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1-1 Lecture 1: RDCH 702 Introduction Class organization §Outcomes §Grading Chart of the nuclides §Description and use of chart §Data Radiochemistry introduction.

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Presentation on theme: "1-1 Lecture 1: RDCH 702 Introduction Class organization §Outcomes §Grading Chart of the nuclides §Description and use of chart §Data Radiochemistry introduction."— Presentation transcript:

1 1-1 Lecture 1: RDCH 702 Introduction Class organization §Outcomes §Grading Chart of the nuclides §Description and use of chart §Data Radiochemistry introduction §Atomic properties §Nuclear nomenclature §X-rays §Types of decays §Forces

2 1-2 RDCH 702: Introduction Outcomes for RDCH 702 §Understand chemical properties in radiation and radiochemistry §Use and application of chemical kinetics and thermodynamics to evaluate radionuclide speciation §Understand the influence of radiolysis on the chemistry of radioisotopes §Understand and evaluate radioisotope production §Evaluate and compare radiochemical separations §Utilization of radioisotope nuclear properties in evaluating chemical behavior §Use and explain the application of radionuclides in research §Discuss and understand ongoing radiochemistry research

3 1-3 Grading Homework (5 %) §In class quiz at completion of topic Quizzes (12.5 % each) §Take home quiz §Develop tools for research (spreadsheets) Presentation (20 %) §Based on recent literature §End of semester §20-25 minutes Classroom participation (12.5 %) §Bring chart of the nuclides! Class developed to assist and compliment research activities

4 1-4 Schedule #DateTopic 1Monday27-AugIntroduction, Chart of the Nuclides 2Wednesday29-AugChemical Speciation and Thermodynamics 3Monday03-SepLabor Day 4Wednesday05-SepQuiz 1 (Chart of the Nuclides) 5Monday10-SepNo Class (Scifinder) 6Wednesday12-SepNo Class (initial research on presentation) 7Monday17-SepChemical Speciation and Thermodynamics 8Wednesday19-SepNuclear Reactions 9Monday24-SepOrigin of the Elements 10Wednesday 26-Sep Electron orbitals and energy Quiz 2 (Speciation and Thermodynamics) 11Monday01-OctElectron orbitals and energy 12Wednesday03-OctNuclear Models 13Monday08-OctNuclear Models, Decay Kinetics 14Wednesday10-OctDecay Kinetics 15Monday15-OctDecay Kinetics 16Wednesday17-OctQuiz 3 (Electron Orbitals and Decay Kinetics) 17Monday22-OctDosimetry and Interaction of Radiation with Matter 18Wednesday24-OctDosimetry and Interaction of Radiation with Matter 19Monday29-OctIsotope production 20Wednesday31-OctIsotope production 21Monday05-NovQuiz 4 (Dosimetry, Radiation Interaction, Isotope Production) 22Wednesday07-NovSolvent Extraction 23Monday12-NovNo Class 24Wednesday14-NovIon Exchange 25Monday19-NovIon Exchange 26Wednesday21-NovMolten Salt 27Monday26-NovIn Reactor Chemistry 28Wednesday28-NovReactors and Fuel Cycle 29Monday03-DecReactors and Fuel Cycle 30Wednesday05-DecQuiz 5 (Separations, Fuel Cycle) 31Monday10-DecPresentations (1010-1210)

5 1-5 1.  decay (occurs among the heavier elements) 2.  decay 3. Positron emission 4. Electron capture 5. Spontaneous fission Types of Decay

6 1-6 Fission Products Fission yield curve varies with fissile isotope 2 peak areas for U and Pu thermal neutron induced fission Variation in light fragment peak Influence of neutron energy observed 235 U fission yield

7 1-7 Photon emission Gamma decay §Emission of photon from excited nucleus àMetastable nuclide (i.e., 99m Tc) àFollowing decay to excited daughter state X-ray §Electron from a lower level is removed àelectrons from higher levels occupy resulting vacancy with photon emission §De-acceleration of high energy electrons §Electron transitions from inner orbitals §X-ray production àBombardment of metal with high energy electrons àSecondary x-ray fluorescence by primary x-rays àRadioactive sources àSynchrotron sources

8 1-8 X-rays Removal of K shell electrons §Electrons coming from the higher levels will emit photons while falling to this K shell  series of rays (frequency or wavelength ) are noted as K , K , K   If the removed electrons are from the L shell, noted as L , L , L  In 1913 Moseley studied these frequencies, showing that: where Z is the atomic number and, A and Z 0 are constants depending on the observed transition. K series, Z 0 = 1, L series, Z 0 = 7.4.

9 1-9 Chart of the Nuclides Presentation of data on nuclides §Information on chemical element §Nuclide information àSpin and parity (0 + for even-even nuclides) àFission yield §Stable isotope àIsotopic abundance àReaction cross sections àMass Radioactive isotope §Half-life §Modes of decay and energies §Beta disintegration energies §Isomeric states §Natural decay series §Reaction cross sections Fission yields for isobars

10 1-10 Chart of Nuclides Decay modes §Alpha §Beta §Positron §Photon §Electron capture §Isomeric transition §Internal conversion §Spontaneous fission §Cluster decay

11 1-11 Chart of the Nuclides Questions How many stable isotopes of Ni? What is the mass and isotopic abundance of 84 Sr? Spin and parity of 201 Hg? Decay modes and decay energies of 212 Bi What are the isotopes in the 235 U decay series? What is the half-life of 176 Lu? What is the half-life of 176 Yb How is 238 Pu produced? How is 239 Pu made from 238 U Which actinide isotopes are likely to undergo neutron induced fission? Which isotopes are likely to undergo alpha decay?

12 1-12 Table of the Isotopes Detailed information about each isotope §Mass chain decay scheme §mass excess (M-A) àMass difference, units in energy (MeV) § particle separation energy §Populating reactions and decay modes §Gamma data àTransitions, % intensities §Decay levels àEnergy, spin, parity, half-life §Structure drawing

13 1-13

14 1-14 Radiochemistry Introduction Radiochemistry §Chemistry of the radioactive isotopes and elements §Utilization of nuclear properties in evaluating and understanding chemistry §Intersection of chart of the nuclides and periodic table Atom §Z and N in nucleus (10 -14 m) §Electron interaction with nucleus basis of chemical properties (10 -10 m) àElectrons can be excited *Higher energy orbitals *Ionization ØBinding energy of electron effects ionization §Isotopes àSame Z different N §Isobar àSame A (sum of Z and N) §Isotone àSame N, different Z §Isomer àNuclide in excited state à 99m Tc

15 1-15 Terms and decay modes: Utilization of chart of the nuclides Identify the isomer, isobars, isotones, and isotopes § 60m Co, 57 Co, 97 Nb, 58 Co, 57 Ni, 57 Fe, 59 Ni, 99m Tc Identify the daughter from the decay of the following isotopes § 210 Po (alpha decay, 206 Pb) § 196 Pb § 204 Bi (EC decay, 204 Pb) § 209 Pb § 222 At § 212 Bi (both alpha and beta decay) § 208 Pb (stable) How is 14 C naturally produced §Reactions with atmosphere ( 14 N as target) Identify 5 naturally occurring radionuclides with Z<84

16 1-16 Half Lives N/N o =e - t N=N o e - t =(ln 2)/t 1/2 is decay constant N o =number at time zero (atoms, mass, moles) N= number at time t Rate of decay of 131 I as a function of time.

17 1-17 Equation questions Calculate decay constant for the following § 75 Se example    ln(2)/119.78 day = 0.00579 d -1  = 0.00579 d -1 *1d/24 hr * 1 hr/3600 s =6.7E-8 s -1 Isotopet 1/2  (s -1 ) 75 Se119.78 days5.79E-3 d -1 6.78E-8 74m Ga10 seconds6.93E-2 s -1 6.93E-2 81 Zn0.32 seconds2.17 s -1 2.17 137 Cs30.07 years2.31E-2 a -1 7.30E-10 239 Pu2.41E4 years2.88E-5 a -1 9.11E-13

18 1-18 Equation Questions What percentage of 66 As remains from a given amount after 0.5 seconds  Use N/N o =e - t  t 1/2 = 95.6 ms; =7.25 s -1  N/N o =e - t = N=/N o =e -7.25(.5) = 0.0266 =2.66 % *After 5.23 half lives How long would it take to decay 90 % of 65 Zn?  Use N/N o =e - t §90 % decay means 10 % remains  Set N/N o =0.1, t 1/2 = 244 d, = 2.84E-3 d -1  0.1=e -2.84E-3t  ln(0.1)= -2.84E-3 d -1 t à=-2.30/-2.84E-3 d-1 = t =810 days

19 1-19 Equation Questions If you have 1 g of 72 Se initially, how much remains in 12 days?  t 1/2 = 8.5 d, =8.15E-2 d -1  N=N o e - t  N=(1 g) e - 8.15E-2(12) §N=0.376 g What if you started with 10000 atoms of 72 Se, how many atoms after 12 days? §0.376 (37.6 %) remains §10000(0.376) = 3760 atoms

20 1-20 What holds the nucleus together: Forces in nature Four fundamental forces in nature Gravity §Weakest force §interacting massive objects Weak interaction §Beta decay Electromagnetic force §Most observable interactions Strong interaction §Nuclear properties

21 1-21 Particle Physics: Boundary of Course fundamental particles of nature and interaction symmetries Particles classified as fermions or bosons §Fermions obey the Pauli principle àantisymmetric wave functions àhalf-integer spins *Neutrons, protons and electrons àBosons do not obey Pauli principle *symmetric wave functions and integer spins ØPhotons

22 1-22 Standard Model Boson are force carriers §Photon, W and Z bosons, gluon §Integer spin

23 1-23 Topic review Types of radioactive decay Understand and utilize the data presented in the chart of the nuclides §Units for data §Relationships between isotopes §Fission yields Identify common fission products Define X-rays Read introduction to chart of the nuclides

24 1-24 Study Questions What are the course outcomes? What are 3 isotones of 137 Cs What are the different types of radioactive decay? Provide 5 radioelements Why is Tc naturally radioactive What are the stable isotopes of Sn? What is the beta decay energy of 90 Sr? Which has more stable isotopes, Cr or Fe?

25 1-25 Pop Quiz Provide 10 facts about 129 I using the chart of the nuclides

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