physics and Nuclear Engineering |
3.0
(BS=0.0,
ET=3.0,
MA=0.0)
|
This course provides the student with an understanding of the fundamental physical principles involved in radioactive decay, radiation interaction with matter, nuclear fission and the nuclear fuel cycle. The course covers neutron interactions with matter, fission, neutron diffusion, neutron moderation, and reactor criticality. This course is essential for the nuclear engineer and is an excellent choice for the applied scientist. |
40 @ 55 min (2.500 Att/wk) |
0 @ 0 min |
|
One research paper is included. |
NE300 |
NUCLEAR REACTOR ANALYSIS |
2008 |
1 |
Physics and Nuclear Engineering |
3.0
(BS=0.0,
ET=3.0,
MA=0.0)
|
This course provides the student with an understanding of the fundamental physical principles involved in nuclear fission and the operation of nuclear reactors. Starting with a brief study of relevant topics from modern physics, the course covers neutron interactions with matter, fission, neutron diffusion, neutron moderation, and the criticality of various reactor types. This course is essential for the nuclear engineer and is an excellent choice for the applied scientist. |
40 @ 55 min (2.500 Att/wk) |
0 @ 0 min |
|
One research paper is included. |
NE300 |
NUCLEAR REACTOR ANALYSIS |
2004 |
1 |
Physics and Nuclear Engineering |
3.0
(BS=0.0,
ET=3.0,
MA=0.0)
|
This course provides the student with an understanding of the fundamental physical principles involved in nuclear fission and the operation of nuclear reactors. Starting with a brief study of relevant topics from modern physics, the course covers neutron interactions with matter, fission, neutron diffusion, neutron moderation, and the criticality of various reactor types. This course is essential for the nuclear engineer and is an excellent choice for the applied scientist. |
40 @ 55 min (2.500 Att/wk) |
0 @ 0 min |
|
Two in class laboratory exercises. One design problem is included. Compensatory time is given for this group requirement. |