Download - Chapter 13 Structure and Shape
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www.cengage.com/chemistry/cracolice
Mark S. CracoliceEdward I. Peters
Mark S. Cracolice • The University of Montana
Chapter 13Structure and Shape
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Drawing Lewis Diagrams
1 Count the total number of valence electrons. If the species is an ion, the number of valence electrons must be adjusted for the charge on the ion.Determine the number of electron pairs.
2 Place the least electronegative atom in the center of
the molecule.
3 Draw a tentative diagram. Place one electron pair between each pair of bonded atoms.
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Drawing Lewis Diagrams
4 Determine the number of lone pairs by subtracting the number of single bonds from the total number of electron pairs available.
5 Starting at the outer atoms, distribute the available lone pair electrons to complete the octet around each atom except hydrogen which requires a duet.
6 If there are not enough electrons to complete all octets, move one or more lone pairs from an outer atom to form a double or triple bond with the central atom until all atoms have an octet.
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Drawing Lewis Diagrams
Example: Draw the Lewis diagram for carbon tetrafluoride.
First, count valence electrons.CF4: 4 (C) + 4 × 7 (F) = 32 valence electronsThere are 16 electron pairs
Second, determine the central atom by comparing electronagativity
EN of C < EN of F, so C is central
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Drawing Lewis Diagrams
Draw a tentative diagram with all single bonds and lone pairs..
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Drawing Lewis Diagrams
Check
Carbon has an octet (4 bonding pairs = 8 electrons)Each fluorine has an octet (one bonding pair and three
lone pairs)
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Valence Shell Electron-Pair Repulsion Theory, VSEPR.
Electron pairs repel one another.
Therefore they distribute themselves in positions around a central atom that are as far away from each
other as possible.
These are the locations of lowest potential energy.
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Electron-Pair Geometry
1. Count the number of lone electron pairs and the number of bonding electron pairs around the central atom. The total number of electron pairs is called the steric number, SN.
2. Distribute the electrons pairs in positions that are far away from each other as possible. These are the locations of lowest energy.
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Electron-Pair Geometry
Electron-Pair GeometryArrangement of regions of electron density
(electron pairs) around a central atom in a molecule.
Electron-Pair AngleThe geometric angle formed by any two
electron pairs and the central atom.
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Electron-Pair Geometry a. The central atom has two electron pairs the electron pair
geometry is linear. The electron pair angle is 1800
b. The central atoms is surrounded by three electron pairs. The geometry is trigonal planar. The electron pair angle is 1200
c. The central atom is surrounded by four electron pairs, The geometry is tetrahedral, and the electron pair angle is 109.50
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Molecular Geometry
Molecular GeometryArrangement of atoms around a central atom in
a molecule.
Molecular geometry follows from electron-pair geometry.
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Molecular Geometry: BeF2
Regions of electron density: 2Electron-pair geometry: Linear
Regions bonded: 2Molecular geometry: Linear
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Molecular Geometry: BF3
Regions of electron density: 3Electron-pair geometry: Trigonal planar
Regions bonded: 3Molecular geometry: Trigonal planar
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Molecular Geometry: SO2
Regions of electron density: 3Electron-pair geometry: Trigonal planar
Regions bonded: 2Molecular geometry: Angular
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Molecular Geometry: CH4
Regions of electron density: 4Electron-pair geometry: Tetrahedral
Regions bonded: 4Molecular geometry: Tetrahedral
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Molecular Geometry: NH3
Regions of electron density: 4Electron-pair geometry: Tetrahedral
Regions bonded: 3Molecular geometry: Trigonal pyramidal
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Molecular Geometry: H2O
Regions of electron density: 4Electron-pair geometry: Tetrahedral
Regions bonded: 2Molecular geometry: Bent
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Molecular Geometry
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Molecular GeometryConventions Used for Drawing Wedge-and-Dash Diagrams
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Polarity of Molecules
Polar MoleculeA molecule in which there is an
asymmetrical distribution of charge.
Nonpolar moleculeA molecule in which there is a symmetrical distribution
of charge.
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Polarity of Molecules
In an electric field, polar molecules are oriented with the positive end toward the direction of the field.
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Polarity of Molecules
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Polarity of Molecules
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Homework• Prepare Exercise B