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Nuclear notation and Binding energy Contents: Atomic notation Isotopes Whiteboard Binding Energy AMU Making an atom Calculating binding energy Whiteboards.

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Presentation on theme: "Nuclear notation and Binding energy Contents: Atomic notation Isotopes Whiteboard Binding Energy AMU Making an atom Calculating binding energy Whiteboards."— Presentation transcript:

1 Nuclear notation and Binding energy Contents: Atomic notation Isotopes Whiteboard Binding Energy AMU Making an atom Calculating binding energy Whiteboards The curve of binding energy and the strong nuclear force (or why there is a limit to the periodic table)The curve of binding energy and the strong nuclear force (or why there is a limit to the periodic table)

2 Atomic notation X A Z X = Symbol (C, Au) A = Atomic Mass Number = #nucleons (Protons + Neutrons) Z = Atomic Number = #protons C 12 6 Carbon A = 12, Z = 6. #neutrons? TOC

3 Isotopes Carbon 12 has 6 Neutrons TOC C 12 6 C 14 6 Carbon 14 has 8 Neutrons Carbon 14 is an isotope of Carbon Chemically the same Nuclear-lly different (it’s unstable) C-14, C-12

4 Whiteboards: Atomic Notation 11 | 2 | 3 | 4 | 52345 TOC

5 W Hydrogen has a Z = 1, A = 1 p + 2 n = 3 What is the Atomic notation for tritium? (tritium is an isotope of Hydrogen with 2 neutrons) 3/1 H

6 22/10 Ne Z = 10, A = 10 + 12 = 22, element 10 is Ne 10 protons, 12 neutrons. What is its atomic notation? W

7 143 U is element 92 235 - 92 = 143 neutrons How many neutrons in U 235? (235 = A) (1) W

8 126 Pb is element 82 208 - 82 = 126 neutrons How many neutrons in Pb 208? (208 = A) (1) W

9 42 Kr is element 36 78 - 36 = 42 neutrons How many neutrons in Kr 78? (1) W

10 Binding energy - the energy to take an atom apart Unified Mass Units: (u) C 12 (neutral atom) = 12.0000000 u (defined) 1 u = 1.6605 x 10 -27 kg = 931.5 MeV (show c = 2.998x10 8 m/s) Electron =.00054858 u (not useful) Proton = 1.007276 u (not useful) H (neutral atom) = 1.007825 u (very useful) Neutron = 1.008665 u (very useful)

11 Binding energy - the energy to take an atom apart TOC To take an atom apart: C 14 has a mass of 14.003242 u (p. 1064 in text) C 14 can be taken apart into: 6 H atoms:6(1.007825 u) (i.e. 6 p + 6 e) 8 Neutrons:8(1.008665 u) Total “taken apart” mass = 6(1.007825 u) + 8(1.008665 u) Total “taken apart” mass = 14.116270 u Mass “defect” = 14.11627 u - 14.003242 u = 0.113028 u 0.113028 u - Represents energy needed to take atom apart Binding energy = (0.113028 u)(931.5 MeV/u) = 105.3 MeV H (neutral atom) = 1.007825 u (very useful) Neutron = 1.008665 u (very useful) 1 u = 931.5 MeV

12 Binding energy - the energy to take an atom apart TOC Binding energy in general 1.Look neutral atom mass in Appendix F (p 1064) 2.Break atom into H and n 3.Subtract neutral atom mass from taken apart mass 4.Multiply mass defect by 931.5 Mev/u H (neutral atom) = 1.007825 u (very useful) Neutron = 1.008665 u (very useful) 1 u = 931.5 MeV

13 Whiteboards: Binding Energy 11 | 2 | 323 TOC

14 W Atom mass = 13.005738 7H + 6n = 7(1.007825 u) +6(1.008665 u) = 13.106765 u Binding energy = (13.106765 - 13.005738)931.5 MeV/u = 94.11 MeV What is the binding energy for Nitrogen 13? (Z = 7) N 13 mass = 13.005738 u H = 1.007825 u Neutron = 1.008665 u 1 u = 931.5 MeV 94.11 MeV

15 W What is the binding energy for Carbon 12? (Z = 6) C 12 mass = 12.000000 u (duh?) H = 1.007825 u Neutron = 1.008665 u 1 u = 931.5 MeV 92.16 MeV Atom mass = 12.000000 6H + 6n = 6(1.007825 u) +6(1.008665 u) = 12.09894 u Binding energy = (12.098940 – 12.000000)931.5 MeV/u = 92.16 MeV Binding energy per nucleon: C 12: 92.16/12 = 7.68 MeV/nucleon C 14: 105.3/14 = 7.52 MeV/nucleon (less)

16 W What is the binding energy for Carbon 10? (Z = 6) C 10 mass = 10.231610 u H = 1.007825 u Neutron = 1.008665 u 1 u = 931.5 MeV -139.7 Atom mass = 10.231610 6H + 4n = 6(1.007825 u) +4(1.008665 u) = 10.08161 u Binding energy = (10.08161 - 10.23161)931.5 MeV/u = -139.7 MeV (Carbon 10 does not exist)

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