Textbooks
Required Textbook
[Yip] = 
Yip, Sidney. Nuclear Radiation Interactions. World Scientific Publishing Co, 2014. ISBN: 9789814368070.
Additional Books
[Saha] = Saha, G. B. Fundamentals of Nuclear Pharmacy. 6th ed. Springer, 2010. ISBN: 9781441958594. [Preview with Google Books]
[Turner] = Turner, J. E. Atoms, Radiation, and Radiation Protection. Wiley-VCH, 2007. ISBN: 9783527406067.
Session Key
L = Lecture
R = Recitation
Q = Quiz or exam
| SES # | TOPICS AND LECTURE NOTES | READINGS |
|---|---|---|
| Part 0: Course Introduction | ||
| L1 | Radiation history to the present |
History of Nuclear Science and Engineering[Yip] pp. 1–19. Chadwick, James. Letter: ———. "The Existence of a Neutron." Proceedings of the Royal Society A 136, no. 830 (1932): 692–708. |
| R1 | Demonstration: Sputter coater plasma | |
| L2 | Radiation-utilizing Technologies (PDF - 3.9MB) |
Background on Nuclear Energetics[Yip] pp. 23–31 and 33–44; skip sections on Nuclear Spin & Electric Quadrupole Moment. |
| L3 | Introduction to Nuclear Energy (PDF - 6.9MB) |
GenIV International Forum / OECD Nuclear Energy Agency. The ITER Tokamak |
| R2 | Demonstration: Tour MIT Alcator C-Mod fusion reactor | |
| Part I: Energetics, Radioactive Decay, Half-life | ||
| L4 | Nuclear Mass and Stability (PDF): Nuclear mass, nuclear structure, binding energy | [Yip] pp. 51–58; read carefully, and try the practice problems. |
| L5 | Nuclear mass and stability (cont.): Nuclear stability, mass parabolas | [Yip] pp. 59–64; read carefully, and try the practice problems. |
| R3 | Deriving the semi-empirical mass formula | |
| L6 | Radioactive Decay (PDF): Alpha, beta, and gamma decay; decay schemes, internal conversion, electron capture | [Saha] pp. 11–18. |
| L7 | Radioactive decay (cont.): Decay energetics, general kinematics and the Q-equation | [Yip] first pp. 141–9; then pp. 103–4 (alpha decay), pp. 112–5 (beta decay) and p. 118 (gamma decay) |
| R4 | 99Tcm, medical imaging, positron annihilation spectroscopy (PAS) | |
| L8 | Radioactive decay (cont.): Activity, exponential decay, half-life |
Units of Radioactivity, Half-lives, Examples[Saha] pp. 18–23. Derivation of Half-life and Decay Constant[Yip] pp. 97–99. |
| L9 | Successive decays, statistics, and precision [no slides] |
Derivation of Successive Decays[Yip] pp. 99–103. Simplified Successive Decay Equations and Examples[Saha] pp. 23–29. |
| R5 | Demonstration: New and old Cesium source measurement | |
| Q1 | Quiz 1: Energetics, radioactive decay, half-life | |
| L10 | Statistics, Precision, Solid Angle (PDF) | [Saha] pp. 27–29. |
| Part II: Radiation Interactions, Shielding, Energy Loss through Matter | ||
| L11 | Radiation interactions: Gamma (photon) scattering and absorption, mass attenuation [no slides] | [Yip] pp. 201–22. |
| L12 | Visit High Purity Germanium (HPGe) detector in the MIT Nuclear Reactor Lab, to measure potassium spectra of banana ashes (for Problem Set 5) | |
| L13 | Radiation interactions: Ion-nuclear [no slides] | [Yip] pp. 223–30. |
| R6 |
Quiz 1 review Myth-busting the Shroud of Turin | |
| L14 | Radiation Interactions: Bremsstrahlung (ion radiation losses) [no slides] | [Yip] pp. 231–9. |
| L15 | Radiation Interactions with Matter [no slides] | [Yip] pp. 184–200, 241–6, and 250–7. |
| R7 | X-ray and proton therapy | |
| L16 | Neutron transport, criticality [no slides] | [Yip] pp. 261–9 and 293–300. |
| L17 |
Radiation Interactions: Neutronics and Neutron Interactions (PDF) Effective shielding and detection [no slides] | [Turner] Chapter 15: External Radiation Protection. |
| R8 | Demonstration: MIT reactor power ramping, control rod insertion | |
| Q2 | Quiz 2: Radiation interactions, shielding, energy loss through matter | |
| Part III: Radiation in Our Environment and Its Effects | ||
| L18 |
 Dose and Dosimetry (PDF - 1.5MB)
| [Turner] Chapter 12: Radiation Dosimetry. |
| L19 |
Background Radiation (PDF - 2.6MB)
|
[Turner] Chapters 4.5: "Natural Radioactivty" and 4.6 "Radon and Radon Daughters." The Origin of Cosmic RaysAckerman, M., et al. "Detection of the Characteristic Pion-Decay Signature in Supernova Remnants." Science 339, no. 6121 (2013): 807–11. |
| R9 | Demonstration: Dosimetry | |
| L20 |
Chemical and Biological Effects of Radiation (PDF - 2.9MB): Short term | [Turner] Chapter 13: Chemical and Biological Effects of Radiation, pp. 399–421. |
| R10 | Chernobyl safety course recap | |
| L21 | Chemical and biological effects of radiation (cont.): Long term | [Turner] Chapter 13: Chemical and Biological Effects of Radiation, pp. 421–41. |
| L22 | Hormesis, linear no-threshold models [no slides] |
ICRP-99 Recommendations on Radiation ProtectionValentin, J., ed. "Low-dose Extrapolation of Radiation-related Cancer Risk." Annals of the International Commission of Radiological Protection 35, no. 4 (2005): 1–141. A Quick Survey of History and Current Knowledge (as of 2003) of Different Models of Radiation ExposurePrekeges, J. L. "Radiation Hormesis, or, Could All That Radiation Be Good for Us?" Journal of Nuclear Medicine Technology 31, no. 1 (2003): 11–17. A Rather Pointed Criticism of the LNT Model.Luckey, T. D. "Radiation Hormesis: The Good, The Bad, and the Ugly." Dose-Response 4, no. 3 (2006): 169–90. |
| R11 |
"Arguing with Greenpeace" debate | |
| L23 | Radiation Hormesis: Real or Not? (PDF) | |
| L24 | Food irradiation [no slides] |
Urbain, W. M. "General Effects of Ionizing Radiation on Foods" and "Wholesomeness of Irradiated Foods." Chapters 5 and 13 in Food Irradiation. Academic Press, 1986, pp. 118–23 and 269–75. ISBN: 9780124315853. |
| R12 |
Irradiated food party Quiz 3 review | |
| Q3 | Quiz 3 | |