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Nuclear Physics PHY232 Remco Zegers Room W109 – cyclotron building

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Presentation on theme: "Nuclear Physics PHY232 Remco Zegers Room W109 – cyclotron building"— Presentation transcript:

1 Nuclear Physics PHY232 Remco Zegers zegers@nscl.msu.edu Room W109 – cyclotron building http://www.nscl.msu.edu/~zegers/phy232.html

2 PHY232 - Remco Zegers - nuclear physics 2 Periodic table of elements We saw that the periodic table of elements can be used to visualize the atomic structure of atoms. It describes the structure of the electron shells in the atom which is important to understand chemical properties of the elements

3 PHY232 - Remco Zegers - nuclear physics 3 the nucleus  The core of the atom is the nucleus and it consists of neutron and protons.  To understand the properties of the nucleus, a quantum-mechanical treatment is necessary (just like for the electrons orbiting the nucleus).  The quantum mechanical description is quite similar to that for the electrons, resulting in a shell-model that describes the structure of the nucleus and its excited states.  each constituent is described by a wave function that gives the probability of finding the nucleon at a certain place

4 PHY232 - Remco Zegers - nuclear physics 4 identifying nuclei In the periodic table of elements, there is only one entry for a given atom (e.g. Carbon). However, for a given number of protons (Z), which determines the name of the element, a variable amount of neutrons can be present. For example, in the case of Carbon, two “stable” isotopes exist, one with 6 neutrons ( 12 C, which is most abundant in nature) and one with ( 13 C) 7 neutrons, which is relatively rare. The other isotopes are unstable (e.g. 14 C) and only live for a ‘short’ period of time Z N

5 PHY232 - Remco Zegers - nuclear physics 5 identification of nuclei Mass number A: total number of nucleons. A=Z(protons)+N(neutrons) Atomic number Z: number of protons Neutron number N: number of neutrons Note that a notation using just the character for the element and the mass number is sufficient to identify the nucleus. For example: 26 Mg: “Mg” tells you that Z=12 and A=26, so N=14 The radius of the nucleus can be calculated using: r=r 0 A 1/3 with r 0 =1.25x10 -15 m (1.25 fm)

6 PHY232 - Remco Zegers - nuclear physics 6 Nuclear masses ParticlekguMeV/c 2 Proton1.673x10 -27 1.007276938.28 Neutron1.675x10 -27 1.008665939.57 Electron9.11x10-315.486x10 -4 0.511 1 unified mass unit: mass( 12 C)/12 Einstein: E=mc 2 so: m=E/c 2 1eV=1.60217733x10 -19 J 1MeV=1.60217733x10 -13 J 1u=931.494 MeV/c 2

7 PHY232 - Remco Zegers - nuclear physics 7 example:  what is the radius of 12 C?  what is the radius of 208 Pb?

8 PHY232 - Remco Zegers - nuclear physics 8 what keeps the nucleons together?  The nucleus consists of positive charges (protons) and neutral particles (neutrons). The positive charges should repel and the nucleus thus fall apart. However, they stick together!!  The reason is the so-called ‘strong’ force that acts between the particles. It is very strong, but its range very short!  Nevertheless, not all nuclei can stay together…

9 PHY232 - Remco Zegers - nuclear physics 9 Binding energy The total energy (mass) of a bound system is less than the combined energy (mass) of the separated nucleons Example: deuteron 2 H (1 proton + 1 neutron+1 electron) m p =1.007276u (proton mass, not 1 H mass!) m n =1.008665 u m e =5.486x10 -4 u (if 1 H is used for m p ignore m e !) m p+n+e =2.016490 u (sum)m 2H =2.014102 u m p+n+e -m 2H =0.002338u (2.224 MeV) The deuteron is 0.002338 u lighter than the sum of the separate proton and the neutron. This is the binding energy and is the energy needed to break that nucleus apart in its separate constituents

10 PHY232 - Remco Zegers - nuclear physics 10 example  What are the binding energies (MeV) of 15 O and 16 O? Go here to get atomic masses: http://ie.lbl.gov/toi2003/MassSearch.asp

11 PHY232 - Remco Zegers - nuclear physics 11 Binding energy MeV per Nucleon Atomic mass M(A)=M(Z)+M(N)-B(N,Z) Most stable fusionfission A source of energy!

12 PHY232 - Remco Zegers - nuclear physics 12 nuclear reactors use fission of heavy elements like uranium fusion reactor: work in progress: ITER

13 PHY232 - Remco Zegers - nuclear physics 13 Now consider 226 Radium 226 Ra: 226.025402 u 222 Rn: 222.017571 u 4 He: 4.002602 u Sum: 226.020173 u difference: 0.005229 u (or 4.87 MeV) in favor of the separate system It is energetically more favorable for the 226 Ra to emit an alpha particle ( 4 He). 4.87 MeV in energy is gained. Where does this energy go to???

14 PHY232 - Remco Zegers - nuclear physics 14 question  226 Ra can decay into 222 Rn (Radon) and an alpha particle. what happens to the energy that is released in the decay?  a) into the excitation of electrons orbiting the nuclei.  b) into the motion (kinetic energy) of the decay products  c) into creating of additional particles

15 PHY232 - Remco Zegers - nuclear physics 15 Radioactivity Spontaneous emission of radiation by unstable nuclei. Note that the binding energy for unstable particles is positive which tells you that the nucleus would not fall apart in its separate constituents. However, as we just saw it can be favorable to break up into several chunks. 4 He (  particles)  particles (electrons or positrons)  rays (energetic photons)

16 PHY232 - Remco Zegers - nuclear physics 16  - decay and tunneling Because of ‘tunneling’, the quantum mechanical wavefunction for the  -particle is not zero outside the nucleus. It has a small probability to be there and thus a small probability it can escape. 234 Th  Coulomb barrier

17 PHY232 - Remco Zegers - nuclear physics 17  -decay  - -decay electron emission  + -decay positron emission (electron with + charge) The atomic number is changed by 1, but the mass number remains constant  -decay is governed by the weak force which is short range, but very weak.

18 PHY232 - Remco Zegers - nuclear physics 18 fundamental forces strong force holds nucleons/quarks together strength 1 range: 1 fm electromagnetic force: electric & magnetic forces strength 1/137 range: infinity weak force describes neutrino interactions strength 10 -6 range: 10 -18 gravity describes force between massive objects strength 6x10 -39 range: infinity

19 PHY232 - Remco Zegers - nuclear physics 19 types of  -decay  - decay an electron is emitted A Z X turns into A Z+1 Y  + decay a positron is emitted A Z X turns into A Z-1 Y electron capture A Z X turns into A Z-1 Y

20 PHY232 - Remco Zegers - nuclear physics 20 …not the complete story Besides the electron (positron) also an anti-neutrino (neutrino) is produced. Look at the spectrum resulting from the beta decay of many nuclei Kinetic energy of the electron (MeV) if neutrinos would not exist all electron would have fixed energy, because of momentum and energy conservation in the decay. This is not observed! Another particle is present: the neutrino! neutrinos ( ) are very light and don’t interact well with material and thus hard to detect. Number of events no neutrinos

21 PHY232 - Remco Zegers - nuclear physics 21  -decay Just like in the case of electrons, the nucleus has different energy levels and going from one to another is associated with the release of a photon (MeV)

22 PHY232 - Remco Zegers - nuclear physics 22 An example ( 226 U)

23 PHY232 - Remco Zegers - nuclear physics 23 radioactivity

24 PHY232 - Remco Zegers - nuclear physics 24 chart of nuclei

25 PHY232 - Remco Zegers - nuclear physics 25 Decay chain The half life indicates how long it takes for half of the nuclei in a sample to decay.

26 PHY232 - Remco Zegers - nuclear physics 26 decay R: decay rate or Activity : decay constant  : decay time (=1/ ) Half-life: T 1/2 =ln2/ =0.693/ N: number of particle remaining N 0 : initial number of particles R: the decay rate

27 PHY232 - Remco Zegers - nuclear physics 27 half-life t 1/2 N0N0 N 0 /2 1 Curie (Ci) = 3.7x10 10 decays/s 1 Bq = 1 decay/s N=N 0 e -tln2/T 1/2

28 PHY232 - Remco Zegers - nuclear physics 28 example  a) Polonium-210 has a half-life of 140 days. If a sample of this material has an initial activity of 1mCi, what is the activity after 20 days and 2000 days?  b) what is the activity after 3 half-lives?  c) if after 100 seconds 1/3 of a sample of unknown material has decayed, what is it’s half-life? N=N 0 e -tln2/T 1/2

29 PHY232 - Remco Zegers - nuclear physics 29 14 C dating Shroud of Turin 14 C is produced from 14 N by Cosmic rays. While alive, organisms have a fixed 12 C/ 14 C ratio (1/1.3x10 -12 ) (Carbon in CO 2 ). After dying, no more 14 C is absorbed and it decays away and the ratio of 12 C/ 14 C can be used for dating. Found to be 1320±60 years old

30 PHY232 - Remco Zegers - nuclear physics 30 Natural occurring radioactivity some can be harmful, like Radon gas in basements some are man-made, like fall-out from nuclear explosions some are useful, for example when used in a smoke detector or for treatment of cancer, or for determining the age of an object. Many elements that occur in nature are radioactive. They have a long life time and so can still be found even if they were made a long time ago. Radiation is harmful because it can damage DNA/body tissue (the particles get stopped and deposit energy in the body). For the same reason they can be used to destroy tumors fiesta ware

31 PHY232 - Remco Zegers - nuclear physics 31 stopping of radioactive material  different types of radiation have different ranges when passing through material. Gammas (and neutrons) have long ranges (not charged!) Beta and Alpha radiation have shorter ranges

32 PHY232 - Remco Zegers - nuclear physics 32 nuclear reactions  Besides natural radioactive decay, nuclear reactions can also be ‘created’, for example in a cyclotron lab, such as the NSCL on MSU campus, to study the properties of nuclei. cyclotrons to accelerate particles fragment separator to make clean beams to experimental devices S800 spectrometer to detect particles after reaction speed of particle beams 0.4c

33 PHY232 - Remco Zegers - nuclear physics 33 nuclear reactions  Many nuclear reactions are studied, for example: 34 P + 7 Li  34 Si + 7 Be usually written as: 34 P( 7 Li, 7 Be) 34 Si Note that mass number and atomic number must be conserved before and after the reaction takes place: (A=34, Z=15) + (A=7, Z=3)  (A=34,Z=14) + (A=7, Z=4) A sum =41, Z sum =18  A sum =41, Z sum =18

34 PHY232 - Remco Zegers - nuclear physics 34 examples  which element is missing?  a) 12 C( ,  )?  b) 56 Ni( 2 H,?) 57 N

35 PHY232 - Remco Zegers - nuclear physics 35 where do all these nuclei come from? remnant of an exploded star (supernova) stable nuclei


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