Transcript III. Quantum Model of the Atom

Ch. 4 - Electrons in Atoms
III. Quantum
Model
of the Atom
(p. 98 - 104)
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A. Electrons as Waves
Louis de Broglie (1924)
Applied wave-particle theory to ee- exhibit wave properties
QUANTIZED WAVELENGTHS
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A. Electrons as Waves
EVIDENCE: DIFFRACTION PATTERNS
ELECTRONS
VISIBLE LIGHT
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B. Quantum Mechanics
Heisenberg Uncertainty Principle
Impossible to know both the velocity
and position of an electron at the same
time
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B. Quantum Mechanics
Orbital (“electron cloud”)
Region in space where there is 90%
probability of finding an e-
Orbital
Radial Distribution Curve
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C. Quantum Numbers
Four Quantum Numbers:
Specify the “address” of each electron
in an atom
UPPER LEVEL
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C. Quantum Numbers
1. Principal Quantum Number ( n )
Energy level
Size of the orbital
n2 = # of orbitals in
the energy level
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C. Quantum Numbers
2. Angular Momentum Quantum # ( l )
Energy sublevel
Shape of the orbital
s
p
d
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f
C. Quantum Numbers
3. Magnetic Quantum Number ( ml )
Orientation of orbital
Specifies the exact orbital
within each sublevel
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C. Quantum Numbers
px
py
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pz
C. Quantum Numbers
Orbitals combine to form a spherical
shape.
2s
2px
2py
2pz
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C. Quantum Numbers
4. Spin Quantum Number ( ms )
Electron spin  +½ or -½
An orbital can hold 2 electrons that spin
in opposite directions.
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C. Quantum Numbers
Pauli Exclusion Principle
No two electrons in an atom can have
the same 4 quantum numbers.
Each e- has a unique “address”:
1. Principal #
2. Ang. Mom. #
3. Magnetic #
4. Spin #




energy level
sublevel (s,p,d,f)
orbital
electron
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Feeling overwhelmed?
Read
Section 4-2!
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