1 / 22

Chapter 14 Liquids & Solids

Chapter 14 Liquids & Solids. 14.1 – Intermolecular Forces. 14.1 - Intermolecular Forces. Intermolecular forces vs. intramolecular forces. 14.1 - Intermolecular Forces. Intermolecular forces vs. intramolecular forces Intramolecular forces = bonds that hold molecules together.

lidia
Download Presentation

Chapter 14 Liquids & Solids

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. Chapter 14Liquids & Solids 14.1 – Intermolecular Forces

  2. 14.1 - Intermolecular Forces Intermolecular forces vs. intramolecular forces

  3. 14.1 - Intermolecular Forces Intermolecular forces vs. intramolecular forces Intramolecular forces = bonds that hold molecules together

  4. 14.1 - Intermolecular Forces Intermolecular forces vs. intramolecular forces Intramolecular forces = bonds that hold molecules together Intermolecular forces = forces that occur between molecules

  5. 14.1 - Intermolecular Forces (3) Types of intermolecular forces discussed in this chapter: • Dipole-dipole attraction

  6. 14.1 - Intermolecular Forces Dipole Dipole Attraction Molecules with dipole moments can attract each other by lining up so that their positive and negative ends are close to each other.

  7. 14.1 - Intermolecular Forces Dipole-dipole attraction

  8. 14.1 - Intermolecular Forces (3) Types of intermolecular forces discussed in this chapter: • Dipole-dipole attraction • Hydrogen bonding

  9. 14.1 - Intermolecular Forces Hydrogen bonding • A type of dipole dipole attraction

  10. 14.1 - Intermolecular Forces Hydrogen bonding • A type of dipole dipole attraction • Stronger than ordinary dipole dipole attractions

  11. 14.1 - Intermolecular Forces Hydrogen bonding • A type of dipole dipole attraction • Stronger than ordinary dipole dipole attractions • Occurs between molecules in which hydrogen is bound to a highly electronegative atome.g. N, O, F

  12. 14.1 - Intermolecular Forces Hydrogen bonding Two reasons why so strong:

  13. 14.1 - Intermolecular Forces Hydrogen bonding Two reasons why so strong: • High polarity

  14. 14.1 - Intermolecular Forces Hydrogen bonding Two reasons why so strong: • High polarity • Close approach of dipoles due to very small size of Hydrogen atom

  15. 14.1 - Intermolecular Forces (3) Types of intermolecular forces discussed in this chapter: • Dipole-dipole attraction • Hydrogen bonding • London dispersion forces

  16. 14.1 - Intermolecular Forces London dispersion forces • Intermolecular attractions formed from temporary dipolar arrangement

  17. 14.1 - Intermolecular Forces London dispersion forces • Intermolecular attractions formed from temporary dipolar arrangement • Form between noble gase and nonpolar moleclese.g. Argon, N2

  18. 14.1 - Intermolecular Forces London dispersion forces

  19. 14.1 - Intermolecular Forces London dispersion forces

  20. 14.1 - Intermolecular Forces London dispersion forces • Weak and short-lived, but can be very significant for large atoms and molecules

  21. 14.1 - Intermolecular Forces London dispersion forces • Weak and short-lived, but can be very significant for large atoms and molecules • Attractions stronger with larger sized atoms because more electrons are available to form dipoles

  22. 14.1 - Intermolecular Forces London dispersion forces • Weak and short-lived, but can be very significant for large atoms and molecules • Attractions stronger with larger sized atoms because more electrons are available to form dipoles • Motions of atoms must be greatly slowed down before the LDF can lock the atoms into place to produce a solid

More Related