Skip to main content

Organic Chemistry I: 1.4 Resonance structures in Organic Chemistry

Organic Chemistry I
1.4 Resonance structures in Organic Chemistry
    • Notifications
    • Privacy
  • Project HomeNatural Sciences Collection: Anatomy, Biology, and Chemistry
  • Projects
  • Learn more about Manifold

Notes

Show the following:

  • Annotations
  • Resources
Search within:

Adjust appearance:

  • font
    Font style
  • color scheme
  • Margins
table of contents
  1. Cover
  2. Title Page
  3. Copyright
  4. Table Of Contents
  5. Introduction
  6. Acknowledgements
  7. Chapter 1 Basic Concepts in Chemical Bonding and Organic Molecules
    1. 1.1 Chemical Bonding
    2. 1.2 Lewis Structure
    3. 1.3 Resonance Structures
    4. 1.4 Resonance structures in Organic Chemistry
    5. 1.5 Valence-Shell Electron-Pair Repulsion Theory (VSEPR)
    6. 1.6 Valence Bond Theory and Hybridization
    7. Answers to Practice Questions Chapter 1
  8. Chapter 2 Fundamental of Organic Structures
    1. 2.1 Structures of Alkenes
    2. 2.2 Nomenclature of Alkanes
    3. 2.3 Functional Groups
    4. 2.4 IUPAC Naming of Organic Compounds with Functional Groups
    5. 2.5 Degree of Unsaturation/Index of Hydrogen Deficiency
    6. 2.6 Intermolecular Force and Physical Properties of Organic Compounds
    7. Answers to Practice Questions Chapter 2
  9. Chapter 3 Acids and Bases: Organic Reaction Mechanism Introduction
    1. 3.1 Review of Acids and Bases and Ka
    2. 3.2 Organic Acids and Bases and Organic Reaction Mechanism
    3. 3.3 pKa of Organic Acids and Application of pKa to Predict Acid-Base Reaction Outcome
    4. 3.4 Structural Effects on Acidity and Basicity
    5. 3.5 Lewis Acids and Lewis Bases
    6. Answers to Practice Questions Chapter 3
  10. Chapter 4 Conformations of Alkanes and Cycloalkanes
    1. 4.1 Conformation Analysis of Alkanes
    2. 4.2 Cycloalkanes and Their Relative Stabilities
    3. 4.3 Conformation Analysis of Cyclohexane
    4. 4.4 Substituted Cyclohexanes
    5. Answers to Practice Questions Chapter 4
  11. Chapter 5 Stereochemistry
    1. 5.1 Summary of Isomers
    2. 5.2 Geometric Isomers and E/Z Naming System
    3. 5.3 Chirality and R/S Naming System
    4. 5.4 Optical Activity
    5. 5.5 Fisher Projection
    6. 5.6 Compounds with More Than One Chirality Centers
    7. Answers to Practice Questions Chapter 5
  12. Chapter 6 Structural Identification of Organic Compounds: IR and NMR Spectroscopy
    1. 6.1 Electromagnetic Radiation and Molecular Spectroscopy
    2. 6.2 Infrared (IR) Spectroscopy Theory
    3. 6.3 IR Spectrum and Characteristic Absorption Bands
    4. 6.4 IR Spectrum Interpretation Practice
    5. 6.5 NMR Theory and Experiment
    6. 6.6 ¹H NMR Spectra and Interpretation (Part I)
    7. 6.7 ¹H NMR Spectra and Interpretation (Part II)
    8. 6.8 ¹³C NMR Spectroscopy
    9. 6.9 Structure Determination Practice
    10. Answers to Practice Questions Chapter 6
  13. Chapter 7 Nucleophilic Substitution Reactions
    1. 7.1 Nucleophilic Substitution Reaction Overview
    2. 7.2 SN2 Reaction Mechanism, Energy Diagram and Stereochemistry
    3. 7.3 Other Factors that Affect SN2 Reactions
    4. 7.4 SN1 Reaction Mechanism, Energy Diagram and Stereochemistry
    5. 7.5 SN1 vs SN2
    6. 7.6 Extra Topics on Nucleophilic Substitution Reaction
    7. Answers to Practice Questions Chapter 7
  14. Chapter 8 Elimination Reactions
    1. 8.1 E2 Reaction
    2. 8.2 E1 Reaction
    3. 8.3 E1/E2 Summary
    4. 8.4 Comparison and Competition Between SN1, SN2, E1 and E2
    5. Answers to Practice Questions Chapter 8
  15. Chapter 9 Free Radical Substitution Reaction of Alkanes
    1. 9.1 Homolytic and Heterolytic Cleavage
    2. 9.2 Halogenation Reaction of Alkanes
    3. 9.3 Stability of Alkyl Radicals
    4. 9.4 Chlorination vs Bromination
    5. 9.5 Stereochemistry for Halogenation of Alkanes
    6. 9.6 Synthesis of Target Molecules: Introduction of Retrosynthetic Analysis
    7. Answers to Practice Questions Chapter 9
  16. Chapter 10 Alkenes and Alkynes
    1. 10.1 Synthesis of Alkenes
    2. 10.2 Reactions of Alkenes: Addition of Hydrogen Halide to Alkenes
    3. 10.3 Reactions of Alkenes: Addition of Water (or Alcohol) to Alkenes
    4. 10.4 Reactions of Alkenes: Addition of Bromine and Chlorine to Alkenes
    5. 10.5 Reaction of Alkenes: Hydrogenation
    6. 10.6 Two Other Hydration Reactions of Alkenes
    7. 10.7 Oxidation Reactions of Alkenes
    8. 10.8 Alkynes
    9. Answers to Practice Questions Chapter 10
  17. About the Author

1.4 Resonance structures in Organic Chemistry

Resonance stabilization effect (also known as resonance effect), as briefly mentioned in Section 1.3, is one of the fundamental concepts of Organic Chemistry and has broad applications. The discussion of resonance effect heavily relies on the understanding of resonance structures. Here we will focus on how to draw resonance structures (or resonance contributors) for organic chemistry species, and how to compare the relative stabilities between the structures.

According to resonance effect, the greater the number of resonance contributors, the greater the resonance stabilization effect, and the more stable the species is. Therefore, to predict whether the resonance effect applies or not, we usually need to construct “new” resonance structures (contributors) based on the “original” one that is available. There are some very important rules we need to follow for such purposes.

Guidelines for Drawing Resonance Structures:

  • All resonance structures must be valid Lewis structures. (Keep in mind that all the rules applied to Lewis structures still apply here!)
  • All resonance structures must have the same atom connectivity, and only differ in the electron arrangement. (Atoms NEVER move, only electrons move.)
  • All resonance structures have the same number of electrons and net charge. (Formal charges on individual atom could be different, but net charge, that is the sum of all the charges, must be the same.)
  • To move electrons, only π electrons and lone-pair electrons (NEVER move σ bonds!) can be moved from the higher electron density area to lower electron density area by following one of the three transformations:
    • π bond forms another π bond;
    • π bond forms the lone pair electrons;
    • lone pair electrons forms a π bond.
  • Use curved arrows to indicate the electron movement in the “original” resonance structure. The “new” resonance structure should be a “product” automatically obtained by following the arrows.
  • Calculate the formal charge in the “new” structure and label any non-zero formal charges.

The way to use curved arrows show electron transfer is also called arrow pushing, it is a very important fundamental skill you need to master in organic chemistry. For the purpose of constructing “new” resonance structures, arrows have to be shown in the “original” structure.

Examples: Draw another resonance structure based on the given one.

1.

""

Approach: There is only one π bond in this example, and no any lone pairs, so only the π electrons can be moved around. There is a carbocation beside the π bond, which is the low electron density spot. Therefore it is reasonable to move the π electrons to the position beside carbocation to form another π bond, and that gives the “new” structure. The two resonance structures here are equivalent.

Solution

""

2.

""

Approach: More electrons available for movement in this example: several lone pairs and one π bond. The guideline of “move electrons from the higher electron density area to the lower electron density area” provides a useful hint about where to start. The nitrogen atom has a “-” formal charge, meaning it has relatively high electron density, higher than other neutral spots. So it is reasonable to move the lone pair on nitrogen away to form a π bond (keep in mind that lone pair can only form π bond, not another lone pair). However, when the new π bond is formed around the carbon atom, there are 5 bonds (10 electrons) on that carbon, which is not allowed. So, another electron pair has to be moved away, and the only available electron pair to be moved is the π electrons in C=O bond. It can be moved onto the oxygen atom and become another lone pair on the oxygen atom.

Solution:

""

The two resonance structures in this example are non-equivalent, so one is more stable than the other. By applying the formal charge guideline, the “-“ formal charge is more preferable on oxygen, which is more electronegative than nitrogen, so the 2nd structure is the more stable one with lower energy, and makes more contribution to the actual structure in this species. The more stable structure can also be called as the major resonance contributor.

Comparing the relative stability of different resonance contributors:

  • Structures with a maximum of octets are most important.
  • Charge separation usually decrease the stability (increase the energy of the contributor).
  • Negative charges should be preferentially located on atoms with greater electronegativity, and positive charges should be preferentially located on atoms with less electronegativity.

Common errors for drawing resonance structures: 

  1. σ bond is moved
  2. Atom is moved
  3. More than eight electrons located around C, N or O
  4. Arrows are not shown in the proper way
  5. Electron pairs are moved too far away, they should only be moved to the next position/atom.

Exercises 1.7 Draw new resonance structure and compare the relative stability, show arrows in the original structure.

""

     2.

""

Answers to Practice Questions Chapter 1

Annotate

Next Chapter
1.5 Valence-Shell Electron-Pair Repulsion Theory (VSEPR)
PreviousNext
Chemistry
The LibreTexts libraries are Powered by NICE CXone Expert and are supported by the Department of Education Open Textbook Pilot Project, the UC Davis Office of the Provost, the UC Davis Library, the California State University Affordable Learning Solutions Program, and Merlot. We also acknowledge previous National Science Foundation support under grant numbers 1246120, 1525057, and 1413739. Legal. Accessibility Statement For more information contact us at info@libretexts.org.
Powered by Manifold Scholarship. Learn more at
Opens in new tab or windowmanifoldapp.org