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Ch. 9 Molecular Geometry & Bonding Theories

Ch. 9 Molecular Geometry & Bonding Theories. Lewis structures tell us which atoms are bonded together, but we will now explore the geometric shapes of these molecules. Overall shape is determined by bond angles. Bond angles are determined by the VSEPR theory .

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Ch. 9 Molecular Geometry & Bonding Theories

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  1. Ch. 9 Molecular Geometry & Bonding Theories Lewis structures tell us which atoms are bonded together, but we will now explore the geometric shapes of these molecules. Overall shape is determined by bond angles. Bond angles are determined by the VSEPR theory. Electrons repel & will try to get as far away from each other as possible Nonbonded electron pairs take up more space than bonded electrons. You must determine the # of electron domains on the central atom. An electron domain is a region of electrons that are either bonded or non-bonded (lone pairs). A double or triple bond only counts as one domain.

  2. Electron Domain Geometry The arrangement of electron domains about the central atom of an ABn molecule is its electron-domain geometry. There are five different electron-domain geometries: linear --(2 electron domains) trigonal planar --(3 domains) tetrahedral --(4 domains) trigonal bipyramidal --(5 domains) octahedral --(6 domains).

  3. VSEPR – Valence Shell Electron Pair Repulsion A = central atom X = atoms bonded to A E = nonbonding electron pairs on A

  4. Electron Domain Geometry

  5. For example… :O=C=O: • There are 2 electron domains on carbon…Its shape must therefore be linear. • H–O–H • There are 4 electron domains on oxygen….Its shape is based on the tetrahedral. • Next, we will look at the molecular geometry! Electron Domain Geometry .. ..

  6. The molecular geometry is the arrangement of the atoms in space. To determine the shape of a molecule we will distinguish between bonding pairs and lone pairs. • Count the # of bonding domains vs. nonbonding domains. • H-O-H Oxygen has 2 bonding and 2 nonbonding domains • With this information, we can determine the molecular geometry…bent (as we know already!) Molecular Geometry .. ..

  7. Molecular Geometry

  8. Molecular Geometry

  9. Molecular Geometry

  10. According to VSEPR theory, if there are three electron domains in the valence shell of an atom, they will be arranged in a(n) _____ geometry • A. octahedral • B. linear • C. tetrahedral • D. trigonal planar • E. trigonal bipyramidal

  11. The electron-domain geometry of the central atom in OF2 is _________. • linear • trigonal planar • tetrahedral • trigonal bipyramidal

  12. The most common shapes we deal with are as follows: • Tetrahedral, pyramidal, bent, linear, and trigonal planar. • ( • The “ideal” bond angle between the central atom and the other atoms should be noted… • Linear= 180º • Tetrahedral = 109.5º • Trigonal Planar =120º • Due to the lone pairs of electrons on pyramidal and bent shapes, the ideal bond angles will be less than 109.5º Molecular Geometry—Most Common Shapes

  13. In general, multiple bonds repel more as do lone pairs. Molecular Geometry— e- repulsion

  14. When there is a difference in electronegativity between two atoms, then the bond between them is polar. • It is possible for a molecule to contain polar bonds, but not be polar. • -For example, the bond dipoles in CO2 cancel each other because CO2 is linear. Molecular Shape and Molecular Polarity

  15. In water, the molecule is not linear and the bond dipoles do not cancel each other. Therefore, water is a polar molecule. Molecular Shape and Molecular Polarity

  16. The overall polarity of a molecule depends on its molecular geometry. Molecular Shape and Molecular Polarity

  17. Bonds form when orbitals on atoms overlap. • There are two electrons of opposite spin in the overlapping orbitals. Why do bonds form?

  18. The overlapping of the orbitals will lower the overall energy of the 2 atoms, therefore it is more stable. Why do bonds form?

  19. A hybrid orbital is simply a mixing of different orbitals together to form a new “hybridized orbital”. • We need the concept of hybrid orbitals to explain molecular shapes. (Let’s try to keep it simple…) • When you mix n atomic orbitals we must get n hybrid orbitals. Hybrid Orbitals • Example: If you mix one “s” orbital and three “p” orbitals you will get four “sp3” hybrid orbitals that all have exactly the same energies.

  20. Hybrid Orbitals The # of electron domains on the atom will indicate the hybridization needed. Example: H2C=CH2 (Carbon has 3 e- domains so its hybridization must be sp2 which has 3 hybrid orbital domains as well.)

  21. Overlapping orbitals come in 2 varieties… • -Bonds: electron density lies on the axis between the nuclei. • - All single bonds are -bonds. Sigma and Pi Bonds

  22. -Bonds: electron density lies above and below the plane of the nuclei. • -A double bond consists of one -bond and one -bond. • -A triple bond has one -bond and two - bonds. Sigma and Pi Bonds Often, the p-orbitals involved in -bonding come from unhybridized orbitals. A total of 5 -bonds are formed from the overlapping sp2 hybrid orbitals of carbon, and the -bond is from the unhybridized overlapping p-orbitals on each carbon. H2C=CH2

  23. H2C=O Sigma and Pi Bonds C and O both have sp2 hybridization and each has an unhybridized p-orbital available to make the -bond portion of the double bond. H–C≡C–H In this case, C has sp hybridization. One -bond and two -bonds form the triple bond between the carbon atoms.

  24. Simply put, if there are resonance structures, the -bond is delocalized or “smeared” between the 2 resonance structures. (By the way, -bonds are never delocalized!) • Example: Benzene (C6H6) Delocalized Pi Bonds

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