1 / 15

VSEPR Theory and Molecular Geometries

VSEPR Theory and Molecular Geometries. VSEPR Theory. VSEPR (pronounced “vesper”) stands for: V alence S hell E lectron P air R epulsion It attempts to explain the 3-D shapes of molecules. How do we know what molecules look like? X-Ray Crystallography

Download Presentation

VSEPR Theory and Molecular Geometries

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. VSEPR Theory and Molecular Geometries

  2. VSEPR Theory • VSEPR (pronounced “vesper”) stands for: • Valence Shell Electron Pair Repulsion • It attempts to explain the 3-D shapes of molecules. • How do we know what molecules look like? • X-Ray Crystallography • X-rays are fired through a crystallized sample of a substance and are diffracted in many directions. • By carefully studying the directions and intensity of the diffracted X-rays, a crystallographer can tell a lot about the locations of atoms within the crystal. • Remember, theories explain observations! • VSEPR Theory explains the observed shapes of molecules.

  3. X-Ray Crystallography

  4. VSEPR Theory • The basic principles of VSEPR Theory: • Electron pairs repel each other. • Electron pairs in molecules tend to arrange themselves so as to minimize the repulsion between them. • In other words, get as far apart as possible.

  5. The Geometry of CH4 • Based on the Lewis structure of methane, you might expect the geometry on the left. • VSEPR theory predicts the geometry on the right. • The geometry on the right is confirmed by observations. H 90º 109.5º H C H H The spheres represent the centers of the carbon and hydrogen atoms.

  6. VSEPR Formulas • Lewis structures do not show geometry, only electron pair placement. • However, the 3-D shape (geometry) of a molecule can be determined from a properly-drawn Lewis structure. • All monocentric molecules can be represented by a VSEPR formula: • AXE • A = central atom • X = outer atoms (doesn’t matter what they actually are or how many bonds they are held by) • E = lone pairs of electrons on the central atom only.

  7. VSEPR Formulas • What VSEPR formula corresponds to the chlorate ion, ClO3-1? • First draw a proper Lewis structure: • Needed = 32 • Available = 26 • Shared = 6 • One central atom, three outer atoms, one lone pair: • AX3E -1 O Cl O O

  8. VSEPR Formulas • What VSEPR formula corresponds to sulfur trioxide, SO3? • Draw a Lewis structure. • Needed = 32 • Available = 24 • Shared = 8 • 1 central atom, 3 outer atoms, no lone pairs: • AX3 O S O O

  9. Molecular Geometries • Each VSEPR formula corresponds to a certain molecular geometry. • There are six possible geometries for molecules whose central atoms obey the octet rule.

  10. Molecular Geometries • VSEPR Formula: AX2 • Geometry: Linear • Bond Angle: 180º • Example: CO2 O C O

  11. Molecular Geometries • VSEPR Formula: AX3 • Geometry: Trigonal Planar • Bond Angle: 120º • Example: SO3 O O S O

  12. Molecular Geometries • VSEPR Formula: AX4 • Geometry: Tetrahedral • Bond Angle: 109.5º • Example: CCl4 Cl Cl C Cl Cl

  13. Molecular Geometries • VSEPR Formula: AX2E • Geometry: Bent (Angular) • Bond Angle: Less than 120º • Example: SO2 O S O

  14. Molecular Geometries • VSEPR Formula: AX3E • Geometry: Trigonal Pyramidal • Bond Angle: Less than 109.5º • Example: NH3 H H N H

  15. Molecular Geometries • VSEPR Formula: AX2E2 • Geometry: Bent (Angular) • Bond Angle: Less than 109.5º • Example: H2O H O H

More Related