Bonding Thermodynamics: why reactions occur Kinetics:

Slides:

Advertisements

Similar presentations

Unit 5B: Covalent Bonding

Advertisements

Lewis Dot Structures and Molecular Geometry

SHAPES OF MOLECULES. REMINDER ABOUT ELECTRONS  Electrons have negative charges  Negative charges “repel” each other  In molecules, electrons want to.

-Types of Covalent Bonds -Rules for Writing Lewis Dot Structures of Molecular Compounds Chemistry Mrs. Coyle.

Covalent Bonding The joining of two or more elements through the sharing of valance electrons to form a molecule Purpose: To form a stable octet between.

Molecular Geometry And Polarity.

Molecular Structures Chapter 9

Chapter 11: Chemical Bonding Chemistry 1020: Interpretive chemistry Andy Aspaas, Instructor.

Chemical Bonding Bonding within a molecule is called intramolecular attraction –Ionic bonds –Covalent bonds –Polar covalent bonds.

Covalent Bonds – Valence Bond (Localized e - ) Model A covalent bonds is the intra-molecular attraction resulting from the sharing of a pair of electrons.

Chapter 11: Chemical Bonding Chemistry 1020: Interpretive chemistry Andy Aspaas, Instructor.

Polarity Chapter 6.1. Review A covalent bond is formed between two non-metals. Electrons are shared. Orbitals are overlapping.

Chapter 8 Molecular Shape The shape of a molecule can be important in determining its chemical reactions Molecular shape is often very important in the.

Writing Lewis Structures of Molecules 1.Determine the central atom (atom in the middle) - usually is the “single” atom - least electronegative element.

Molecular Geometry. 2-D and 3-D Lewis Structures explain the two dimensional structure of molecules In order to model the actual structure of a molecule.

Section 12.1 Characteristics of Chemical Bonds 1.To learn about ionic and covalent bonds and explain how they are formed 2.To learn about the polar covalent.

CHAPTER 4 Covalent Molecules General, Organic, & Biological Chemistry Janice Gorzynski Smith.

Bonding Where the magic of chemistry takes place!.

Chemistry Unit 4 Chapter 8.  Molecule  A neutral group of atoms joined together by covalent bonds  Molecular Compound  Tend to have lower melting.

Lewis Structures, VSPER, Electron Domain and Molecular Geometry, Hybridization.

4.6 Quantum Mechanics and Bonding: Hybridization.

Types of chemical bonds

Chapter 9 Molecular Shape.

Chapter 5. Covalent Compounds (Molecular Compounds)

Molecular Geometry Lewis Structures VSEPR Theory

Chapter 12 Chemical Bonding.

6.8 Shapes and Polarity of Molecules

CHEMICAL BONDING Cocaine Chemistry I – Chapter 8

Lewis Structure Shows how valence electrons are arranged among atoms in a molecule. Reflects central idea that stability of a compound relates to noble.

Section 4: Molecular Shapes

Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals Chapter 9 Copyright © The McGraw-Hill Companies, Inc. Permission required.

Molecular Geometry Cocaine

Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals Chapter 10 Copyright © The McGraw-Hill Companies, Inc. Permission required.

Bond Polarity and Molecular Geometry

7.10 – NOTES Shapes for Covalent Structures

CHEMICAL BONDING Cocaine

Unit 4: Covalent Bonding

Chemical Bonding and VSEPR

Molecular Shapes Lewis structures physical properties VSEPR

Covalent Bonds Covalent bond is a bond formed when 2 electrons are shared between atoms H + H forms H2 Lewis Structure of H2 Lewis Structure of F2 A lone.

Lewis Structures & VSEPR

Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals Chapter 9 Copyright © The McGraw-Hill Companies, Inc. Permission required.

Valence shell electron pair repulsion (VSEPR) model:

Localized Electron Model

Real Molecule Shapes Any molecule containing only 2 atoms has a linear shape. To predict shapes of molecules with more than 2 atoms we use VESPR theory.

A. Types of Chemical Bonds

GEOMETRY AND POLARITY OF MOLECULES

Drawing Lewis Structures

7.7 – NOTES Shapes for Covalent Structures

Which of the following molecules does

Chapter 11 Chemical Bonding.

V. Lewis Dot Diagrams for Double & Triple Bonds + Polyatomic Ions

Bonding Thermodynamics: why reactions occur Kinetics:

Molecular Structure and Shape

ChemicalBonding Honors Only Problems and questions —

CHEMICAL BONDING Cocaine Chemistry I – Chapter 8

Molecular shapes.

CHEMICAL BONDING By Mrs. Idha Nurhayati, SPd. Cocaine

Bonding Thermodynamics: why reactions occur Kinetics:

Bonding: General Concepts

CHEMICAL BONDING Cocaine Chemistry I – Chapter 8

CHEMICAL BONDING Cocaine Chemistry I – Chapter 8

Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals Chapter 10 Copyright © The McGraw-Hill Companies, Inc. Permission required.

Bonding Thermodynamics: why reactions occur Kinetics:

Bonding Thermodynamics: why reactions occur Kinetics:

Chapter 8 Molecular Compounds.

CHEMICAL BONDING Cocaine Chemistry I – Chapter 8

Polar and Non-polar Covalent Bonds

Molecular Shapes.

CHEMICAL BONDING Cocaine Chemistry I – Chapter 8

Presentation transcript:

Bonding Thermodynamics: why reactions occur Kinetics: how reactions occur Organic chemistry: chemistry of carbon chemistry of life Bonding Lewis dot structures: valence e- used in bonding # valence e- = group # “noble gas” = 8 valence e-

Lewis structures CH3OH 1. Determine # valence e- element group number e- C IV 4 H I 1 O VI 6 2. Place least electronegative element in center (never H)

non-polar covalent  0.4 polar covalent 0.5-1.8 NaCl = 3.0 - 0.9 = 2.1 ionic Cl-Cl = 3.0 - 3.0 = 0.0 covalent C-O = 3.5 - 2.5 = 1.0 polar covalent C-H = 2.5 - 2.1 = 0.4 covalent

Lewis structures 1. Determine # valence e- 2. Place least electronegative element in center (never H) C 3. Make single bond (2e-) between each pair of atoms 4. Use remaining e- to satisfy octet rule 5. Use double or triple bonds to reduce # of unshared e-

Lewis structures : : : : : : : CH3OH C H O valence e- 4 4 6 14 e- H H

Lewis structures formal charge COCl2 C O Cl valence e- 4 6 14 24 e- .. 7 - 4 - 2 = +1 .. .. .. .. O .. .. 6 - 6 - 1 = -1 .. C O Cl 7 - 6 - 1 = 0 .. 6 - 4 - 2 = 0 group number - unshared e- - (1/2) shared e-

VSEPR Molecular geometries : H2O : : H O H : 4 - : H2O : : H O H + + : 4 pairs of valence e- on O tetrahedron bonds angles 109.5o actually 108o polar bonds dipole moment H-bonding H bound to O, N, F = H-bond donor O, .. N, .. .. F = H-bond acceptor

VSEPR Molecular geometries : CH2O : : H C H : : : O : 3 + : CH2O : : H C H : : : O : - 3 pairs of e- on C trigonal planar bonds angles 120o polar bond dipole moment dipole-dipole

VSEPR Molecular geometries : : CO2 : : : : : : O C O : : + : CO2 : : : : : : O C O : : - - 2 bonding pairs of e- on C linear bonds angles 180o polar bonds no dipole moment LDF

: H2O : : H O H : O ___ s electrons ___ p electrons 2 4 equivalent orbitals 4 Hybridization atomic orbitals s p s p 3 -bond molecular orbitals

H : C : H CH2O : : : : O C ___ s electrons ___ p electrons 2 3 equivalent orbitals 2 Hybridization atomic orbitals s p p -bond sp2 -bond molecular orbitals

H : C : H CH2O : : : : O O ___ s electrons ___ p electrons 2 3 equivalent orbitals 4 Hybridization atomic orbitals s p p -bond sp2 -bond molecular orbitals

: : CO2 : : : : O C O : : C ___ s electrons ___ p electrons 2 2 equivalent orbitals 2 Hybridization atomic orbitals s p p -bond sp -bond molecular orbitals

: : CO2 : : : : O C O : : O ___ s electrons ___ p electrons 2 3 equivalent orbitals 4 Hybridization atomic orbitals s p p -bond sp2 -bond molecular orbitals