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ENTC 4390 MEDICAL IMAGING

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ENTC 4390 MEDICAL IMAGING STRUCTURE OF MATTER Since the late 1920s it has been understood that electrons in an atom do not behave exactly like tiny moons orbiting a ... – PowerPoint PPT presentation

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Title: ENTC 4390 MEDICAL IMAGING


1
ENTC 4390MEDICAL IMAGING
  • STRUCTURE OF MATTER

2
  • Since the late 1920s it has been understood that
    electrons in an atom do not behave exactly like
    tiny moons orbiting a planet-like nucleus.
  • Their behavior Is described more accurately if,
    instead of defining them as point particles in
    orbits with specific velocities and positions,
    they are defined as entities whose behavior is
    described by wave functions.

3
  • While a wave function itself is not directly
    observable, calculations may be performed with
    this function to predict the location of the
    electron.
  • In contrast to the calculations of classical
    mechanics in which properties such as force,
    mass, acceleration, and so on, are entered into
    equations to yield a definite answer for a
    quantity such as position in space, quantum
    mechanical calculations yield probabilities.

4
  • At a particular location in space, for example,
    the square of the amplitude of a particles wave
    function yields the probability that the particle
    will appear at that location.
  • However, it is important to emphasize that the
    probability of finding the electron at other
    locations, even in the middle of the nucleus, is
    not zero.
  • This particular result explains a certain form of
    radioactive decay in which a nucleus captures an
    electron.
  • This event is not explainable by classical
    mechanics, but can be explained with quantum
    mechanics.

5
Atomic Theory
  • An atom consists of a nucleus of protons and
    neutrons surrounded by a group of orbiting
    electrons.
  • Electrons have a negative charge, protons have a
    positive charge.
  • In its normal state, each atom has an equal
    number of electrons and protons.

6
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7
Atomic Theory
  • Electrons orbit the nucleus in discrete orbits
    called shells.
  • These shells are designated by letters K, L, M,
    N, etc.
  • Only certain numbers of electrons can exist
    within any given shell.

8
Atomic Theory
  • The outermost shell of an atom is called the
    valence shell.
  • The electrons in this shell are called valence
    electrons.
  • No element can have more than eight valence
    electrons.
  • The number of valence electrons affects its
    electrical properties.

9
  • The binding energy of an electron (Eb) is defined
    as the energy required to completely separate the
    electron from the atom.
  • When energy is measured in the macroscopic world
    of everyday experience, units such as joules and
    kilowatt-hours are used.
  • In the microscopic world, the electron-volt is a
    more convenient unit of energy
  • One electron volt is the kinetic energy imparted
    to an electron accelerated across a potential
    difference (i.e., voltage) of 1 Volt.

10
  • The electron volt can be convened to other units
    of energy
  • 1eV 1.6 x 109J
  • 1.6 x 1012 erg
  • 4.4)lt 1026 kW-hr
  • Nott 103eV 1 keV
  • lO6eV lMc\

11
  • The electron volt describes potential as well as
    kintnic energy. The binding energy of
  • an electron in an atom is a form oF potential
    energy

12
  • An electron in an inner shell of an atom is
    attracted to the nucleus by a force greater than
    that exerted by the nucleus on an electron
    farther away.
  • An electron may be moved from one shell to
    another shell that is farther from the nucleus
    only if energy is supplied by an external source.
  • Binding energy is negative (i.e., written with a
    minus sign) because it represents an amount of
    energy that must be supplied to remove an
    electron from an atom. The energy that must be
    imparted to an atom to move an electron from an
    inner shell to an outer shell is equal to the
    arithmetic difference in binding energy between
    the two shells.

13
  • For example, the binding energy is ?13.5 eV for
    an electron in the K shell of hydrogen and is ?
    3.4 eV for an electron in the L shell.
  • The energy required to move an electron from the
    K to the L shell in hydrogen is (?3.4 eV) ?
    (?13.5 eV) 10.1 eV

14
  • Electrons in inner shells of high-Z atoms are
    near a nucleus with high positive charge.
  • These electrons are bound to the nucleus with a
    force much greater than that exerted upon the
    solitary electron in hydrogen.
  • All of the electrons within a particular electron
    shell do not have exactly the same binding energy
  • Differences in binding energy among the electrons
    in a particular shell are described by the
    orbital, magnetic, and spin quantum numbers,

15
  • The combinations of these quantum numbers allowed
    by quantum mechanics provide
  • three subshells (LI to LIII) for the L shell and
  • five subshells (MI to Mv) for the M shell
  • the M subshells occur only if a magnetic field is
    present.
  • Energy differences between the subshells are
    small when compared with differences between
    shells.
  • These differences are important in radiology
    however, because they explain certain properties
    of the emission spectra of x-ray tubes.

16
  • Various processes can cause an electron to be
    ejected from an electron shell.
  • When an electron is removed from a shell, a
    vacancy or hole is left in the shell
  • (i.e., a quantum address is left vacant.
  • An electron may move from one shell to another to
    fill the vacancy
  • This movement, termed an electron transition,
    involves a

17
Conductors
  • Materials that have large numbers of free
    electrons are called conductors.
  • Metals are generally good conductors because they
    have few loosely bound valence electrons.
  • Silver, gold, copper, and aluminum are excellent
    conductors.

18
Insulators
  • Materials that do not conduct because their
    valence shells are full or almost full are called
    insulators.
  • Glass, porcelain, plastic, and rubber are good
    insulators.
  • If high enough voltage is applied, an insulator
    will break down and conduct.

19
Semiconductors
  • Semiconductors have half-filled valence shells
    and are neither good conductors nor good
    insulators.
  • Silicon and germanium are good semiconductors.
  • They are used to make transistors, diodes, and
    integrated circuits.

20
Electrical Charge
  • Objects become charged when they have an excess
    or deficiency of electrons.
  • An example is static electricity.
  • The unit of charge is the coulomb.
  • 1 coulomb 6.24 1024 electrons.

21
ENTC 4390
  • THE NUCLEUS

22
Nucleons
  • A nucleus consists of two types of particles,
    referred to collectively as nucleons.
  • The positive charge and roughly half the mass of
    the nucleus are contributed by protons.
  • The second type of nucleon is the neutron.

23
Protons
  • Each proton possesses a positive charge of 1.6 x
    10-19 coulombs.
  • equal to in magnitude and opposite in sign to the
    charge of an electron.
  • The number of protons in nucleus is the atomic
    number of the atom.
  • The mass of a proton is 1.6734 x 10-27 kg.

24
Neutrons
  • Neutrons are uncharged particles with a mass of
    1.6747 x 10-27 kg.
  • Outside the nucleus, neutrons are unstable and
    divide into protons, electrons, and
    antineurtrinos.
  • The number of neutrons in in a nucleus is the
    neutron number N for the nucleus.

25
  • The mass number
  • A Z N
  • The standard form used to denote the composition
    of a specific nucleus is
  • where X is the chemical symbol.

26
Isotopes
  • Isotopes are atoms that possess the same number
    of protons but a varying number of neutrons.
  • Isotopes of hydrogen are
  • 1Hprotium
  • 2Hdeuterium
  • 3Htritium

27
ENTC 4390
  • NUCLEAR FISSION FUSION

28
Nuclear Power
  • Nuclear power may be produced in two ways
  • Nuclear fission involves the splitting of an atom
    into two fragments, particles, and the release of
    energy
  • Nuclear fusion involves the combination of two
    nuclei into a single, more massive nuclei, plus
    energy
  • Stars are powered by nuclear fusion

29
Nuclear Fusion
  • Nuclear Fusion has been used since the early
    1950s in Hydrogen bombs
  • These are the most powerful type of nuclear
    weapon
  • We have not yet devised a method of utilizing the
    power of nuclear fusion in the laboratory, nor in
    any commercial reactor
  • Therefore, we will not further consider fusion in
    this course

30
Nuclear Fission
  • Fission induced by neutron bombardment and capture

31
Fission Diagram
  • When a heavy nucleus undergoes fission, a variety
    of fragment pairs may be formed, depending on the
    distribution of neutrons and protons between the
    fragments

32
Fission Yield
  • This leads to probability distribution of both
    mass and nuclear charge for the fragments
  • The probability of formation of a particular
    fragment is called its fission yield and is
    expressed as the percentage of fissions leading
    to it

33
Fission Products
  • A fission product is any of the lighter atomic
    nuclei formed by splitting heavier nuclei
    (nuclear fission), including both the primary
    nuclei directly produced (fission fragments) and
    the nuclei subsequently generated by their
    radioactive decay

34
Fission Fragment Decay
  • Fission fragments are highly unstable because of
    their abnormally large number of neutrons
    compared with protons
  • Consequently, they undergo successive radioactive
    decays by emitting neutrons, by converting
    neutrons into protons, antineutrinos, and ejected
    electrons (beta decay), and by radiating energy
    (gamma decay)

35
Fission of 235U
  • One of the many known fission reactions of
    uranium-235 induced by absorbing a neutron
    results, for example, in two extremely unstable
    fission fragments, a barium and a krypton nucleus
  • These fragments almost instantaneously release
    three neutrons between themselves, becoming
    barium-144 and krypton-89

36
Barium Decay
  • By repeated beta decay, the barium-144 in turn is
    converted step by step to other fission products
  • Lanthanum-144
  • Cerium-144
  • Praseodymium-144
  • Eventually relatively stable neodymium-144

37
Krypton
  • krypton-89 is similarly transformed by repeated
    beta decay to
  • Rubidium-89
  • Strontium-89
  • To stable yttrium-89

38
Fission Product Identification
  • Fission products are identified by their chemical
    properties and by their radioactive properties,
    such as their half-lives and the kinds of
    particles they emit
  • The multiple decays mean fission products are
    highly radioactive and therefore quite dangerous

39
Why are Fission Products Radioactive?
  • To maintain stability, the neutron-to-proton
    (n/p) ratio in nuclei must increase with
    increasing proton number
  • The ratio remains at unity up to the element
    calcium, with 20 protons
  • It then gradually increases until it reaches a
    value of about 1.5 for the heaviest elements

40
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