Presentation is loading. Please wait.

Presentation is loading. Please wait.

Ionic – Bonding and Crystal Structure. Valence and Lewis Bond Theory metals and non-metals exchange electrons eg. Na 2 O O [He]    2s 2 2p 4 Na [Ne]

Published byJasper Blair Modified over 8 years ago

Similar presentations

Presentation on theme: "Ionic – Bonding and Crystal Structure. Valence and Lewis Bond Theory metals and non-metals exchange electrons eg. Na 2 O O [He]    2s 2 2p 4 Na [Ne]"— Presentation transcript:

1 Ionic – Bonding and Crystal Structure

2 Valence and Lewis Bond Theory metals and non-metals exchange electrons eg. Na 2 O O [He]    2s 2 2p 4 Na [Ne]  3s 1 Na [Ne]  3s 1 2 Na 1+ [Ne] 3s 0 O 2- [He]  2s 2 2p 6

3 Crystal Structures Ions are viewed as hard spheres. The packing pattern adopted provides the greatest energy stability. The packing pattern is:   the larger ion creates the overall frame

4  the smaller ion is placed in the “holes” created by the frame  the type of frame depends on the ratio of the radii of the two ions

5 Predicting Crystal Structures General “rules” have been developed, based on unit cell geometry, to predict crystal structures using ionic radii. Radius ratios, usually expressed as the (radius of the anion)/(radius of the cation) are used. CNr - /r + Hole/packing 81.0 – 1.37body centered packing 61.37 – 2.44octahedral holes 42.44 – 4.55tetrahedral holes

6 Body Centered Ionic crystal Occurs when the ion sizes are very similar. The smaller ion fits in the center of a cube formed by 8 opposite ions.

7 Holes in Close Packed Crystals Octahedral holes lie within two staggered triangular planes of ions There are 2 types of holes created Tetrahedral holes lie within a triangular plane with another ion on top

8 Octahedral Holes The coordination number of these ions is 6. # n ions = n holes.

9 Tetrahedral Holes The coordination number of these ions is 4 # n ions = 2n tetrahedral holes.

10 Ionic Compounds Since anions are often larger than cations, ionic structures are often viewed as a close-packed array of anions with cations added, and sometimes distorting the close-packed arrangement. Common examples:

11 1. Rock Salt (NaCl) Is viewed as an array of the anions, with the cations in all of the octahedral holes, or The other way around – depending on which is larger The coordination number is 6 for both ions.

12 2. The CsCl structure Chloride ions occupy the corners of a cube, with a cesium ion in the center or vice versa. Both ions have a coordination number of 8, with the two ions fairly similar in size.

13 3. The Zinc-blende or Sphalerite structure- Anions (S 2- ) ions are in the frame with cations (Zn 2+ ) in half of the tetrahedral holes.

14 4. The Fluorite (CaF 2 ) and Antifluorite structures A frame of Ca 2+ ions with F - ions in all of the tetrahedral holes.

Download ppt "Ionic – Bonding and Crystal Structure. Valence and Lewis Bond Theory metals and non-metals exchange electrons eg. Na 2 O O [He]    2s 2 2p 4 Na [Ne]"

Similar presentations

Objectives By the end of this section you should:

Objectives By the end of this section you should:
Lecture 4 (9/18/2006) Crystal Chemistry Part 3: Coordination of Ions Pauling’s Rules Crystal Structures.

Lecture 4 (9/18/2006) Crystal Chemistry Part 3: Coordination of Ions Pauling’s Rules Crystal Structures.
Crystals.

Crystals.
Introduction to Mineralogy Dr. Tark Hamilton Chapter 4: Lecture 10 The Chemical Basis of Minerals (coordination polyhedra & lattice energy) Camosun College.

Introduction to Mineralogy Dr. Tark Hamilton Chapter 4: Lecture 10 The Chemical Basis of Minerals (coordination polyhedra & lattice energy) Camosun College.
Unit Cell of Crystal Structure

Unit Cell of Crystal Structure
BONDING Ch 7& 8 – Honors Chemistry General Rule of Thumb: metal + nonmetal = ionic polyatomic ion + metal or polyatomic ion = ionic (both) nonmetal + nonmetal(s)

BONDING Ch 7& 8 – Honors Chemistry General Rule of Thumb: metal + nonmetal = ionic polyatomic ion + metal or polyatomic ion = ionic (both) nonmetal + nonmetal(s)
Metal atoms with low ionization energies and non-metal atoms with high electron affinity form cations (+) and anions (-) Oppositely charged ions attract.

Metal atoms with low ionization energies and non-metal atoms with high electron affinity form cations (+) and anions (-) Oppositely charged ions attract.
Ionic Bonding. CA Standards  Students know atoms combine to form molecules by sharing electrons to form covalent or metallic bonds or by exchanging electrons.

Ionic Bonding. CA Standards  Students know atoms combine to form molecules by sharing electrons to form covalent or metallic bonds or by exchanging electrons.
Solids Ch.13. Solids Fixed, immobile (so to speak) Fixed, immobile (so to speak) Symmetry Symmetry Crystals Crystals So what’s the inner order? So what’s.

Solids Ch.13. Solids Fixed, immobile (so to speak) Fixed, immobile (so to speak) Symmetry Symmetry Crystals Crystals So what’s the inner order? So what’s.
Explaining Vapor Pressure on the Molecular Level Some of the molecules on the surface of a liquid have enough energy to escape the attraction of the bulk.

Explaining Vapor Pressure on the Molecular Level Some of the molecules on the surface of a liquid have enough energy to escape the attraction of the bulk.
Metallic –Electropositive: give up electrons Ionic –Electronegative/Electropositive Colavent –Electronegative: want electrons –Shared electrons along bond.

Metallic –Electropositive: give up electrons Ionic –Electronegative/Electropositive Colavent –Electronegative: want electrons –Shared electrons along bond.
L03C: Chapter 3 (Continued) Inorganic Compounds Reminder: Bonding ranges from ionic to covalent depending on relative electronegativity of constituents.

L03C: Chapter 3 (Continued) Inorganic Compounds Reminder: Bonding ranges from ionic to covalent depending on relative electronegativity of constituents.
Factors affecting metallic bond strength Metallic crystal structures

Factors affecting metallic bond strength Metallic crystal structures
Metallic –Electropositive: give up electrons Ionic –Electronegative/Electropositive Colavent –Electronegative: want electrons –Shared electrons along bond.

Metallic –Electropositive: give up electrons Ionic –Electronegative/Electropositive Colavent –Electronegative: want electrons –Shared electrons along bond.
Ceramics Term ceramics comes from the greek word keramikos – “burnt stuff” Ceramics are typically formed during high temperature heat treating – “Firing”

Ceramics Term ceramics comes from the greek word keramikos – “burnt stuff” Ceramics are typically formed during high temperature heat treating – “Firing”
Crystalline Structures Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.

Crystalline Structures Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.
Chemical Bonding: The Ionic Bond Model. Chemical Bonds Forces that hold atoms to each other within a molecule or compound.

Chemical Bonding: The Ionic Bond Model. Chemical Bonds Forces that hold atoms to each other within a molecule or compound.
Crystalline Structures Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.

Crystalline Structures Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.
Crystalline Structures Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.

Crystalline Structures Edward A. Mottel Department of Chemistry Rose-Hulman Institute of Technology.
Structure of Solids Objectives

Structure of Solids Objectives

Similar presentations

Ads by Google