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John A. Schreifels

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Title: John A. Schreifels


1
Chapter 7
  • Quantum Theory of the Atom

2
Overview
  • Light Waves, Photons, and the Bohr Theory
  • Wave Nature of Light
  • Quantum Effects and Photons
  • Bohr Theory Hydrogen and Hydrogen-like atoms
  • Quantum Mechanics and Quantum Numbers
  • Quantum Mechanics
  • Quantum Numbers and Atomic Orbitals

3
The Wave Nature of the Light
  • Atomic structure elucidated by interaction of
    matter with light.
  • Light properties characterized by wavelength, ?,
    and frequency,?.
  • Light electromagnetic radiation, a wave of
    oscillating electric and magnetic influences
    called fields.
  • Frequency and wavelength inversely proportional
    to each other.
  • c ??
  • where c the speed of light 3.00x108 m/s
    units ? s?1, ? m
  • E.g. calculate the frequency of light with a
    wavelength of 500 nm.
  • E.g.2 calculate the frequency of light if the
    wavelength is 400 nm.

4
Electromagnetic Radiation and Atomic Spectra - 2
  • Line spectra result from the emission of
    radiation from an excited atom.
  • Spectrum characteristic pattern of wavelengths
    absorbed (or emitted) by a substance.
  • Emission Spectrum spontaneous emission of
    radiation from an excited atom or molecule.
  • Line Spectrum spectrum containing only certain
    wavelengths.
  • Balmer hydrogen has a line spectrum in the
    visible region with wavelengths of 656.3 nm,
    486.1 nm, 434.0 nm, 410.1 nm.
  • Balmer equation where n 3.

5
Quantized Energy and Photons
  • Light wave arriving as stream of particles
    called "photons".
  • Each photon quantum of energy
  • where h (Planck's constant) 6.63x10?34Js.
  • An increase in the frequency an increase in the
    energy
  • An increase in the wavelength gives an decrease
    in the energy of the photon.
  • E.g. determine the energies of photons with
  • wavelengths of 650 nm, 700 nm and
  • frequencies 4.50x1014 s?1, 6.50x1014 s?1
  • Photoelectric effect E h? ? ? where ?
    constant
  • the energy of the electron is directly related to
    the energy of the photon.
  • the threshold of energy must be exceeded for
    electron emission.
  • The total energy of a stream of particles
    (photons) of that energy will be where n
    1, 2, (only discrete energies).

6
Bohrs Model of the Hydrogen Atom
  • Line spectra in other spectral regions also were
    observed
  • Lyman series ultraviolet
  • Paschen, Brackett, Pfund infrared
  • Balmer-Rydberg equation predicted the wavelengths
    of emission.
  • where m 1, 2, 3, and n 2, 3, (always at
    least m 1
  • Longest wavelength observed when n m 1.
  • Shortest wavelength observed when n ?.
  • E.g. Determine the wavelength of emission for the
    first line in the Paschen series (m 3, n 4).
  • E.g. Determine the shortest wavelength in the
    Paschen series (m 3 and n ?).

7
Bohr model of the Hydrogen Atom II
  • Duality of matter led to the hypothesis that
    electrons behave as waves.
  • Bohr model assumed
  • Only circular orbits around the nucleus and that
    the angular momentum around the atom must be
    quantized.
  • Stable orbital where constructive interference
    occurs.
  • Assumption led to the conclusions
  • Radius of an orbital rn n2r1.
  • Energy of an orbital En E1/n2
    ?21.93x10?19J/n2 where E1 energy of the most
    stable hydrogen orbital. E1ltE2ltE3.
  • Most stable state E1,r1 ground state.
  • Higher energy states excited states.
  • A photon is emitted when the electron moves from
    a higher energy state to a lower one.
  • Photon energy equals the difference in energy of
    the two states.

8
Bohr model of the Hydrogen Atom III
  • If Ei the initial state energy and Ef final
    state energy, then the energy of the transition
    would be ?E Ei ? Ef.
  • R Rydberg constant 1.097x107m?1.
  • Theory and experiment agree for hydrogen and
    hydrogen-like particles.

9
Wave Nature of Matter
  • Light behaves like matter since it can only have
    certain energies.
  • Light had both wave- and particle-like properties
    ? matter did too.
  • Einstein equation helps describe the duality of
    light
  • E mc2 Particle behavior
  • E h? Wave behavior
  • Wave and particle behavior
  • Duality of matter expressed by replacing the
    speed of light with the speed of the particle to
    get
  • where ? called the de Broglie wavelength of any
    moving particle.
  • E.g. determine the de Broglie wavelength of a
    person with a mass of 90 kg who is running 10
    m/s.

10
Quantum Mechanics Hydrogen
  • Bohr model did not work with multielectron atoms,
    i.e. line spectra not predicted.
  • Quantum mechanics provides universal description
    of the electron distribution in atoms.
  • Heisenberg uncertainty principle impossible to
    determine the position and momentum with absolute
    precision or (position uncertainty)(momentum
    uncertainty) ?
  • Schroedinger used wave concepts to derive the
    wave equation.Electrons allowed to be in
    anywhere.
  • Solution of the Schroedinger three dimensional
    wave equation, ?, led to the discrete energy
    levels of the hydrogen atom.
  • Lowest level is spherical.
  • Predicts distribution of electrons in other
    elements.

11
Quantum Mechanics and Atomic Orbitals
  • The first orbital of all elements is spherical.
  • Other orbitals have a characteristic shape and
    position as described by 4 quantum numbers
    n,l,ml,ms. All are integers except ms
  • Principal Quantum Number (n) an integer from
    1... Total e? in a shell n2.
  • Angular quantum number (l). (permitted values l
    0 to n?1) the subshell shape.
  • Common usage for l 0, 1, 2, 3, 4, and use s, p,
    d, f, g,... respectively.
  • Subshell described as 1s, 2s, 2p, etc.
  • Magnetic quantum number,ml, (allowed ?l to l )
    directionality of an l subshell orbital.
  • Total number of possible orbitals is 2l1.
  • E.g. s and p subshells have 1 3 orbitals,
    respectively.
  • Spin quantum number,ms (allowed values ?1/2).
    Due to induced magnetic fields from rotating
    electrons.
  • Pauli exclusion principle no two electrons in an
    atom can have the same four quantum numbers.

12
Permissible Quantum States
13
Figure 7.23 Orbital energies of the hydrogen
atom.
14
Orbital Energies of Multielectron Atoms
  • All elements have the same number of orbitals
    (s,p, d, and etc.).
  • In hydrogen these orbitals all have the same
    energy.
  • In other elements there are slight orbital energy
    differences as a result of the presence of other
    electrons in the atom.
  • The presence of more than one electron changes
    the energy of the electron orbitals (click here)

15
Shape of 1s Orbital
16
Shape of 2p Orbital
17
Shape of 3d Orbitals
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