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VSEPR MODEL V alence S hell E lectron P air R epulsion Model

VSEPR MODEL V alence S hell E lectron P air R epulsion Model A model for predicting the shapes of molecules and ions in which valence shell electron pairs are arranged about each atom so that electron pair repulsion is minimized. ELECTRONIC GEOMETRY

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VSEPR MODEL V alence S hell E lectron P air R epulsion Model

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  1. VSEPR MODEL Valence Shell Electron Pair Repulsion Model A model for predicting the shapes of molecules and ions in which valence shell electron pairs are arranged about each atom so that electron pair repulsion is minimized. ELECTRONIC GEOMETRY The general shape of a molecule determined by the number of electron pairs around the central atom occupying different quadrants. Gives starting point for bond angle. MOLECULAR GEOMETRY The general shape of a molecule determined by the relative positions of the atomic nuclei. The nonbonding electron pairs modifiy the geometry.

  2. VSEPR MODEL I. Draw the Lewis dot structure. II. Determine the electronic geometry by counting the number of pairs of electrons around the central atom occupying different quadrants (top, bottom, left, right). This geometry gives the initial bond angle. Pairs of e-geometrybond angle 2 linear 180o 3 trigonal planar 120o 4 tetrahderal 109.5o

  3. VSEPR MODEL III. Next, using the electronic geometry, determine the number of bonding and nonbonding electron pairs then arrange the electron pairs as far apart as possible. ___ nonbonding pairs require more space than bonding pairs. ___ multiple bonds require more space than single bonds. IV. The direction in space of the bonding pairs give the molecular geometry modified by the position of the nonbonding pairs.

  4. Fig. 13-1, p. 369

  5. Fig. 13-2, p. 369

  6. Fig. 13-3, p. 370

  7. Table describing Molecular GeometryVSPER Theory Number of electronic bonding nonbonding molecular e- pairs geometry e- pairs e- pairs geometry 2 linear 2 0 linear 3 trigonal planar 3 0 trigonal planar 3 trigonal planar 2 1 bent 4 tetrahedral 4 0 tetrahedral 4 tetrahdral 3 1 trigonal pyramidal 4 tetrahedral 2 2 bent

  8. Fig. 13-4, p. 370

  9. Fig. 13-5, p. 372

  10. Table 13-2, p. 371

  11. p. 374

  12. p. 374

  13. p. 375

  14. p. 375

  15. p. 375

  16. p. 376

  17. Predict the Molecular Geometry for the following molecules. 1. H2O There are 4 pairs of electrons around the central atom so the electronic geometry is tetrahedral with a bond angle of 109.5o. Since 2 of the pairs of electrons are bonding and the other two pairs are nonbonding, the electronic geometry has been modified to a molecular geometry of BENT. 2. CO2 There are four pairs of electrons in two different quadrents (left & right) so the molecular geometry is LINEAR with a bond angle of 180o. . . . . : O = C = O :

  18. Predict the Molecular Geometry for the following molecules. 3. BH3 There are 3 pairs of electrons around the central atom so the electronic geometry is trigonal planar with a bond angle of 120o. Since all three pairs of electrons are bonding, the electronic geometry has not been modified. 4. NH3 There are 4 pairs of electrons around the central atom so the electronic geometry is tetrahedral with a bond angle of 109.5o. Since 3 of the pairs of electrons are bonding and the other pair is nonbonding, the electronic geometry has been modified to a molecular geometry of TRIGONAL PYRAMIDAL.

  19. Practice Problems • Draw the Lewic structure for the following, then predict both the electronic & molecular geometry. Give the approximate bond angle. (See instructor for answers) a) GeH2 b) AsF3 c) AlF3 d) SO2 e) SO3 f) SO32- g) SiF4 h) C2H4 I) Cl2O

  20. Group Study Problems Draw the Lewic structure for the following, then predict both the electronic & molecular geometry. Give the approximate bond angle. a) H2S b) PH3 c) CH2O d) NO2- e) H3PO4 f) CBr4 g) CH2FCl h) C2H2 I) O3

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