Chapter 2 Lecture Outline

Chapter 2 Lecture Outline
Organic Chemistry, Second Edition Janice Gorzynski Smith University of Hawai’i Chapter 2 Lecture Outline Prepared by Rabi Ann Musah State University of New York at Albany Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Acids and Bases Brønsted-Lowry Acids and Bases
A Brønsted-Lowry acid is a proton donor. A Brønsted-Lowry base is a proton acceptor. H+ = proton Figure 2.1 Examples of Brønsted–Lowry acids and bases

Acids and Bases Brønsted-Lowry Acids and Bases
Some molecules contain both hydrogen atoms and lone pairs and thus, can act either as acids or bases, depending on the particular reaction. An example is the addictive pain reliever morphine.

Acids and Bases Reactions of Brønsted-Lowry Acids and Bases
A Brønsted-Lowry acid base reaction results in the transfer of a proton from an acid to a base. In an acid-base reaction, one bond is broken, and another one is formed. The electron pair of the base B: forms a new bond to the proton of the acid. The acid H—A loses a proton, leaving the electron pair in the H—A bond on A.

Acids and Bases Reactions of Brønsted-Lowry Acids and Bases
The movement of electrons in reactions can be illustrated using curved arrow notation. Because two electron pairs are involved in this reaction, two curved arrows are needed. Loss of a proton from an acid forms its conjugate base. Gain of a proton by a base forms its conjugate acid. A double reaction arrow is used between starting materials and products to indicate that the reaction can proceed in the forward and reverse directions. These are equilibrium arrows. Examples:

Acids and Bases Acid Strength and pKa
Acid strength is the tendency of an acid to donate a proton. The more readily a compound donates a proton, the stronger an acid it is. Acidity is measured by an equilibrium constant. When a Brønsted-Lowry acid H—A is dissolved in water, an acid-base reaction occurs, and an equilibrium constant can be written for the reaction.

Acids and Bases Acid Strength and pKa
Because the concentration of the solvent H2O is essentially constant, the equation can be rearranged and a new equilibrium constant, called the acidity constant, Ka, can be defined. It is generally more convenient when describing acid strength to use “pKa” values than Ka values.

Acids and Bases Acid Strength and pKa

Acids and Bases Factors that Determine Acid Strength
Anything that stabilizes a conjugate base A:¯ makes the starting acid H—A more acidic. Four factors affect the acidity of H—A. These are: Element effects Inductive effects Resonance effects Hybridization effects No matter which factor is discussed, the same procedure is always followed. To compare the acidity of any two acids: Always draw the conjugate bases. Determine which conjugate base is more stable. The more stable the conjugate base, the more acidic the acid.

Element Effects—Trends in the Periodic Table. Across a row of the periodic table, the acidity of H—A increases as the electronegativity of A increases. Positive or negative charge is stabilized when it is spread over a larger volume.

Element Effects—Trends in the Periodic Table. Down a column of the periodic table, the acidity of H—A increases as the size of A increases. Size, and not electronegativity, determines acidity down a column. The acidity of H—A increases both left-to-right across a row and down a column of the periodic table. Although four factors determine the overall acidity of a particular hydrogen atom, element effects—the identity of A—is the single most important factor in determining the acidity of the H—A bond.

Acids and Bases Factors that Determine Acid Strength—Inductive Effects
An inductive effect is the pull of electron density through  bonds caused by electronegativity differ-ences between atoms. In the example below, when we compare the acidities of ethanol and 2,2,2-trifluoroethanol, we note that the latter is more acidic than the former.

The reason for the increased acidity of 2,2,2-trifluoroethanol is that the three electronegative fluorine atoms stabilize the negatively charged conjugate base.

When electron density is pulled away from the negative charge through  bonds by very electronegative atoms, it is referred to as an electron withdrawing inductive effect. More electronegative atoms stabilize regions of high electron density by an electron withdrawing inductive effect. The more electronegative the atom and the closer it is to the site of the negative charge, the greater the effect. The acidity of H—A increases with the presence of electron withdrawing groups in A.

Acids and Bases Factors that Determine Acid Strength—Resonance Effects
Resonance is a third factor that influences acidity. In the example below, when we compare the acidities of ethanol and acetic acid, we note that the latter is more acidic than the former. When the conjugate bases of the two species are compared, it is evident that the conjugate base of acetic acid enjoys resonance stabilization, whereas that of ethanol does not.

Resonance delocalization makes CH3COO¯ more stable than CH3CH2O¯, so CH3COOH is a stronger acid than CH3CH2OH. The acidity of H—A increases when the conjugate base A:¯ is resonance stabilized.

Electrostatic potential plots of CH3CH2O¯ and CH3COO¯ below indicate that the negative charge is concentrated on a single O in CH3CH2O¯, but delocalized over both of the O atoms in CH3COO¯.

Acids and Bases Factors that Determine Acid Strength—Hybridization Effects The final factor affecting the acidity of H—A is the hybridization of A. Let us consider the relative acidities of three different compounds containing C—H bonds. The higher the percent of s-character of the hybrid orbital, the closer the lone pair is held to the nucleus, and the more stable the conjugate base.

Acids and Bases Factors that Determine Acid Strength—Hybridization Effects

Acids and Bases Factors that Determine Acid Strength—Hybridization Effects Figure 2.5 Summary of the factors that determine acidity

Acids and Bases Commonly Used Acids in Organic Chemistry
In addition to the familiar acids HCl, H2SO4 and HNO3, a number of other acids are often used in organic reactions. Two examples are acetic acid and p-toluene-sulfonic acid (TsOH).

Acids and Bases Commonly Used Bases in Organic Chemistry
Common strong bases used in organic reactions are more varied in structure.

Acids and Bases Commonly Used Bases in Organic Chemistry
It should be noted that: Strong bases have weak conjugate acids with high pKa values, usually > 12. Strong bases have a net negative charge, but not all negatively charged species are strong bases. For example, none of the halides F¯, Cl¯, Br¯, or I¯, is a strong base. Carbanions, negatively charged carbon atoms, are especially strong bases. A common example is butyllithium. Two other weaker organic bases are triethylamine and pyridine.

Acids and Bases Lewis Acids and Bases
The Lewis definition of acids and bases is more general than the BrØnsted-Lowry definition. A Lewis acid is an electron pair acceptor. A Lewis base is an electron pair donor. Lewis bases are structurally the same as BrØnsted-Lowry bases. Both have an available electron pair—a lone pair or an electron pair in a  bond. A BrØnsted-Lowry base always donates this electron pair to a proton, but a Lewis base donates this electron pair to anything that is electron deficient.

A Lewis acid must be able to accept an electron pair, but there are many ways for this to occur. All BrØnsted-Lowry acids are also Lewis acids, but the reverse is not necessarily true. Any species that is electron deficient and capable of accepting an electron pair is also a Lewis acid. Common examples of Lewis acids (which are not BrØnsted-Lowry acids) include BF3 and AlCl3. These compounds contain elements in group 3A of the periodic table that can accept an electron pair because they do not have filled valence shells of electrons.

Any reaction in which one species donates an electron pair to another species is a Lewis acid-base reaction. In a Lewis acid-base reaction, a Lewis base donates an electron pair to a Lewis acid. Lewis acid-base reactions illustrate a general pattern in organic chemistry. Electron-rich species react with electron-poor species. In the simplest Lewis acid-base reaction one bond is formed and no bonds are broken. This is illustrated in the reaction of BF3 with H2O. H2O donates an electron pair to BF3 to form a new bond.

A Lewis acid is also called an electrophile. When a Lewis base reacts with an electrophile other than a proton, the Lewis base is also called a nucleophile. In this example, BF3 is the electrophile and H2O is the nucleophile. electrophile nucleophile

Two other examples are shown below. Note that in each reaction, the electron pair is not removed from the Lewis base. Instead, it is donated to an atom of the Lewis acid and one new covalent bond is formed.

In some Lewis acid-base reactions, one bond is formed and one bond is broken. To draw the products of these reactions, keep in mind the following steps: Always identify the Lewis acid and base first. Draw a curved arrow from the electron pair of the base to the electron-deficient atom of the acid. Count electron pairs and break a bond when needed to keep the correct number of valence electrons.

Consider the Lewis acid-base reaction between cyclohexene and H—Cl. The BrØnsted-Lowry acid HCl is also a Lewis acid, and cyclohexene, having a bond, is the Lewis base.

To draw the product of this reaction, the electron pair in the  bond of the Lewis base forms a new bond to the proton of the Lewis acid, generating a carbocation. The H—Cl bond must break, giving its two electrons to Cl, forming Cl¯. Because two electron pairs are involved, two curved arrows are needed.

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