I' Covalent Bonds and Reactions - PowerPoint PPT Presentation

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I' Covalent Bonds and Reactions

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A Model is a simple explanation that lets us explain complicated things ... Chloroform (CH3Cl) Total E = 1578 kJ/mol. We can use C-H value ... – PowerPoint PPT presentation

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Title: I' Covalent Bonds and Reactions


1
I. Covalent Bonds and Reactions
  • Covalent Bond Model
  • A Model is a simple explanation that lets us
    explain complicated things
  • Chemical Bonds are a model that help us explain
    why groups of atoms behave as a unit in reactions
  • Chemical Bond forms only if that arrangement is
    more stable
  • Chemical Bond Energy energy gained by behaving
    as a unit
  • Examples
  • Methane (CH4)
  • a. 4 C-H covalent bonds arranged in a tetrahedral
    shape
  • b. The total energy of methane is 1652 kJ/mol
  • c. We can estimate any C-H bond as being 413
    kJ/mol
  • Chloroform (CH3Cl)
  • Total E 1578 kJ/mol
  • We can use C-H value
  • C-Cl bond E 339 kJ/mol 1578 - 3(413) 339

2
  • Other bond energies
  • Every C-H bond is not exactly 413 kJ/mol, but we
    estimate as such
  • Other X-Y bond strengths have been estimated
  • Single bond 2 atoms share one pair of e- (C-H)
  • Double bond 2 atoms share 2 pairs of e-
    stronger than single bond
  • CO 745, C-O 358
  • Triple bond 2 atoms share 3 pairs of e- even
    stronger
  • C?O 1072
  • Bond length shortens as more e- are shared
    between the atoms
  • Calculation Enthalpy of a Reaction
  • Enthalpy DH sum of energy to break and form
    bonds in a reaction
  • a. Bond breaking requires energy (endothermic).
  • Bond formation releases energy (exothermic).
  • ?H ?D(bonds broken) ? ?D(bonds formed)

energy required
energy released
3
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4
  • Find DH for 1 H2 1 F2
    2 HF
  • 1(432 kJ/mol) 1(154 kJ/mol) 2(565 kJ/mol)
    -544 kJ/mol DH
  • 3. Sample Ex. 8.5 CH4 2Cl2 2F2 ----gt
    CF2Cl2 2HF 2HCl
  • II. Lewis Structures
  • Localized Electron Bonding Model
  • A molecule is composed of atoms that are bound
    together by sharing pairs of electrons using the
    atomic orbitals of the bound atoms.
  • Pairs of e- are either
  • Shared in a bond (bonding pair)
  • Localized on a single atom (lone pair)
  • Duet and Octet Rules are in effect most stable
    form of any atom
  • Lewis Structures
  • Uses and to show arrangement of valence
    electrons in a molecule
  • Ionic Compounds are straightforward

5
  • Covalent Compounds
  • Shared electrons count for both atoms
  • A line stands for one pair of electrons
  • Rules for drawing Lewis structures
  • Add up total valence e- for all atoms CH4
    4x1 4 8 e-
  • Use one pair for each bond
  • Arrange leftover e- to satisfy octet/duet
  • Examples CCl4, CO2, H2O and Sample Ex. 8.6 N2,
    NH3, CF4, NO

6
  • 4. Exceptions to the Octet Rule
  • a. 2nd row elements C, N, O, F always observe
    the octet rule.
  • b. 2nd row elements B and Be (have very small
    size) often have fewer than 8 electrons around
    themselves - they are very reactive.
  • c. 3rd row and heavier elements CAN exceed the
    octet rule using empty valence d orbitals.
  • d. When writing Lewis structures, satisfy octets
    first, then place electrons around elements
    having available d orbitals.
  • e. Sample Ex. 8.7 and 8.8 PCl5, ClF3, RnCl2

7
  • 5. Formal Charge
  • a. The difference between the number of valence
    electrons (VE) on the free atom and the number
    assigned to the atom in the molecule.
  • b. We need
  • a. VE on free neutral atomfrom its group
    in periodic table
  • b. VE belonging to the atom in the
    molecule
  • One e- for each bond
  • All the lone pairs electrons
  • c. Examples
  • i. NO
  • ii. NO2-
  • iii. CO2

8
  • III. Resonance Forms multiple correct Lewis
    structures for a given molecule
  • A. Example NO3-
  • B. Rules
  • 1. Bracket the set of structures and separate
    with ??
  • 2. Only electron pairs move to interconvert
    atoms dont move
  • Electron Pushing
  • C. Resonance Hybrids The true structure is a
    mixture of all resonance forms
  • 1. Every resonance form contributes to the
    overall structure
  • 2. None of the resonance forms are true
    pictures of the structure
  • The real structure is not interconverting between
    resonance structures, but is a composite all of
    them, all of the time
  • Sample Ex. 8.9 NO2-

9
  • IV. VSEPR Valence Shell Electron-Pair Repulsion
  • Electron pairs want to be as far apart from one
    another as possible
  • This applies to bonding pairs and lone pairs
    alike
  • Steps in Applying VSEPR
  • Draw the Lewis Structure
  • Count atoms and lone pairs and arrange them as
    far apart as possible
  • Determine the name of the geometry based only on
    where atoms are

10
  • B. Complications to VSEPR
  • Lone pairs count for arranging electrons, but not
    for naming geometry
  • Example NH3 (ammonia)
  • Lone pairs are larger than bonding pairs,
    resulting in adjusted geometries
  • Bond angles are squeezed to accommodate lone
    pairs

Trigonal pyramidal
Tetrahedral
11
  • b. Lone pairs must be as far from each other as
    possible
  • 4. Double and triple bonds are treated as only 1
    pair of electrons

12
5. Names for and examples of complicated VSEPR
Geometries
linear
trigonal planar
bent
trigonal pyramidal
tetrahedral
bent
T-shaped
linear
trigonal bipyramidal.
see-saw
square pyramidal
octahedral
square planar
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