Roos Organic Chemistry Concepts

Chapter 2 Functional Classes I, Structure and Naming
Abstract
This chapter takes an initial look at the structure and representation of functional groups. The principles of the unambiguous systematic classification and naming of organic compounds are introduced. The importance of these for accurate information transfer is highlighted. Common functional classes are detailed and, where needed, three-dimensional diagrams, oxidation states, and physical properties are introduced. Keywords
3-D drawings; Carbon oxidation states; Conjugation; Molecular diagrams; Physical properties; Systematic compound naming 2.1. Drawing and Naming Molecules
To understand the chemistry of organic molecules, we need to know the types of compounds that are possible. In this chapter we look at some details of the important functional classes introduced in Chapter 1. Each compound class is shown with structural diagrams (how to draw the compounds) and systematic naming of the compounds. This background knowledge will prepare you for the chemistry in later chapters. 2.2. Saturated Hydrocarbons
Hydrocarbon means that this class of compound has only carbon and hydrogen. In this broad grouping there are both: ? acyclic examples called alkanes; ? cyclic examples called cycloalkanes. All saturated examples have only single s-bonds between sp3-hybridized carbon atoms and hydrogen atoms. This class gives the parent compounds from which all other functional types come from. They also serve as the parent compounds for systematic naming. Hydrocarbons have low chemical reactivity. This is because they have no reactive functional group. They simply consist of chains of tetrahedral carbon atoms which are surrounded by hydrogen atoms. Table 2.1 gives a selection of hydrocarbons along with their physical properties of melting and boiling points. These low melting and boiling values show their overall non-polar character. Hydrocarbons can have “straight” chains (do not forget the shape caused by the tetrahedral carbon), branched chains, and cyclic variations. For any of these subclasses, we can write a series of compounds that have the same basic structure, but differ from each other by a single extra –CH2– methylene group. Any series of compounds like these is called a homologous series and its members are homologs of each other. 2.2.1. Structural Diagrams
The purpose of a structural diagram is to show details for the arrangement of atoms in a particular compound. As shown in Figure 2.1, there are a number of ways to do this. The choice of method depends on the specific structural feature(s) of interest.
FIGURE 2.1 Structural diagrams. Table 2.1 Parent Acyclic Alkanes and Cycloalkanes Methane CH4 CH4 -182 -162 Ethane C2H6 CH3CH3 -183 -89 Propane C3H8 CH3CH2CH3 -187 -42 Butane C4H10 CH3(CH2)2CH3 -135 -0.5 Pentane C5H12 CH3(CH2)3CH3 -130 36 Hexane C6H14 CH3(CH2)4CH3 -94 69 Heptane C7H16 CH3(CH2)5CH3 -91 98 Octane C8H18 CH3(CH2)6CH3 -57 126 Nonane C9H20 CH3(CH2)7CH3 -54 151 Decane C10H22 CH3(CH2)8CH3 -30 174 Cyclopropane C3H6 -127 -33 Cyclobutane C4H8 -80 -13 Cyclopentane C5H10 -194 49 Cyclohexane C6H12 6.5 81 IUPAC, International Union of Pure and Applied Chemistry. For the beginner, the full Lewis-type structure (extended) is the safest choice. Because every bond and atom is shown, we can avoid mistakes with the tetravalent nature of carbon. After practice with examples that have different structural features and functional groups, it becomes easier to use the shorter forms, such as condensed and bond line types. The condensed forms use groups of atoms and show almost no detail of individual bonds. These groups can show all atoms, for example CH3– and –CH2–. Alternatively, accepted short forms can be used, for example Me– for CH3– and Et– for CH3CH2–. Often it is useful to use a combination of structural diagram forms. In these diagrams, only important features are shown in full detail. You must take care to draw any bonds between the actual bonded atoms. This will avoid any mistakes with the valency (oxidation state) of the atoms involved. Note that only the bond line method shows the shape of the carbon framework. This is because every bend in the diagram represents a bonded group, for example –CH2–. The ends of lines represent CH3– groups. It is also useful to be able to describe the degree of substitution at saturated sp3 carbon centers. This is simply done by counting the number of hydrogen atoms bonded to the particular carbon. As Figure 2.2 shows, this gives rise to four types: ? primary, with 3 Hs on carbon; ? secondary, with 2 Hs on carbon; ? tertiary, with 1 H on carbon; ? quaternary, with no Hs on carbon.
FIGURE 2.2 Classification of carbon centers. It is also common to use the symbol –R to show general alkyl groups. A selection of these are detailed in Section 2.2.3 and are derived from alkanes by removing a hydrogen ligand. In addition, as Figure 2.3 shows, there are different ways to show the three-dimensional (3-D) shape of tetrahedral sp3 centers. A tetrahedral center has four substituents, or attached groups. The most common is to show two adjacent substituents in the plane of the paper with normal bond lines. The other two substituents are drawn going into the paper with a dashed wedged bond, or coming out of the paper with a solid wedged bond.
FIGURE 2.3 Three-dimensional representations around atomic centers. The Fischer projection is a less common alternative. By definition in these drawings, the vertical bonds go into the paper, and the horizontal bonds come out of the paper. You do not always have to show the full stereochemistry (3-D shape) of a molecule. However, as you will see in Chapter 3, it is important not to forget that molecules have 3-D shapes. 2.2.2. Oxidation States for Carbon
This concept helps to create a link between the various classes of carbon compounds. The type and electronegativity of the atoms which are bonded to a carbon lets us assign nominal oxidation numbers to the various carbon atoms. These oxidation numbers indicate the relative gain or loss of electrons at the carbon in each compound type. This shows the relative equivalence of particular carbon oxidation states. From this, we can compare the oxidation levels of different functional groups. The series of oxygen-containing functional classes in Figure 2.4 shows the principle. We can extend this process to other functional classes that involve other heteroatoms such as nitrogen, sulfur, and the halogens.
FIGURE 2.4 Nominal carbon oxidation numbers in functional classes. Hydrogen is given the oxidation number of +1. Therefore, methane has carbon in its most reduced form of -4, which is its most stable, least reactive state. If a hydrogen atom is replaced with a bond to another carbon, the nominal oxidation number of the original carbon changes to -3. This is because we consider the carbons to have no effect on each other. The replacement of another hydrogen atom with a carbon, or the formation of a carbon–carbon double bond, then changes the oxidation number to -2, and so on. Hydrocarbons (alkanes, alkenes, alkynes) can have carbons with nominal oxidation numbers ranging from -4 to 0. This depends on the number of other carbons attached. This follows the sequence from methane through 1°, 2°, 3°, and 4° carbon centers as was shown in Section 2.2.1. This helps us understand the different characteristics which they show in their reactions. When we apply this process to common heteroatoms, they are all more electronegative than carbon and will count as -1 per bond....