Topic 7.2 Extended B – Nuclear Stability  Stable isotopes exist for elements having atomic numbers Z = 1 to 83, excepting 43 and 61.  Up to Z = 20,

Slides:

Advertisements

Similar presentations

Review Draw a model of each of the hydrogen isotopes Hydrogen-1

Advertisements

20th Century Discoveries

Properties of nucleus 26.2 Binding energy and mass defect. UNIT 26 : NUCLEUS is defined as the central core of an atom that is positively charged.

7: Atomic and Nuclear Physics 7.3 Nuclear reactions, fission and fusion.

Nuclear Physics Lesson 13

Nuclear Binding, Radioactivity Sections 32-1 – 32-9 Physics 1161: Lecture 33.

RADIOACTIVE DECAY NCCS 1.1.4

Chapter 31 Nuclear Applications. Neutron-Proton Ratios Any element with more than one proton (i.e., anything but hydrogen) will have repulsions between.

Nuclear Physics Nucleus: –nucleons (neutrons and protons) bound together. –Strong Force binds nucleons together over short range (~ m) –Nuclide:

Nuclear / Subatomic Physics Physics – Chapter 25 (Holt)

Overview. Nucleus = Protons+ Neutrons nucleons A = nucleon number (atomic mass number) Gives you mass density of element Z = proton number (atomic number)

A nucleus is more than just mass

Lecture 10 Energy production. Summary We have now established three important equations: Hydrostatic equilibrium: Mass conservation: Equation of state:

Nuclear Physics Developed by Mr. D. Patterson.

Unit 2 – The Atom Nuclear Chemistry Fusion and Fission.

Topic 7: Atomic and nuclear physics 7

1 Chapter 31 Nuclear Physics and Radioactivity Nuclear Structure a)Proton - positive charge - mass x kg ≈ 1 u b) Neutron - discovered.

Nuclear Physics Physics 12. Protons, Neutrons and Electrons  The atom is composed of three subatomic particles: Particle Charge (in C) Symbol Mass (in.

1. Nucleons. Protons and neutrons 2. Nuclide

Nuclear Chemistry Chapter 21. Slide 2 of 24 Review Chapter 3  Z = Atomic Number  Atomic Number is the number of _______.  Mass Number  Number of _______.

IB Assessment Statements, Topic 7.3  Nuclear Reactions Describe and give an example of an artificial (induced) transmutation Construct and.

Unit 2 – The Atom Nuclear Chemistry Fusion and Fission.

Nuclear Physics and Radioactivity

"More than any other time in history, mankind faces a crossroads. One path leads to despair and utter hopelessness. The other, to total extinction. Let.

PHYS 205 Powerhouse PHYS 205 Possible sources Chemical Energy: Sun has hydrogen and if it has oxygen, than we can make water. will last 18,000 years.

Atomic Stability. Isotopes Isotopes are atoms of an element that have different numbers of neutrons in their nucleus. Cu Copper – 63 OR Copper.

Topic – Physics 2a Mass defect and binding energy Prior learning Atomic structure Electrical forces Key words –Atomic nucleus,mass difference, mass of.

Nuclear Physics Nucleus: –nucleons (neutrons and protons) bound together. –Strong Force binds nucleons together over short range (~ m) –Nuclide:

NUCLEAR MASS AND ENERGY Physics 12. Clip of the day:  Minutephysics…on Einstein and uncertainty principle 

Nuclear Stability Notes

Unit 12 – Nuclear Chemistry. Part II Key Terms Alpha decay – spontaneous decay of a nucleus that emits a helium nucleus and energy Beta decay – spontaneous.

Lecture 1 & 2 © 2015 Calculate the mass defect and the binding energy per nucleon for a particular isotope.Calculate the mass defect and the binding.

Protons and neutrons are called nucleons. An atom is referred to as a nuclide. An atom is identified by the number of protons and neutrons in its nucleus.

Chapter 21 Nuclear Chemistry John A. Schreifels Chemistry 212.

Physics 12 Mr. Jean May 20th, 2014 The plan: Video clip of the day Question #1 –Visiting the Relatives Binding energy Energy Deflection Mass and energy.

Radioactivity Radioactivity is the spontaneous

Nuclear Reactions. Elementary Particles  The only atomic particles that play a part in nuclear reactions are the protons and the neutrons; electrons.

Essential idea: Energy can be released in nuclear decays and reactions as a result of the relationship between mass and energy. Nature of science: Patterns,

NUCLEAR CHEMISTRY THE ULTIMATE IN SPONTANEITY. Review Atomic number (Z) – number of protons Mass number (A) – sum of the protons and the neutrons Nuclides–

5.3.4 Nuclear Fission and Fusion. (a) select and use Einstein’s mass–energy equation ΔE = Δmc 2.

Nuclear Chemistry. ATOMIC REVIEW: Atomic number = # of protons # of neutrons = mass # - atomic # protons & neutrons are in the nucleus.

Review Videos-Radioactivity Review Videos-Strong and Weak Nuclear Forces.

1 Nuclear Stability Notes “Why do protons stay together when positive charges repel each other?” The main reason is because of a force called Strong Force.

Physics 102: Lecture 27, Slide 1 Nuclear Binding, Radioactivity Physics 102: Lecture 28.

Nuclear Reactions Nuclear Reactions.

2 protons 2 neutrons Energy of a nucleus The mass of a helium nucleus is slightly smaller (

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

Unit 3: Part 2 of the Atom Nuclear Chemistry I. The Nucleus (p. 701 – 704 in Class Modern Chemistry Text) I. The Nucleus (p. 701 – 704 in Class Modern.

Notes 42 - Topic 7 - Atomic and Nuclear Physics Artificial.

NUCLEAR CHEMISTRY. Atomic Structure Recall: Atoms – consist of a positively charged nucleus, which has protons and neutrons. IsotopeSymbol# protons# neutronsAtomic.

Nuclear Physics SP2. Students will evaluate the significance of energy in understanding the structure of matter and the universe a. Relate the energy.

Honors Physics Chapter 25: Subatomic Physics.  Nucleons  Protons and Neutrons that Make Up the Nucleus  Atomic Number (Z)  # of Protons  Atomic Mass.

7.2 Nuclear Stability and Nuclear Reactions 2 Nuclides above the band are too large - decay by . To the left  decay occurs. Nuclides below the band.

SACE Stage 2 Physics The Structure of the Nucleus.

Fission and Fusion Physics 12 Adv. Nuclear Particles As we discussed, the nuclear particles are composed of quarks; the individual particles are the result.

Understandings: The unified atomic mass unit Mass defect and nuclear binding energy Nuclear fission and nuclear fusion Applications and skills: Solving.

Unstable Nuclei and Radioactive Decay Radioactivity – spontaneous emission of radiation Radiation – rays and particles emitted from a radioactive material.

Nuclear Stability You should be aware that: A nucleus can be naturally unstable Instability can be induced into a nucleus – for example if we bombard.

7.2 Nuclear Stability and Nuclear Reactions

Mass of constituent parts of the nucleus:

Nuclear Physics Lecture 1& 2 © 2015, 2016.

Nuclear notation and Binding energy

Topic 7: Atomic, nuclear and particle physics 7.2 – Nuclear reactions

Topic 7.3 Continued Fission and Fusion

Nuclear Stability.

Harnessing the Power of the Sun

Harnessing the Power of the Sun

CHAPTER 22 Nuclear Chemistry

Nuclear Chemistry Chapter 21.

Binding energy Electric potential energy => Nuclear Binding energy ( a mass loss! ) What is the energy change that occurs when constituent particles come.

Presentation transcript:

Topic 7.2 Extended B – Nuclear Stability  Stable isotopes exist for elements having atomic numbers Z = 1 to 83, excepting 43 and 61.  Up to Z = 20, the neutron- proton ratio is close to 1.  Beyond Z = 20, the neutron- proton ratio is bigger than 1, and grows with atomic number.  Since  decay decreases protons and neutrons at the same rate, the daughter nucleus would be no more stable than the parent, for the larger atomic numbers.  Thus the larger unstable nuclei become stable by a combo  decay and  - decay (which turns neutrons into protons). N UCLEON P OPULATIONS

Topic 7.2 Extended B – Nuclear Stability  There are 168 stable nuclei having an even number of protons and neutrons.  There are 107 stable nuclei having either Z even and N odd, or Z odd and N even.  There are only 4 stable nuclei having an odd number of each.  Thus, you would expect 27 Al to be stable, but 26 Al to be unstable, and this is the case. P AIRING E FFECT OF S TABLE N UCLEI 13 General Criteria for Nuclear Stability (1) Isotopes with Z < 83 are stable. (2) Most Even-Even, Even-Odd, Odd-Even isotopes are stable. (3) Isotopes with Z Z. Is sulfur-38 stable, or is it unstable?  Since Z = 16 < 83 for sulfur, (1) is satisfied.  Since N = = 22, and Z = 16, (2) is satisfied.  Since Z < 20 and N  Z (3) is not satisfied.  We may conclude that sulfur-38 is NOT stable. FYI: Since there are 6 more neutrons than protons, sulfur-38 is susceptible to  - decay. Question: How many  - decays would it undergo? Question: To which element would it transmute?

Topic 7.2 Extended B – Nuclear Stability  In the world of nuclear reactions we have to keep track of the mass of the nucleus if we are to determine the energy of a reaction.  To this end we define the unified atomic mass unit (u) using a neutral carbon-12 atom as our standard of precisely u. B INDING E NERGY  Thus 1 u =  kg Atomic Mass Unit (u) Particle Masses and Energy Equivalents ParticleMass (u)Mass (kg)Energy (MeV) 1 u  Electron  Proton  H atom  Neutron  He atom  FYI: 1 H has one proton, and 1 electron for a total mass of u u = u. FYI: 4 He has two 1 H (which includes the 2 electrons) and 2 neutrons, for a total mass of 2( ) + 2( ) = u. This value matches the value in the table: This value DOES NOT match the value in the table: FYI: The DIFFERENCE between the constituent masses and the resulting mass is called the mass defect. 4 He has a mass defect of = u.

Topic 7.2 Extended B – Nuclear Stability  We can convert the mass defect  m into equavalent energy using E =  mc 2 : u B INDING E NERGY  kg 1 u ( 3  10 8 ms -1 ) 2 E =  J 1 eV 1.6  J E = E = MeV  To save time you can use the conversion from mass to MeV: 1 u = MeV Atomic Mass Unit (u)  Thus u MeV 1 u = MeV E = FYI: This energy deficit is called the total binding energy (E b ) of the helium nucleus. In fact, this is the energy released in the nuclear reaction which combines the nucleons to form helium. FYI: The sun generates its energy through the nuclear reaction combining hydrogen into helium. Each reaction liberates 28.3 MeV. E b =  mc 2 Binding Energy (E b )

Topic 7.2 Extended B – Nuclear Stability  Just as 28.3 MeV are released when the 4 He fuses... B INDING E NERGY ... we can reverse the process if we somehow "inject" 28.3 MeV into the helium nucleus: FUSION FISSION FYI: The energy to ASSEMBLE the 4 He nucleus from hydrogen on the sun is from gravitational compression. Causing fusion here on earth, we have to obtain this energy in a different way. FYI: The energy to DISASSEMBLE the 4 He nucleus can come from photons of very high energy, or particle beams such as electrons, protons, or anti-protons (p-bars).

Topic 7.2 Extended B – Nuclear Stability  We can calculate the average binding energy per nucleon for helium (or any stable isotope) using the following formula: B INDING E NERGY binding energy per nucleon = EbAEbA Average Binding Energy  Thus for 4 He (A = 4) we have EbAEbA = 28.3 MeV 4 = MeV  To disassemble the nucleus we would need to supply MeV / nucleon.  If we could remove one nucleon, it would take about MeV. FYI: Recall that it takes 13.6 eV to remove an electron from a hydrogen atom. Compare this CHEMICAL energy to the NUCLEAR energy of 7,075,000 eV to remove a nucleon. This gives us a rough comparison NUCLEAR ENERGY to CHEMICAL ENERGY of 7,075,000 eV / 13.6 eV = 520,221! FYI: This is why nuclear bombs pack a real punch!

Topic 7.2 Extended B – Nuclear Stability B INDING E NERGY  We can calculate the average binding energy per nucleon for all of the elements:  For the elements with A < 56 note that fusion results in more stable nuclei.  For the elements with A > 56 note that fission results in more stable nuclei. FYI: The higher the binding energy per nucleon, the harder it is to break apart the nucleus. Thus, the bigger E b /A the more stable the nucleus. Fe (iron) is the most stable element.  Note that iron is the most stable element.

Topic 7.2 Extended B – Nuclear Stability B INDING E NERGY  This brings us to an aside on stellar evolution:  During the lifetime of a star there are two opposing forces maintaining an equilibrium. (1) Gravitation is trying to collapse the star. (2) Radiation pressure is opposing the gravitational collapse. Gravitational Collapse Nuclear Reactions Start Gravitational Collapse Balanced by Radiation Pressure  If a star is sufficiency massive, it will maintain nuclear reactions until it becomes IRON. Question: Why will it cease fusion when it reaches this point?  When such a star becomes iron, it will have no more radiation pressure to oppose gravity.  It will collapse (due to gravity), and its complex iron nuclei will decay into ALL NEUTRONS! FYI: This is called the IRON CATASTROPHE. Question: If the universe started out as hydrogen and helium, and stars can only breed nuclei up to iron, where do all the higher elements come from?

Topic 7.2 Extended B – Nuclear Stability M AGIC N UMBERS  Remember how Pauli's Exclusion Principle told us how many electrons could be at any energy level?  Thus, the magic numbers were 2, 8, 18, 32, etc. for electrons about a nucleus.  Theoretically, these numbers came from Schrödinger's equation.  To make a long story short, Schrödinger's equation also reveals something about the shell structure of the nucleus!  The shells of the nucleus fill up with nucleons just like electron shells fill up with electrons.  A nuclear shell is said to be closed if it has the optimum number of protons OR neutrons in it.  Here is the series of those optimum numbers: 2, 8, 20, 28, 50, 82, or 126. Magic Numbers FYI: Nuclei having this many protons (or neutrons) are more stable than the average nuclei (and usually have more stable isotopes).