© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.1 Redraw each structure to get the electron groups as far apart.

Slides:

Advertisements

Similar presentations

Chemical Bonding and VSEPR L. Scheffler IB Chemistry 1-2 Lincoln High School 1.

Advertisements

1 Chapter 4 Compounds and Their Bonds 4.7 Shapes and Polarity of Molecules Copyright © 2005 by Pearson Education, Inc. Publishing as Benjamin Cummings.

General, Organic, and Biological Chemistry Fourth Edition Karen Timberlake 5.8 Shapes and Polarity of Molecules Chapter 5 Compounds and Their Bonds © 2013.

Chapter 4 Compounds and Their Bonds 4.7 Shapes and Polarity of Molecules 1 Chemistry: An Introduction to General, Organic, and Biological Chemistry, Eleventh.

V alence S hell E lectron P air R epulsion Theory Planar triangular Tetrahedral Trigonal pyramidal Bent.

Chemical Bonds.

Copyright © Houghton Mifflin Company. All rights reserved. 12 | 1 Chemical Bonds Forces that hold atoms together Ionic bonds: the forces of attraction.

 Water molecule dipole moment.  The polarity of water affects its properties –Causes water to remain liquid at higher temperature –Permits ionic compounds.

Covalent compounds A covalent compound consists of two or more nonmetals. They are able to bond together by sharing their valence electrons.

Chapter 10 Properties of Solids and Liquids

Copyright ©2009 by Pearson Education, Inc. Upper Saddle River, New Jersey All rights reserved. Introductory Chemistry, Third Edition By Nivaldo J.

Forces that hold atoms together.  There are several major types of bonds. Ionic, covalent and metallic bonds are the three most common types of bonds.

Chapter 4 Compounds and Their Bonds

Chapter 10 Properties of Solids and Liquids (Molecular Structures)

Chapter 5 Compounds and Their Bonds

BONDING AND GEOMETRY Unit 8 Chemistry.

Chapter 8 Covalent Bonding. The Covalent Bond Atoms will share electrons in order to form a stable octet. l Covalent bond : the chemical bond that results.

Chapter 6 Preview Objectives Molecular Geometry VSEPR Theory

Section 2 - Intermolecular Forces Comparing Ionic and Covalent Compounds Particles attract each other, so it takes energy to overcome the forces holding.

A. Ionic Bonding 1. attraction between large numbers of (+) ions and (-) ions 2. results when there is large electronegativity differences 3. generally.

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

Introductory Chemistry: Concepts & Connections Introductory Chemistry: Concepts & Connections 4 th Edition by Charles H. Corwin Chemical Bonding Christopher.

Chapter 5 Molecular Compounds.

Chapter Five Molecular Compounds Fundamentals of General, Organic & Biological Chemistry 4th Edition Mohammed Hashmat Ali Southeast Missouri State University.

Chapter 5 The covalent bond model. Covalent bonds result from the sharing of electrons between atoms. These electron pairs (bonds) act like a glue to.

Christopher G. Hamaker, Illinois State University, Normal IL © 2008, Prentice Hall Chapter 12 Chemical Bonding INTRODUCTORY CHEMISTRY INTRODUCTORY CHEMISTRY.

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

1 Chapter 4 Compounds and Their Bonds 4.7 Shapes and Polarity of Molecules Copyright © 2009 by Pearson Education, Inc. °

Warm Up What does VSEPR stand for?

BONDING AND GEOMETRY Unit 10 ChemistryLangley **Corresponds to Chapter 7 and 8 (pages ) in the Prentice Hall Chemistry textbook.

MOLECULAR GEOMETRY Determining the Structure of Molecules.

Chapter 6 Molecular Geometry

Chemical Bonding Chapter 11

Molecular Shape and Polarity The Importance of Geometry in Determining Physical Properties.

Covalent Compounds Chapter 8. Section 1, Covalent Bonds –Remember, ionic compounds are formed by gaining and losing electrons –Atoms can also share electrons.

INTRODUCTORY CHEMISTRY INTRODUCTORY CHEMISTRY Concepts and Critical Thinking Sixth Edition by Charles H. Corwin Chapter 12 1 © 2011 Pearson Education,

Chapter 9 – Molecular Geometry and Bonding Theories

Covalent Compounds Chapter Covalent Bonds. Covalent Bond The sharing of electrons between atoms Forms a molecule To have stable (filled) orbitals.

INTRODUCTORY CHEMISTRY INTRODUCTORY CHEMISTRY Concepts and Critical Thinking Sixth Edition by Charles H. Corwin Chapter 12 1 © 2011 Pearson Education,

Solubility: Molecular Polarity. How do molecules stay together?

COVALENT BONDING. This occurs when two non-metallic atoms _________ electrons in order to obtain the stable number of eight electrons in their outer shells.

Molecular Geometry. It’s all about the Electrons Electrons decide how many bonds an atom can have They also decide the overall shape of the molecule OPPOSITES.

Polarity and VSEPR. Covalent Bonding SHARING OF ELECTRONS! Atoms attain an octet (also called noble gas electron configurations) by sharing electrons.

POLARITY. Polar Molecules l A polar molecule is a molecule with one end having positive electrical charge and the other end having negative electrical.

I can #2 I can draw a Lewis structure. Rules for Lewis Structures 1. total number of valance electrons 2. central atom –Always C, Never H, Rarely O, or.

Preview Objectives Molecular Geometry VSEPR Theory Hybridization Intermolecular Forces Chapter 6 Section 5 Molecular Geometry.

Chapter 12 Chemical Bonding. Chapter 12 Table of Contents 12.1 Types of Chemical Bonds (see Part 1) 12.2 Electronegativity (see Part 1) 12.3 Bond Polarity.

Chapter 6 The Shape of Molecules.

Chapter 12 Chemical Bonding.

6.8 Shapes and Polarity of Molecules

Chapter 6 The Shape of Molecules.

Chapter 8 “Covalent Bonding”

Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals Chapter 10.

Chapter 12 Chemical Bonding by Christopher Hamaker

Electronegativity and Polarity

CHEMICAL BONDING IONIC BONDS COVALENT BONDS HYDROGEN BONDS

CHEMICAL BONDING IONIC BONDS COVALENT BONDS HYDROGEN BONDS

2/10/16 Today I will determine the shapes of small molecules.

Drawing Lewis Structures

Chapter 10 Properties of Solids and Liquids

Chapter 4 Compounds and Their Bonds

Chapter 7: Covalent Bonds and Molecular Structure

DO NOW Pick up notes and Electron Dot handout

Bonding Chapter 12 Chemical Lecture Presentation John Singer

Covalent Bonds Chapter 8.

Bonding Review.

Warm Up What does VSEPR stand for?

Presentation transcript:

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.1 Redraw each structure to get the electron groups as far apart as possible. What angles did you use?

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.1 CO 2. Answer: First draw a dot diagram, then examine it via VSEPR: Note: Don’t worry about the arrangement of the electron pairs about the peripheral (outer) atoms of a molecule. Only the electrons on the inner atoms affect the shape. For all these problems, describe the geometry of the electron groups and name the molecular shape resulting from that geometry. Also, draw the molecule, and label the size of all bond angles in your drawing.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.2 NH 4 + (cation). For all these problems, describe the geometry of the electron groups and name the molecular shape resulting from that geometry. Also, draw the molecule, and label the size of all bond angles in your drawing.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.3 C 2 Cl 2, which is connected Cl—C—C—Cl. For all these problems, describe the geometry of the electron groups and name the molecular shape resulting from that geometry. Also, draw the molecule, and label the size of all bond angles in your drawing.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.4 COCl 2, in which all atoms are connected to C, and there is a carbon–oxygen double bond. For all these problems, describe the geometry of the electron groups and name the molecular shape resulting from that geometry. Also, draw the molecule, and label the size of all bond angles in your drawing.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.2 How would you describe the shape of the water and ozone molecules? Follow the convention! Ignore the lone pairs on each central atom. Cover them up and use a word or phrase that best describes the shape created by the atoms.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.3 The drawings preceding WorkPatch 6.2 give the ideal values for the bond angles in the molecules. Recalling that there is roughly a 2° compression from the ideal VSEPR angle for every lone pair on the central atom, give a more accurate bond angle for each molecule.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.4 We left three possible situations out of Table 6.2: 1.Four electron groups (SN = 4): one bonding group and three lone pairs. 2.Three electron groups (SN = 3): one bonding group and two lone pairs. 3.Two electron groups (SN = 2): one bonding group and one lone pair. These are considered trivial cases. Why? What shape(s) do these bonding situations give rise to?

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.5 PBr 3. Answer: First draw a dot diagram (which must show 26 electrons): Next, count electron groups about the central atom. There are four (three single bonds and one lone pair), indicating a tetrahedral geometry of these groups about the P atom. However, because you must ignore the lone pair on P, the molecule is pyramidal in shape, with a predicted Br—P — B angle of less than 109.5°. (You might predict 107°, but P is not a period 2 element. The actual bond angle is 102°.) For each molecule or polyatomic ion in the following five problems, (a) draw the electron-group geometry, (b) name the shape of the molecule, and (c) estimate the size of all the bond angles in the molecule or ion. (Some of the molecules and ions have lone pairs on the central atom.)

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.6 SO 4 2– (anion). For each molecule or polyatomic ion in the following five problems, (a) draw the electron-group geometry, (b) name the shape of the molecule, and (c) estimate the size of all the bond angles in the molecule or ion. (Some of the molecules and ions have lone pairs on the central atom.)

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.7 HCN, in which hydrogen and nitrogen are attached to carbon. For each molecule or polyatomic ion in the following five problems, (a) draw the electron-group geometry, (b) name the shape of the molecule, and (c) estimate the size of all the bond angles in the molecule or ion. (Some of the molecules and ions have lone pairs on the central atom.)

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.8 Sulfur dioxide, SO 2, a pollutant that comes from burning coal contaminated with sulfur. For each molecule or polyatomic ion in the following five problems, (a) draw the electron-group geometry, (b) name the shape of the molecule, and (c) estimate the size of all the bond angles in the molecule or ion. (Some of the molecules and ions have lone pairs on the central atom.)

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.9 HNO 3, in which hydrogen is attached to one of the oxygens and all oxygens are attached to nitrogen. To simplify, ignore the hydrogen when you name the molecule’s shape. For each molecule or polyatomic ion in the following five problems, (a) draw the electron-group geometry, (b) name the shape of the molecule, and (c) estimate the size of all the bond angles in the molecule or ion. (Some of the molecules and ions have lone pairs on the central atom.)

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.5 When does a bond have a dipole moment of zero? Here is a hint for the Workpatch. The dipole moment will be zero only when the two atoms have no partial charges. When does this happen? What does a dipole moment of zero mean for the bond? Check your answer against ours at the end of the chapter.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.6 Which molecule is more polar? [Be careful!] Which molecule is more polar?

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 6.7 Why is the upward tug in COCl 2 slightly stronger than either of the downward tugs?

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.10 Is phosphorus trichloride, PCl 3, a polar molecule? If it is, draw the dipole moment vector for the entire molecule and show where the  + and  – regions of the molecule are. Answer: Yes, it is a polar molecule. PCl 3 should have 26 electrons.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.11 Is chloroform, CHCl 3, a polar molecule? If it is, draw the dipole moment vector for the entire molecule and show where the  + and  – regions of the molecule are.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 6.12 Show how the molecules of Problems 6.10 and 6.11 would arrange themselves if they were placed between two plates, one carrying a positive electrical charge and the other carrying a negative electrical charge.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 7.3Draw a picture showing how NH 3 molecules attract one another.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 7.7(a)Draw a dot diagram for NH 3 and one for PH 3. (b)Is either molecule polar? (The electronegativities of N, P, and H are 3.0, 2.1, and 2.1, respectively.) (c)In which substance are the London forces stronger? Explain. (d)Basing your answer solely on the London forces in the two substances, which substance would you expect to have the higher boiling point? Explain.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Workpatch 7.3 The boiling point of one of these compounds is 35 º C, and the boiling point of the other is 78 º C: Which boils at which temperature? Why? If hydrogen bonds are involved in either case, make a drawing using dotted lines to show the hydrogen-bonding.

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 7.10For the hydrogen halides, the order of boiling points is HF > HI > HBr > HCl. (a)Why does HF have the highest boiling point? (b)Why is the boiling point of HI greater than those of HBr and HCl?

© 2011 Pearson Education, Inc. Introductory Chemistry, 4th Edition Steve Russo Practice Problems 7.12How is a piece of iron similar to a piece of sodium chloride in terms of the forces that must be overcome to melt it?