1. Dr. Bill Pezzaglia Nuclear & Particle Physics1
AstroPhysics Notes
Dr. Bill Pezzaglia Nuclear & Particle Physics
Updated: 2013Aug29
(for physics 1700)

2. Nuclear Physics A. Nuclear Structure B. Nuclear Decay2
Nuclear Physics
A. Nuclear Structure
B. Nuclear Decay
C. Nuclear Reactions
D. Particle Physics

3. 3
A. Nuclear Structure
Parts of the Atom
Isotopes
Nuclide Table

4. 1. Parts of Atom 4
Electrons (negative charge) orbital diameter approximately m
Nucleus size m
Nucleus made of
Protons (+ charge)
Neutrons (neutral)

5. 1b. The Electron 5
1897 Thomson discovers the electron. Three experiments on “cathode rays”
deflected by magnetic field
Deflected by electric field
Measures e/m
1909 Millikan’s Oil drop experiment determines value of charge “e”

6. 1c. The Proton (1918)
1886 Goldstein discovers “canal rays” which move in opposite direction as “cathode rays”
1918 Rutherford’s experiment demonstrates small size of Hydrogen nucleus, which is 1800x more massive than electron
Rutherford calls it the “proton” (greek word “protos” for “first”)

7. 1d. The Neutron 7
1920 Rutherford proposes neutral particle in nucleus (thought it was a proton combined with electron) to explain nuclear masses (e.g. helium is mass of 4, but only has charge of +2 protons)
1932 Chadwick discovers neutron (Nobel prize!)
Slightly heavier than proton; spin ½ like proton, even though it is neutral, it has a significant magnetic moment!

8. 8
1d. Antimatter
Every particle has an “antiparticle”, which is analogous to the particle moving backwards in time
1927 Paul Dirac predicts “anti-electron”
1931 Anderson finds it (“positron”)
1955 Segre & Chamberlain discover the “antiproton” (at UCB !)
1956 the “anti-neutron” is discovered at UCB !

9. 2. Isotopes 9
Isotopes have same atomic number (number of protons)

10. 2b. Nomenclature 10
Z: Atomic Number Number of Protons Tells what is chemical “X”
N: Neutron Number Number of Neutrons
A: Mass Number Number of Nucleons A=Z+N
Don’t really need “Z”: You know Carbon 14 has 6 protons, because its carbon.

11. 2c. Atomic Mass 11 AMU: Atomic Mass Unit Carbon 12 is exactly 12 amu
Or 1 mole of C12 is 12 grams [1 mole=6.021023 atoms]
Naturally occurring carbon
98.9% C12 ( amu)
1.1% C13 ( amu)
Average:

12. 3. Nuclide Table 12 Isotopes: same Z C12, C13
G. Seaborg 1940
Atomic number is on vertical axis, Neutron number on the horizontal
Isotopes: same Z C12, C13
Isotones: same N C14, N15, O16
Isobars: same A C14, N14, O14

13. Nuclide Table (Small Z)13

14. Nuclide Table (BIG Z) 14 97 96 95 94 93 92 91

15. B. Nuclear Decay Activity Decay Law Modes (Alpha, Beta, Gamma) Dosage15
Activity
Decay Law
Modes (Alpha, Beta, Gamma)
Dosage

16. 1. Radioactivity 16 (a) Phenomena
1898 Term coined by Pierre & Marie Curie (radiation-active)
1896 Becquerel discovers radioactive emissions (“Becquerel Rays”) of uranium salts (using photographic plates)
(b) Units
Activity: decays per second (emissions per second)
new SI unit Bq=becquerels= decays per second
Old Unit: Curie: 1 Ci = 3.7×1010 Bq (activity of 1 gram of radium 226)
(c) Decay Constant
Activity is proportional to number of nuclei present “N”
Activity = N
Decay Constant “” is probability of decay per second.
Antoine Henri Becquerel ( ), 1903 Nobel Prize for discovery of radioactivity

17. 17
2. Decay Law
1902 Rutherford & Soddy realized that all radioactive decays obeyed the same exponential decay law
Half Life: time for half of sample to decay. It is related to decay constant :
This “emination law” showed radioactive decay was not deterministic, but statistical (indeterminant) in nature.

18. 3. Decay Modes 18
Rutherford (1897) clarifies that there are two types of “Becquerel Rays”, alpha (which he identifies as a Helium nucleus), and beta which is 100x more penetrating.
By emitting any of these, the element undergoes “transmutation” into another element.

19. 3. Decay Modes 19

20. 3a. Alpha Decay Example: Most alpha emitters are heavy nuclei20
3a. Alpha Decay
Alpha particle is a Helium Nucleus
Example:
Most alpha emitters are heavy nuclei

21. 21
3b. Beta Decay
Beta particle is actually an electron, identified in 1897 by Thomson.
Beta decay involves a “neutrino” (described by Enrico Fermi in 1930s)
Example: Neutron decays to proton (plus beta and neutrino) with 12 min halflife

22. 22
3b. More Beta Decay
Nuclei with neutron excess will change a neutron into a proton by beta decay, emitting an “anti-neutrino” and beta minus (aka an “electron”)
Example: Carbon 14 decay

23. 23
3b. Inverse Beta Decay
Nuclei with proton excess will change a proton into a neutron by inverse beta decay emitting a neutrino and beta plus (aka positron or anti-electron).
Hydrogen fusion in sun changes 2 protons into neutrons to make helium:

24. 24
3c. Gamma Decay
“Gamma Rays” discovered 1900 by Villard (later identified as high energy photons, which were what Becquerel originally saw)
For example: If a - (electron) combines with its “antimatter” particle, the + (positron), they will annihilate, creating two gamma rays

25. 4 Dosage Dose (energy damage) Dose Equivalent25
Dose (energy damage)
Rad=0.01 Joule/kg
New unit: Gray=1 Joule/kg=100 Rad
Dose Equivalent
Rem=RadRBE
New unit: Sievert:=GrayRBE=100 rem
RBE: Relative Biological Effectiveness
1 for X-ray, Gamma, Beta
10 for Alpha (more damage!)

26. 4b How much is bad? Disasters26
Disasters
2011 Fukushima Daiichi nuclear disaster 1 mSv
1986 Chernobyl: much worse
Hiroshima: 4.5 Gray (1 km from blast)
Exposures:
500 rem 50/50 chance of death
360 mrem average annual dose
30 mrem one X-ray
35 mrem annual dose from inside body

27. 27
C. Nuclear Reactions
Stability
Fission & Fusion
Efficiency

28. 1. Nuclear Stability 28
(a) Binding Energy: the energy required to remove one nucleon from the nucleus
The mass of an atom is LESS than the sum of its parts due to negative potential energy of nuclear force.
Mass Defect: m=(Zmp+Nmn-matom)
Binding Energy: BE=m( MeV/u)

29. 1b. Binding energy per nucleon29
Low Z: more nucleons means more nuclear force, hence more stable
High Z: nuclear force is short range, big nuclei unstable
Iron is most stable nuclei

30. 30
1c. Nuclear Force
Aka “strong force”. This is what holds the protons together in a nucleus
Nucleons attract each other
Force is short range, hence big nuclei are unstable

31. 2b Fusion 31
Combine two (or more) small nuclei to make a bigger, more stable, nuclei
Fusion of 4 Hydrogen to Helium is how sun produces energy
Fusion of 3 Helium to Carbon is how “red giants” create energy
All elements up to iron in the universe were made this way inside of stars (“nucleosynthesis”).

32. 2c Fission 32
Large (bigger than iron), unstable nucleus is split into two (or more) smaller, more stable nuclei
Fission can be induced by tossing a slow neutron at a nucleus.
During fission, often 2 or more neutrons are released, which can create more fissions (chain reaction)
Nuclear reactors generate power from fission of U235.

33. 33
3. Efficiency
The reaction that the sun uses to generate energy is to fuse (four) hydrogen into helium.
The mass of 4 Hydrogen’s (protons) is: 4( ) = amu
This is more than the Helium ( ), so there was a small amount of mass converted to energy m=( )= amu
Converted to a percentage: / = or 0.7% of the mass was converted to energy. This is called the efficiency.

34. D. Particle Physics Quark model Four fundamental forces34
D. Particle Physics
Quark model
Four fundamental forces
The standard model

35. 1a. Quark model of Baryons35
All Baryons made of 3 quarks (one of each “color”, so that they can all three be in the same “1s” orbital and not violate pauli exclusion principle)
Proton is an “uud”, which adds up to plus charge

36. 1b. The Neutron 36
The neutron is a “udd” combination, which has net zero charge.
The “beta” decay of a neutron into a proton is hence due to one of the “d” quarks decaying into an “u” quark

37. 1c More Quarks 1968 “s” Strange Quark 1974 “c” Charmed Quark37
1968 “s” Strange Quark
1974 “c” Charmed Quark
1977 “b” Bottom (beauty) quark
1995 “t” Top (truth) quark
Murry Gell-Mann 1969 Nobel Prize Quark Model

38. Charmed Baryons: Spin 1/238
C=+2
C=+1
C=0

39. 2. Fundamental Forces Gravity Electromagnetism Strong (Nuclear) Force39
2. Fundamental Forces
Gravity
Electromagnetism
Strong (Nuclear) Force
Weak Force (beta decay)

40. 3. The Standard Model 40 1. Three generations
3 isospin doublets of quarks
Matches 3 generations of lepton doublets
Matches (?) 4 fundamental forces?

41. Fundamental Particles and Interactions41

42. References/Notes 42
Physics Today, Feb (1996) 21-26, “The Discovery of Radioactivity”