Chapter 29

Chapter 29 Nuclear Physics

Ernest Rutherford • 1871 – 1937 • Discovery that atoms could be broken apart • Studied radioactivity • Nobel prize in 1908

Some Properties of Nuclei • All nuclei are composed of protons and neutrons • Exception is ordinary hydrogen with just a proton • The atomic number, Z, equals the number of protons in the nucleus • The neutron number, N, is the number of neutrons in the nucleus • The mass number, A, is the number of nucleons in the nucleus • A = Z + N • Nucleon is a generic term used to refer to either a proton or a neutron • The mass number is not the same as the mass

Symbolism • Symbol: • X is the chemical symbol of the element • Example: • Mass number is 27 • Atomic number is 13 • Contains 13 protons • Contains 14 (27 – 13) neutrons • The Z may be omitted since the element can be used to determine Z

More Properties • The nuclei of all atoms of a particular element must contain the same number of protons • They may contain varying numbers of neutrons • Isotopes of an element have the same Z but differing N and A values • Example:

Charge • The proton has a single positive charge, +e • The electron has a single negative charge, -e • The neutron has no charge • Makes it difficult to detect • e = 1.602 177 33 x 10-19 C

Mass • It is convenient to use unified mass units, u, to express masses • 1 u = 1.660 559 x 10-27 kg • Based on definition that the mass of one atom of C-12 is exactly 12 u

Density of Nuclei • The volume of the nucleus (assumed to be spherical) is directly proportional to the total number of nucleons • This suggests that all nuclei havenearly the same density • Nucleons combine to form a nucleus as though they were tightly packed spheres

Maria Goeppert-Mayer • 1906 – 1972 • Best known for her development of shell model of the nucleus • Shared Nobel Prize in 1963

Nuclear Stability • There are very large repulsive electrostatic forces between protons • These forces should cause the nucleus to fly apart • The nuclei are stable because of the presence of another, short-range force, called the nuclear force • This is an attractive force that acts between all nuclear particles • The nuclear attractive force is stronger than the Coulomb repulsive force at the short ranges within the nucleus

Nuclear Stability, cont • Light nuclei are most stable if N = Z • Heavy nuclei are most stable when N > Z • As the number of protons increase, the Coulomb force increases and so more nucleons are needed to keep the nucleus stable • No nuclei are stable when Z > 83

Marie Curie • 1867 – 1934 • Discovered new radioactive elements • Shared Nobel Prize in physics in 1903 • Nobel Prize in Chemistry in 1911

Radioactivity • Radioactivity is the spontaneous emission of radiation • Experiments suggested that radioactivity was the result of the decay, or disintegration, of unstable nuclei

Radioactivity – Types • Three types of radiation can be emitted • Alpha particles • The particles are 4He nuclei • Beta particles • The particles are either electrons or positrons • A positron is the antiparticle of the electron • It is similar to the electron except its charge is +e • Gamma rays • The “rays” are high energy photons

Distinguishing Types of Radiation • A radioactive beam is directed into a region with a magnetic field • The gamma particles carry no charge and they are not deflected • The alpha particles are deflected upward • The beta particles are deflected downward • A positron would be deflected upward

Penetrating Ability of Particles • Alpha particles • Barely penetrate a piece of paper • Beta particles • Can penetrate a few mm of aluminum • Gamma rays • Can penetrate several cm of lead

Alpha Decay • When a nucleus emits an alpha particle it loses two protons and two neutrons • N decreases by 2 • Z decreases by 2 • A decreases by 4 • Symbolically • X is called the parent nucleus • Y is called the daughter nucleus

Alpha Decay – Example • Decay of 226 Ra • Half life for this decay is 1600 years • Excess mass is converted into kinetic energy • Momentum of the two particles is equal and opposite

Decay – General Rules • When one element changes into another element, the process is called spontaneous decay or transmutation • The sum of the mass numbers, A, must be the same on both sides of the equation • The sum of the atomic numbers, Z, must be the same on both sides of the equation • Conservation of mass-energy and conservation of momentum must hold

Beta Decay • During beta decay, the daughter nucleus has the same number of nucleons as the parent, but the atomic number is changed by one • Symbolically

Beta Decay, cont • The emission of the electron is from the nucleus • The nucleus contains protons and neutrons • The process occurs when a neutron is transformed into a proton and an electron • Energy must be conserved

Beta Decay – Electron Energy • The energy released in the decay process should almost all go to kinetic energy of the electron (KEmax) • Experiments showed that few electrons had this amount of kinetic energy

Neutrino • To account for this “missing” energy, in 1930 Pauli proposed the existence of another particle • Enrico Fermi later named this particle the neutrino • Properties of the neutrino • Zero electrical charge • Mass much smaller than the electron, recent experiments indicate definitely some mass • Spin of ½ • Very weak interaction with matter

Beta Decay – Completed • Symbolically •  is the symbol for the neutrino • is the symbol for the antineutrino • To summarize, in beta decay, the following pairs of particles are emitted • An electron and an antineutrino • A positron and a neutrino

Gamma Decay • Gamma rays are given off when an excited nucleus “falls” to a lower energy state • Similar to the process of electron “jumps” to lower energy states and giving off photons • The photons are called gamma rays, very high energy relative to light • The excited nuclear states result from “jumps” made by a proton or neutron • The excited nuclear states may be the result of violent collision or more likely of an alpha or beta emission

Gamma Decay – Example • Example of a decay sequence • The first decay is a beta emission • The second step is a gamma emission • The C* indicates the Carbon nucleus is in an excited state • Gamma emission doesn’t change either A or Z

Enrico Fermi • 1901 – 1954 • Produced transuranic elements • Other contributions • Theory of beta decay • Free-electron theory of metals • World’s first fission reactor (1942) • Nobel Prize in 1938

Uses of Radioactivity • Carbon Dating • Beta decay of 14C is used to date organic samples • The ratio of 14C to 12C is used • Smoke detectors • Ionization-type smoke detectors use a radioactive source to ionize the air in a chamber • A voltage and current are maintained • When smoke enters the chamber, the current is decreased and the alarm sounds

More Uses of Radioactivity • Radon detection • Radon is an inert, gaseous element associated with the decay of radium • It is present in uranium mines and in certain types of rocks, bricks, etc that may be used in home building • May also come from the ground itself

Natural Radioactivity • Classification of nuclei • Unstable nuclei found in nature • Give rise to natural radioactivity • Nuclei produced in the laboratory through nuclear reactions • Exhibit artificial radioactivity • Three series of natural radioactivity exist • Uranium • Actinium • Thorium • See table 29.2

Decay Series of 232Th • Series starts with 232Th • Processes through a series of alpha and beta decays • Ends with a stable isotope of lead, 208Pb

Nuclear Reactions • Structure of nuclei can be changed by bombarding them with energetic particles • The changes are called nuclear reactions • As with nuclear decays, the atomic numbers and mass numbers must balance on both sides of the equation

Nuclear Reactions – Example • Alpha particle colliding with nitrogen: • Balancing the equation allows for the identification of X • So the reaction is

Radiation Damage in Matter • Radiation absorbed by matter can cause damage • The degree and type of damage depend on many factors • Type and energy of the radiation • Properties of the absorbing matter • Radiation damage in biological organisms is primarily due to ionization effects in cells • Ionization disrupts the normal functioning of the cell

Types of Damage • Somatic damage is radiation damage to any cells except reproductive ones • Can lead to cancer at high radiation levels • Can seriously alter the characteristics of specific organisms • Genetic damage affects only reproductive cells • Can lead to defective offspring

Units of Radiation Exposure • Roentgen [R] • That amount of ionizing radiation that will produce 2.08 x 109 ion pairs in 1 cm3 of air under standard conditions • That amount of radiation that deposits 8.76 x 10-3 J of energy into 1 kg of air • Rad (Radiation Absorbed Dose) • That amount of radiation that deposits 10-2 J of energy into 1 kg of absorbing material

Radiation Levels • Natural sources – rocks and soil, cosmic rays • Background radiation • About 0.13 rem/yr • Upper limit suggested by US government • 0.50 rem/yr • Excludes background and medical exposures • Occupational • 5 rem/yr for whole-body radiation • Certain body parts can withstand higher levels • Ingestion or inhalation is most dangerous

Applications of Radiation • Sterilization • Radiation has been used to sterilize medical equipment • Used to destroy bacteria, worms and insects in food • Bone, cartilage, and skin used in graphs is often irradiated before grafting to reduce the chances of infection

Applications of Radiation, cont • Tracing • Radioactive particles can be used to trace chemicals participating in various reactions • Example, 131I to test thyroid action

Applications of Radiation, final • MRI • Magnetic Resonance Imaging • When a nucleus having a magnetic moment is placed in an external magnetic field, its moment processes about the magnetic field with a frequency that is proportional to the field • Transitions between energy states can be detected electronically

Chapter 29

Chapter 29

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Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

CHAPTER 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

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Chapter 29

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Chapter 29

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Chapter 29