Chapter 3 Lecture Outline

Chapter 3 Lecture Outline
Organic Chemistry, Second Edition Janice Gorzynski Smith University of Hawai’i Chapter 3 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.

Introduction to Organic Molecules and Functional Groups
A functional group is an atom or a group of atoms with characteristic chemical and physical properties. It is the reactive part of the molecule. Most organic compounds have C—C and C—H bonds. However, many organic molecules possess other structural features: Heteroatoms—atoms other than carbon or hydrogen.  Bonds—the most common  bonds occur in C—C and C—O double bonds. These structural features distinguish one organic molecule from another. They determine a molecule’s geometry, physical properties, and reactivity, and comprise what is called a functional group.

Heteroatoms and  bonds confer reactivity on a particular molecule. Heteroatoms have lone pairs and create electron-deficient sites on carbon.  Bonds are easily broken in chemical reactions. A  bond makes a molecule a base and a nucleophile. Don’t think that the C—C and C—H bonds are unimportant. They form the carbon backbone or skeleton to which the functional group is attached.

Ethane: This molecule has only C—C and C—H bonds, so it has no functional group. Ethane has no polar bonds, no lone pairs, and no  bonds, so it has no reactive sites. Consequently, ethane and molecules like it are very unreactive. Ethanol: This molecule has an OH group attached to its backbone. This functional group is called a hydroxy group. Ethanol has lone pairs and polar bonds that make it reactive with a variety of reagents. The hydroxy group makes the properties of ethanol very different from the properties of ethane.

Hydrocarbons are compounds made up of only the elements carbon and hydrogen. They may be aliphatic or aromatic.

Aromatic hydrocarbons are so named because many of the earliest known aromatic compounds had strong characteristic odors. The simplest aromatic hydrocarbon is benzene. The six-membered ring and three  bonds of benzene comprise a single functional group. When a benzene ring is bonded to another group, it is called a phenyl group.

Examples of Molecules Containing C-Z  Bonds

Functional Groups

Compounds Containing the C=O Group: This group is called a “carbonyl group”. The polar C—O bond makes the carbonyl carbon an electrophile, while the lone pairs on O allow it to react as a nucleophile and base. The carbonyl group also contains a  bond that is more easily broken than a C—O  bond.

Molecules Containing the C=O Functional Group

It should be noted that the importance of a functional group cannot be overstated. A functional group determines all of the following properties of a molecule: Bonding and shape Type and strength of intermolecular forces Physical properties Nomenclature Chemical reactivity

Intermolecular Forces Intermolecular forces are interactions that exist between molecules. Functional groups determine the type and strength of these interactions. There are several types of intermolecular interactions. Ionic compounds contain oppositely charged particles held together by extremely strong electrostatic inter-actions. These ionic inter-actions are much stronger than the intermolecular forces present between covalent molecules.

Intermolecular Forces Covalent compounds are composed of discrete molecules. The nature of the forces between molecules depends on the functional group present. There are three different types of interactions, shown below in order of increasing strength: van der Waals forces dipole-dipole interactions hydrogen bonding

Intermolecular Forces—van der Waals Forces van der Waals forces are also known as London forces. They are weak interactions caused by momentary changes in electron density in a molecule. They are the only attractive forces present in nonpolar compounds. Even though CH4 has no net dipole, at any one instant its electron density may not be completely symmetrical, resulting in a temporary dipole. This can induce a temporary dipole in another molecule. The weak interaction of these temporary dipoles constitutes van der Waals forces.

Intermolecular Forces—van der Waals Forces All compounds exhibit van der Waals forces. The surface area of a molecule determines the strength of the van der Waals interactions between molecules. The larger the surface area, the larger the attractive force between two molecules, and the stronger the intermolecular forces. Figure 3.1 Surface area and van der Waals forces

Intermolecular Forces—van der Waals Forces van der Waals forces are also affected by polarizability. Polarizability is a measure of how the electron cloud around an atom responds to changes in its electronic environment. Larger atoms, like iodine, which have more loosely held valence electrons, are more polarizable than smaller atoms like fluorine, which have more tightly held electrons. Thus, two F2 molecules have little attractive force between them since the electrons are tightly held and temporary dipoles are difficult to induce.

Intermolecular Forces—Dipole-Dipole Interactions Dipole—dipole interactions are the attractive forces between the permanent dipoles of two polar molecules. Consider acetone (below). The dipoles in adjacent molecules align so that the partial positive and partial negative charges are in close proximity. These attractive forces caused by permanent dipoles are much stronger than weak van der Waals forces.

Intermolecular Forces—Hydrogen Bonding Hydrogen bonding typically occurs when a hydrogen atom bonded to O, N, or F, is electrostatically attracted to a lone pair of electrons on an O, N, or F atom in another molecule.

Intermolecular Forces—Hydrogen Bonding Note: as the polarity of an organic molecule increases, so does the strength of its intermolecular forces.

Physical Properties—Boiling Point The boiling point of a compound is the temperature at which liquid molecules are converted into gas. In boiling, energy is needed to overcome the attractive forces in the more ordered liquid state. The stronger the intermolecular forces, the higher the boiling point. For compounds with approximately the same molecular weight:

Physical Properties—Boiling Point Consider the example below. Note that the relative strength of the intermolecular forces increases from pentane to butanal to 1-butanol. The boiling points of these compounds increase in the same order. For two compounds with similar functional groups: The larger the surface area, the higher the boiling point. The more polarizable the atoms, the higher the boiling point.

Physical Properties—Boiling Point Consider the examples below which illustrate the effect of size and polarizability on boiling points. Figure 3.2 Effect of surface area and polarizability on boiling point

Physical Properties—Boiling Point Liquids having different boiling points can be separated in the laboratory using a distillation apparatus, shown in Figure 3.3. Figure 3.3 Schematic of a distillation apparatus

Physical Properties—Melting Point The melting point is the temperature at which a solid is converted to its liquid phase. In melting, energy is needed to overcome the attractive forces in the more ordered crystalline solid. The stronger the intermolecular forces, the higher the melting point. Given the same functional group, the more symmetrical the compound, the higher the melting point.

Physical Properties—Melting Point Because ionic compounds are held together by extremely strong interactions, they have very high melting points. With covalent molecules, the melting point depends upon the identity of the functional group. For compounds of approximately the same molecular weight:

Physical Properties—Melting Point The trend in melting points of pentane, butanal, and 1-butanol parallels the trend observed in their boiling points.

Physical Properties—Melting Point Symmetry also plays a role in determining the melting points of compounds having the same functional group and similar molecular weights, but very different shapes. A compact symmetrical molecule like neopentane packs well into a crystalline lattice whereas isopentane, which has a CH3 group dangling from a four-carbon chain, does not. Thus, neopentane has a much higher melting point.

Physical Properties—Solubility Solubility is the extent to which a compound, called a solute, dissolves in a liquid, called a solvent. In dissolving a compound, the energy needed to break up the interactions between the molecules or ions of the solute comes from new interactions between the solute and the solvent.

Physical Properties—Solubility Compounds dissolve in solvents having similar kinds of intermolecular forces. “Like dissolves like.” Polar compounds dissolve in polar solvents. Nonpolar or weakly polar compounds dissolve in nonpolar or weakly polar solvents. Water and organic solvents are two different kinds of solvents. Water is very polar and is capable of hydrogen bonding with a solute. Many organic solvents are either nonpolar, like carbon tetrachloride (CCl4) and hexane [CH3(CH2)4CH3], or weakly polar, like diethyl ether (CH3CH2OCH2CH3). Most ionic compounds are soluble in water, but insoluble in organic solvents.

Physical Properties—Solubility An organic compound is water soluble only if it contains one polar functional group capable of hydrogen bonding with the solvent for every five C atoms it contains. For example, compare the solubility of butane and acetone in H2O and CCl4.

Physical Properties—Solubility Since butane and acetone are both organic compounds having a C—C and C—H backbone, they are soluble in the organic solvent CCl4. Butane, which is nonpolar, is insoluble in H2O. Acetone is soluble in H2O because it contains only three C atoms and its O atom can hydrogen bond with an H atom of H2O.

Physical Properties—Solubility To dissolve an ionic compound, the strong ion-ion interactions must be replaced by many weaker ion-dipole interactions. Figure 3.4 Dissolving an ionic compound in H2O

Physical Properties—Solubility The size of an organic molecule with a polar functional group determines its water solubility. A low molecular weight alcohol like ethanol is water soluble since it has a small carbon skeleton of  five C atoms, compared to the size of its polar OH group. Cholesterol has 27 carbon atoms and only one OH group. Its carbon skeleton is too large for the OH group to solubilize by hydrogen bonding, so cholesterol is insoluble in water.

Physical Properties—Solubility The nonpolar part of a molecule that is not attracted to H2O is said to be hydrophobic. The polar part of a molecule that can hydrogen bond to H2O is said to be hydrophilic. In cholesterol, for example, the hydroxy group is hydrophilic, whereas the carbon skeleton is hydrophobic. Figure 3.5 Solubility summary

Application—Vitamins Vitamins are organic compounds needed in small amounts for normal cell function. Most cannot be synthesized in our bodies, and must be obtained from the diet. Most are identified by a letter, such as A, C, D, E and K. There are several different B vitamins, so a subscript is added to distinguish them. Examples are B1, B2, and B12. Vitamins are fat soluble (they dissolve in organic media) or water soluble. Vitamins A and C illustrate the differences between fat-soluble and water-soluble vitamins.

Application—Vitamins Vitamin A, or retinol, may be obtained directly from the diet. In addition, -carotene, the orange pigment found in many plants including carrots, is readily converted into vitamin A in our bodies. Vitamin A is an essential component of the vision receptors in our eyes. It also helps to maintain the health of mucous membranes and skin. Vitamin A is water insoluble.

Application—Vitamins Vitamin C, or ascorbic acid, is important in the formation of collagen It is obtained from eating citrus fruits. Vitamin C deficiency results in scurvy It is heavily hydroxylated, which makes it capable of hydrogen bonding, and thus, water soluble.

Application—Soap Figure 3.6 Dissolving soap in water Soap: Soap molecules have two distinct parts—a hydrophilic portion composed of ions called the polar head, and a hydrophobic carbon chain of nonpolar C—C and C—H bonds, called the nonpolar tail.

Application—The Cell Membrane Figure 3.7 The cell membrane

Application—The Cell Membrane Transport Across a Cell Membrane: Polar molecules and ions are transported across cell membranes encapsulated within molecules called ionophores. Ionophores are organic molecules that complex cations. They have a hydrophobic exterior that makes them soluble in the nonpolar interior of the cell membrane, and a central cavity with several oxygens whose lone pairs complex with a given ion.

Application—The Cell Membrane Transport Across a Cell Membrane: Figure 3.8 Transport of ions across a cell membrane

Application—The Cell Membrane Several synthetic ionophores have also been prepared, including one group called crown ethers. Crown ethers are cyclic ethers containing several oxygen atoms that bind specific cations depending on the size of their cavity.

Influence of Functional Groups on Reactivity Recall that: Functional groups create reactive sites in molecules. Electron-rich sites react with electron poor sites. All functional groups contain a heteroatom, a  bond or both, and these features create electron-deficient (or electrophilic) sites and electron-rich (or nucleophilic) sites in a molecule. Molecules react at these sites.

Influence of Functional Groups on Reactivity

Influence of Functional Groups on Reactivity An electron-deficient carbon reacts with a nucleophile, symbolized as :Nu¯. An electron-rich carbon reacts with an electrophile, symbolized as E+. For example, alkenes contain an electron rich double bond, and so they react with electrophiles E+.

Influence of Functional Groups on Reactivity On the other hand, alkyl halides possess an electrophilic carbon atom, so they react with electron-rich nucleophiles.

Biomolecules Biomolecules are organic compounds found in biological systems. Many are relatively small with molecular weights of less than 1000 g/mol. There are four main families of small molecule biomolecules: Simple sugars—combine to form complex carbohydrates like starch Nucleotides—are the building blocks of DNA Amino acids—join together to form proteins Fatty acids—are the building blocks of triacylglycerols, lipids that are stored as fat droplets in adipose tissue. Biomolecules often have several functional groups.

Figure 3.9 Simple and complex biomolecules

Figure 3.9 continued Simple and complex biomolecules

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