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1
Electromagnetic Radiation
Radiant energy that exhibits wavelength-like behavior and travels through space at the speed of light in a vacuum.
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2
Waves
Waves have 3 primary characteristics:
1. Wavelength: distance between two peaks in a wave.
2. Frequency: number of waves per second that pass a given point in space.
3. Speed: speed of light is 3.00 108 m/s.
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Figure 7.1 The Nature of Waves
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Wavelength and frequency can be interconverted.
= c/
= frequency (s1)
= wavelength (m)
c = speed of light (m s1)
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5
Planck’s Constant
E = change in energy, in J
h = Planck’s constant, 6.626 1034 J s
= frequency, in s1
= wavelength, in m
E hhc
= =
Transfer of energy is quantized, and can only Transfer of energy is quantized, and can only occur in discrete units, called quanta.occur in discrete units, called quanta.
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Energy and Mass
Energy has mass, so does yo mama
E = mc2
E = energy
m = mass
c = speed of light
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Energy and Mass
Ehc
photon =
mhcphoton =
(Hence the (Hence the dualdual nature of light.) nature of light.)
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8
Wavelength and Mass
= wavelength, in m
h = Planck’s constant, 6.626 1034 J s = kg m2 s1
m = mass, in kg
= velocity in m/s
= h
m
de Broglie’s Equationde Broglie’s Equation
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Atomic Spectrum of Hydrogen
Continuous spectrum: Contains all the wavelengths of light.
Line (discrete) spectrum: Contains only some of the wavelengths of light.
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The Bohr Model
E = energy of the levels in the H-atom
z = nuclear charge (for H, z = 1)
n = an integer
E = 2.178 10 J (18 2 z n/ )2
The electron in a hydrogen atom moves around the The electron in a hydrogen atom moves around the nucleus only in certain allowed circular orbits.nucleus only in certain allowed circular orbits.
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11
The Bohr Model
Ground State: The lowest possible energy state for an atom (n = 1).
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12
Energy Changes in the Hydrogen Atom
E = Efinal state Einitial state
= hcE
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13
Quantum Mechanics
Based on the wave properties of the atom
= wave function
= mathematical operator
E = total energy of the atom
A specific wave function is often called an orbital.
H E =
H
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14
Heisenberg Uncertainty Principle
x mvh
4
x = position
mv = momentum
h = Planck’s constant
The more accurately we know a particle’s position, the less accurately we can know its momentum.
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15
Probability Distribution
square of the wave function probability of finding an electron at a given
position
Radial probability distribution is the probability distribution in each spherical shell.
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Figure 7.12Radial Probability Distribution
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Quantum Numbers (QN)
1. Principal QN (n = 1, 2, 3, . . .) - related to size and energy of the orbital.
2. Angular Momentum QN (l = 0 to n 1) - relates to shape of the orbital.
3. Magnetic QN (ml = l to l) - relates to orientation of the orbital in space relative to other orbitals.
4. Electron Spin QN (ms = +1/2, 1/2) - relates to the spin states of the electrons.
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18
Figure 7.13Two Representations of the Hydrogen 1s, 2s, and 3s Orbitals
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Figure 7.14The Boundary Surface
Representations of All Three 2p Orbitals
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20
Pauli Exclusion Principle
In a given atom, no two electrons can have the same set of four quantum numbers (n, l, ml, ms).
Therefore, an orbital can hold only two electrons, and they must have opposite spins.
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21
Figure 7.18 Orbital Energy Levels for the Hydrogen Atom
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Figure 7.20A Comparison of the Radial Probability Distributions of the 2s and 2p Orbitals
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Polyelectronic Atoms
• Shielding
• Hydrogen orbitals: degenerate
• Hydrogenlike orbitals: NOT degenerate!
• Ens < Enp < End < Enf …etc.
• Penetration: e- tunneling
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24
Figure 7.21The Radial Probability Distribution for the 3s, 3p, and 3d Orbitals
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Figure 7.23Mendeleev’s Early Periodic
Table, Published in 1872
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History of the Periodic Table
Dobereiner: triads
Newlands: octaves
Meyer / Mendeleev: arrangements by atomic masses.
Theory → prediction
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27
Aufbau Principle
As protons are added one by one to the nucleus to build up the elements, electrons are similarly added to these hydrogen-like orbitals.
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Hund’s Rule
The lowest energy configuration for an atom is the one having the maximum number of unpaired electrons allowed by the Pauli principle in a particular set of degenerate orbitals.
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29
Figure 7.36Special Names for Groups in the Periodic Table
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Valence Electrons
Atom Valence Electrons
Ca 2
N 5
Br 7
The electrons in the outermost principle The electrons in the outermost principle quantum level of an atom.quantum level of an atom.
Inner electrons are called Inner electrons are called corecore electrons. electrons.
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31
Figure 7.24The Electron Configurations in the Type of
Orbital Occupied Last for the First 18 Elements
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Figure 7.25Electron Configurations for Potassium Through Krypton
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33
Figure 7.26The Orbitals Being Filled for Elements in
Various Parts of the Periodic Table
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Broad Periodic Table Classifications
Representative Elements (main group): filling s and p orbitals (Na, Al, Ne, O)
Transition Elements: filling d orbitals (Fe, Co, Ni)
Lanthanide and Actinide Series (inner transition elements): filling 4f and 5f orbitals (Eu, Am, Es)
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35
Figure 7.27 The Periodic Table With Atomic Symbols, Atomic Numbers, and Partial Electron
Configurations
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36
Figure 7.30The Positions of the Elements
Considered in Sample Exercise 7.7
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37
Ionization Energy
The quantity of energy required to remove one electron from the gaseous atom or ion.
X(g) → X+(g) + e-
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38
Periodic Trends
First ionization energy:
increases from left to right across a period;
decreases going down a group.
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39
Figure 7.31The Values of First Ionization Energy for the
Elements in the First Six Periods
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1s22s22p63s1
1s22s22p6
1s22s22p63s2
Which atom has the largest first I.E.?
Which one has the smallest second I.E.?
Explain.
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41
Electron Affinity
The energy change associated with the addition of an electron to a gaseous atom or ion.
X(g) + e X(g)
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42
Figure 7.33The Electronic Affinity Values for Atoms Among the First 20 Elements that Form
Stable, Isolated X- Ions
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43
Figure 7.35Atomic Radii for Selected Atoms
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44
Periodic Trends
Atomic Radii:
decrease going from left to right across a period;
increase going down a group.
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45
Figure 7.34The Radius of an Atom
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Alkali MetalsExpected trend in reducing ability:
Cs > Rb > K > Na > Li
But in water,
Li > K > Na
Hydration energy
Charge density
What we observe in water:
K > Na > Li