Chapter 12 Molecular Structure. An Introduction to Chemistry by Mark Bishop

Similar documents
Ionic and Covalent Bonds

Sample Exercise 8.1 Magnitudes of Lattice Energies

Chapter 5 Chemical Compounds

Laboratory 11: Molecular Compounds and Lewis Structures

AP Chemistry A. Allan Chapter 8 Notes - Bonding: General Concepts

Theme 3: Bonding and Molecular Structure. (Chapter 8)

Self Assessment_Ochem I

Chapter 8 Concepts of Chemical Bonding

LEWIS DIAGRAMS. by DR. STEPHEN THOMPSON MR. JOE STALEY

Health Science Chemistry I CHEM-1180 Experiment No. 15 Molecular Models (Revised 05/22/2015)

Molecular Geometry and Chemical Bonding Theory

Lewis Dot Notation Ionic Bonds Covalent Bonds Polar Covalent Bonds Lewis Dot Notation Revisited Resonance

Sample Exercise 8.1 Magnitudes of Lattice Energies

A pure covalent bond is an equal sharing of shared electron pair(s) in a bond. A polar covalent bond is an unequal sharing.

CHEMISTRY BONDING REVIEW

C has 4 valence electrons, O has six electrons. The total number of electrons is 4 + 2(6) = 16.

We will not be doing these type of calculations however, if interested then can read on your own

Start: 26e Used: 6e Step 4. Place the remaining valence electrons as lone pairs on the surrounding and central atoms.

EXPERIMENT 9 Dot Structures and Geometries of Molecules

CHAPTER 6 Chemical Bonding

Chapter 7. Comparing Ionic and Covalent Bonds. Ionic Bonds. Types of Bonds. Quick Review of Bond Types. Covalent Bonds

EXPERIMENT 17 : Lewis Dot Structure / VSEPR Theory

Worksheet 14 - Lewis structures. 1. Complete the Lewis dot symbols for the oxygen atoms below

Formal Charges. Step 2. Assign the formal charge to each atom. Formal charge is calculated using this formula: H O H H

Molecular Geometry and VSEPR We gratefully acknowledge Portland Community College for the use of this experiment.

Hybrid Molecular Orbitals

Chemical Bonding: Covalent Systems Written by Rebecca Sunderman, Ph.D Week 1, Winter 2012, Matter & Motion

Chapter 2 The Chemical Context of Life

ch9 and 10 practice test

pre -TEST Big Idea 2 Chapters 8, 9, 10

A REVIEW OF GENERAL CHEMISTRY: ELECTRONS, BONDS AND MOLECULAR PROPERTIES

5. Structure, Geometry, and Polarity of Molecules

7.14 Linear triatomic: A-----B-----C. Bond angles = 180 degrees. Trigonal planar: Bond angles = 120 degrees. B < B A B = 120

2. Atoms with very similar electronegativity values are expected to form

Bonding & Molecular Shape Ron Robertson

CHAPTER 6 REVIEW. Chemical Bonding. Answer the following questions in the space provided.

Chapter 8 Basic Concepts of the Chemical Bonding

SOME TOUGH COLLEGE PROBLEMS! .. : 4. How many electrons should be shown in the Lewis dot structure for carbon monoxide? N O O

Chemistry 105, Chapter 7 Exercises

2. Which one of the ions below possesses a noble gas configuration? A) Fe 3+ B) Sn 2+ C) Ni 2+ D) Ti 4+ E) Cr 3+

CH101/105, GENERAL CHEMISTRY LABORATORY

Molecular Models & Lewis Dot Structures

B) atomic number C) both the solid and the liquid phase D) Au C) Sn, Si, C A) metal C) O, S, Se C) In D) tin D) methane D) bismuth B) Group 2 metal

A mutual electrical attraction between the nuclei and valence electrons of different atoms that binds the atoms together is called a(n)

SHAPES OF MOLECULES (VSEPR MODEL)

Question 4.2: Write Lewis dot symbols for atoms of the following elements: Mg, Na, B, O, N, Br.

Chapter 5 TEST: The Periodic Table name

Chapter 6 Assessment. Name: Class: Date: ID: A. Multiple Choice Identify the choice that best completes the statement or answers the question.

Exercises Topic 2: Molecules

CHEM 1301 SECOND TEST REVIEW. Covalent bonds are sharing of electrons (ALWAYS valence electrons). Use Lewis structures to show this sharing.

Geometries and Valence Bond Theory Worksheet

Survival Organic Chemistry Part I: Molecular Models

Bonding Practice Problems

Covalent Bonding and Molecular Geometry

4.2. Molecular Shape and Polarity. Lewis Structures for Molecules and Polyatomic Ions

Structures and Properties of Substances. Introducing Valence-Shell Electron- Pair Repulsion (VSEPR) Theory

Chapter 4 Lecture Notes

Valence Bond Theory: Hybridization

Chapter 4: Structure and Properties of Ionic and Covalent Compounds

A PREVIEW & SUMMMARY of the 3 main types of bond:

List the 3 main types of subatomic particles and indicate the mass and electrical charge of each.

Chapter 1 Benzene Blues 27

OCTET RULE Generally atoms prefer electron configurations with 8 valence electrons. - Filled s and p subshells

Questions on Chapter 8 Basic Concepts of Chemical Bonding

VSEPR Model. The Valence-Shell Electron Pair Repulsion Model. Predicting Molecular Geometry

CHEMISTRY Practice Exam #5 - SPRING 2014 (KATZ)

The elements of the second row fulfill the octet rule by sharing eight electrons, thus acquiring the electronic configuration of neon, the noble gas o

Periodic Table Questions

Chapter 2 Polar Covalent Bonds: Acids and Bases

Bonding Models. Bonding Models (Lewis) Bonding Models (Lewis) Resonance Structures. Section 2 (Chapter 3, M&T) Chemical Bonding

Chapter10 Tro. 4. Based on the Lewis structure, the number of electron domains in the valence shell of the CO molecule is A) 1 B) 2 C) 3 D) 4 E) 5

Elements in the periodic table are indicated by SYMBOLS. To the left of the symbol we find the atomic mass (A) at the upper corner, and the atomic num

Chemical Bonding. Chemical Bonding

Chapter 1 Structure and Bonding. Modified by Dr. Daniela Radu

Molecular Models in Biology

Molecular Models Experiment #1

CHAPTER 12: CHEMICAL BONDING

Visualizing Molecular Orbitals: A MacSpartan Pro Experience

Chapter 9 - Covalent Bonding: Orbitals

Ionization energy _decreases from the top to the bottom in a group. Electron affinity increases from the left to the right within a period.

Unit 3: Quantum Theory, Periodicity and Chemical Bonding. Chapter 10: Chemical Bonding II Molecular Geometry & Intermolecular Forces

7.4. Using the Bohr Theory KNOW? Using the Bohr Theory to Describe Atoms and Ions

CHEMICAL NAMES AND FORMULAS

PERIODIC TABLE OF GROUPS OF ELEMENTS Elements can be classified using two different schemes.

Trends of the Periodic Table Diary

Ionic and Metallic Bonding

Unit 3: Quantum Theory, Periodicity and Chemical Bonding

TYPES OF CHEMICAL BONDING Ionic Bonding - two atoms of opposite charge electrically attracted to one another

SCPS Chemistry Worksheet Periodicity A. Periodic table 1. Which are metals? Circle your answers: C, Na, F, Cs, Ba, Ni

Chapter 9. Chemical reactivity of molecules depends on the nature of the bonds between the atoms as well on its 3D structure

Modelling Compounds. 242 MHR Unit 2 Atoms, Elements, and Compounds

Test Bank - Chapter 4 Multiple Choice

19.2 Chemical Formulas

EXPERIMENT 1: Survival Organic Chemistry: Molecular Models

Section Activity #1: Fill out the following table for biology s most common elements assuming that each atom is neutrally charged.

1.15 Bonding in Methane and Orbital Hybridization

: : Solutions to Additional Bonding Problems

Chapter 2 Polar Covalent Bonds; Acids and Bases

3) Of the following, radiation has the shortest wavelength. A) X-ray B) radio C) microwave D) ultraviolet E) infrared Answer: A

Acids and Bases: Molecular Structure and Acidity

Transcription:

Chapter 12 Molecular Structure An Introduction to Chemistry by Mark Bishop

Chapter Map

Models Advantages and Disadvantages (1) They help us to visualize, explain, and predict chemical changes. Because a model is a simplified version of what we think is true, the processes it depicts are sometimes described using the phrase as if. When you read, It is as if an electron were promoted from one orbital to another, the phrase is a reminder that we do not necessarily think this is what really happens. We merely find it useful to talk about the process as if this is the way it happens.

Models Advantages and Disadvantages (2) One characteristic of models is that they change with time. Because our models are simplifications of what we think is real, we are not surprised when they sometimes fail to explain experimental observations. When this happens, the model is altered to fit the new observations.

Assumptions of the Valence-Bond Model Only the highest energy electrons participate in bonding. Covalent bonds usually form to pair unpaired electrons.

Valence Electrons Valence electrons are the highestenergy s and p electrons in an atom.

Fluorine F 1s 2 2s 2 2p 5 Valence electrons

H 2 Formation The unpaired electron on a hydrogen atom makes the atom unstable. Two hydrogen atoms combine to form one hydrogen molecule.

Carbon 4 bonds

Carbon Multiple Bonds

Nitrogen 3 bonds & 1 lone pair

Nitrogen 4 bonds

Oxygen 2 bonds & 2 lone pairs

Oxygen 1 bond & 3 lone pairs

Carbon 3 bonds & 1 lone pair Oxygen 3 bonds & 1 lone pair

Boron 3 bonds

Halogens 1 bond & 3 lone pairs

Most Common Bonding Patterns for Nonmetals Element # Bonds # lone pairs H 1 0 C 4 0 N, P 3 1 O, S, Se 2 2 F, Cl, Br, I 1 3

Drawing Lewis Structures (1) Step 1: Determine the total number of valence electrons for the molecule or polyatomic ion. For uncharged molecules, the total number of valence electrons is the sum of the valence electrons of each atom. For polyatomic cations, the total number of valence electrons is the sum of the valence electrons for each atom minus the charge. For polyatomic anions, the total number of valence electrons is the sum of the valence electrons for each atom plus the charge.

Drawing Lewis Structures (2) Step 2: Draw a reasonable skeletal structure, using single bonds to join all the atoms. Try to arrange the atoms to yield the most typical number of bonds for each atom. Apply the following guidelines in deciding what element belongs in the center of your structure. Hydrogen and fluorine atoms are never in the center. Oxygen atoms are rarely in the center. The element with the fewest atoms in the formula is often in the center. The atom that is capable of making the most bonds is often in the center. Oxygen atoms rarely bond to other oxygen atoms. The molecular formula often reflects the molecular structure. Carbon atoms commonly bond to other carbon atoms.

Drawing Lewis Structures (3) Step 3: Subtract 2 electrons from the total for each of the single bonds (lines) described in Step 2.

Drawing Lewis Structures (4) Step 4: Try to distribute the remaining electrons as lone pairs to obtain a total of eight electrons around each atom except hydrogen and boron. In a reasonable Lewis structure, carbon, nitrogen, oxygen, and fluorine always have eight electrons around them. Hydrogen will always have a total of two electrons from its one bond. Boron can have fewer than eight electrons but never more than eight. The nonmetallic elements in periods beyond the second period (P, S, Cl, Se, Br, and I) usually have eight electrons around them, but they can have more. The bonding properties of the metalloids arsenic, As, and tellurium, Te, are similar to those of phosphorus, P, and sulfur, S, so they usually have eight electrons around them but can have more.

Drawing Lewis Structures (5) Step 5: Do one of the following. If in Step 4 you were able to obtain an octet of electrons around each atom other than hydrogen and boron, and if you used all of the remaining valence electrons, go to Step 6. If you have electrons remaining after each of the atoms other than hydrogen and boron have their octet, you can put more than eight electrons around elements in periods beyond the second period. (You will not need to use this procedure for any of the structures in this text, but if you take more advanced chemistry courses, it will be useful.) If you do not have enough electrons to obtain octets of electrons around each atom (other than hydrogen and boron), convert one lone pair into a multiple bond for each two electrons that you are short.

Drawing Lewis Structures (6 & 7) Step 6: Check your structure to see if all of the atoms have their most common bonding pattern. Step 7: If necessary, try to rearrange your structure to give each atom its most common bonding pattern. One way to do this is to return to Step 2 and try another skeleton. (This step is unnecessary if all of the atoms in your structure have their most common bonding pattern.)

Lewis Structure Drawing Summary

Resonance We can view certain molecules and polyatomic ions as if they were able to resonate to switch back and forth between two or more different structures. Each of these structures is called a resonance structure. The hypothetical switching from one resonance structure to another is called resonance.

To draw Resonance Forms

Resonance Hybrid To blend the resonance structures into a single resonance hybrid: Step 1: Draw the skeletal structure, using solid lines for the bonds that are found in all of the resonance structures. Step 2: Where there is sometimes a bond and sometimes not, draw a dotted line. Step 3: Draw only those lone pairs that are found on every one of the resonance structures. (Leave off the lone pairs that are on one or more resonance structure but not on all of them.)

Nitrate Resonance

Methane, CH 4

Ammonia, NH 3

Water, H 2 O

Trigonal Planar Geometry BF 3

Ethene (ethylene)

Ethyne (acetylene), C 2 H 2

Steps for Molecular Geometry Step 1: To determine the name of the electron group geometry around each atom that is attached to two or more atoms, count the number of electron groups around each atom and apply the guidelines found on Table 5.2. Step 2: Use one or more of the geometric sketches shown on Table 5.2 for the geometric sketch of your molecule.

Steps for Molecular Geometry (cont.) Step 3: To determine the name of the molecular geometry around each atom that has two or more atoms attached to it, count the number of bond groups and lone pairs, and then apply the guidelines found on Table 5.2.

2024 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information