Transcript Chapter 10
Amines Structure and Classification of Amines • Classification • 1°, 2°, or , 3° amines: Amines in which 1, 2, or 3 hydrogens of NH3 are replaced by alkyl or aryl groups. • Amines are further divided into aliphatic, aromatic, and heterocyclic amines. • Aliphatic amine: An amine in which nitrogen is bonded only to alkyl groups. • Aromatic amine: An amine in which nitrogen is bonded to one or more aryl groups. • Heterocyclic amine: An amine in which nitrogen is one of the atoms of a ring. sp3 Nitrogens as Stereocenters • An acyclic sp3 nitrogen atom with three different groups and a lone pair of electrons is asymmetric. • Even so, an amine with an asymmetric nitrogen atom is rarely a stereocenter, leading to enantiomers. • Acyclic amines interconvert into their own mirror images billions of times per second in a process called pyramidal inversion. • Thus acyclic amines are not chiral. • Cyclic amines and quaternary ammonium salts can be chiral since they are unable to undergo pyramidal inversion. • When the Cahn-Ingold-Prelog rules are used to priorize groups to determine stereoisomers, the electron lone-pair is last. Nomenclature of Amines • Aliphatic amines: replace the suffix -e of the parent alkane by -amine. • To name a secondary or tertiary amine, the alkyl branches need to be named and “numbered” using “N” to designate the branching. N,N-dimethyl-3-ethyl-3-pentanamine N-ethyl-2-propanamine 3,N-dimethyl-2-butanamine • For aromatic amines, the IUPAC system retains the common name aniline. • Among the functional groups, -NH2 has one of the lowest priorities. • Thus –NH2 is often referred to as an amino group and is given the amino- prefix. • Common names for most aliphatic amines are derived by listing the alkyl groups bonded to nitrogen in one word ending with the suffix -amine. • Alkyl groups are listed alphabetically. • When four groups are bonded to the nitrogen atom, we name the compound as a salt (with cation and anion) of the corresponding amine. • Use the suffix –ium to name tetraalkyl amine cation. • i.e., ammonium, pyridinium, anilinium, etc… • Include the counterion (chloride, bromide, etc…) in the name. Physical Properties of Amines • Amines are polar compounds, and both 1° and 2° amines form intermolecular hydrogen bonds. • N-H- - - -N hydrogen bonds are weaker than O-H- - - -O hydrogen bonds because the difference in electronegativity between N and H (3.0 - 2.1 = 0.9) is less than that between O and H (3.5 - 2.1 = 1.4). • Amines generally smell bad. • Trimethylamine is responsible for the smell of rotting fish. Applications of Amines • Amines are used as precursors to make dyes. • Mauveine • The first synthetic dye invented by William Perkin when he was 18. • Acid Orange 7 • It is used in hair coloring formulations. • Aniline Yellow • It is used in inkjet printer inks. • Alkaloids are naturally occurring amines many with medicinal properties. Many are 3o heterocyclic amines. nicotine • Many important neurotransmitters are amines. Basicity of Amines • All amines are weak bases; thus, aqueous solutions of amines are basic. • The reaction of the weak base with water is quantified with the base-dissociation constant, Kb. CH 3 NH 3 OH Kb CH3 NH 2 • It is also common to discuss the basicity of amines by reference to the acid-dissociation constant of its corresponding conjugate acid. • For any conjugate acid-base pair, the pKa and pKb are deeply connected to each other. • Using values of pKa, we can predict the position of equilibrium in acid-base reactions. • Acetic acid is the stronger acid and, therefore, the position of this equilibrium lies to the right. • Aliphatic amines have about the same base strength, pKb 3.0 – 4.0 and are slightly stronger bases than NH3. • Aromatic amines are considerably weaker bases than aliphatic amines. • Aromatic amines are weaker bases than aliphatic amines because the resonance stabilization of the base is lost on protonation. • That is, the conjugate acid of an aromatic amine is a stronger acid than the conjugate acid of the aliphatic amine. • Electron-withdrawing groups, such as halogen atoms, the nitro group, and the carbonyl group, decrease the basicity of aromatic amines by decreasing the availability of the electron pair on nitrogen. • Guanidine (pKb = 0.4) is the strongest base among neutral organic compounds. • Its basicity is due to the resonance delocalization of the positive charge over the three nitrogen atoms. Reactions of Amines (Summary) • Formation of ammonium salts with strong acids. • Reduction of nitro group to form amino group. (Formation of primary amine) • Reagent in nucleophilic substitution. • Formation of benzenediazonium salt from aniline with HNO2. • Reaction of benzenediazonium salt with various reagents to make substituted benzenes. Formation of Ammonium Salts • All amines, whether soluble or insoluble in water, react quantitatively with strong acids to form water-soluble salts. • Many drugs that are water-insoluble are made soluble through the reaction with hydrochloric acid. Norepinephrine is used to treat hypotension (low blood pressure). Synthesis of 1° Amines • Most 1° aromatic amines are synthesized by nitration of an aromatic ring followed by catalytic reduction of the nitro group to an amino group. Amines in Nucleophilic Substitution • Reaction of an amine with an alkyl halide can be used to form a new covalent bond. • Step 1: Reaction of a nucleophile with an electrophile to form a new covalent bond. • Step 2: Take a proton away. Unreacted base deprotonates the substrate, converting the amine salt to a free amine. • In Step 2, a new 2° amine was produced. • The new amine can then also act as a nucleophile. • Thus the final reaction mixture will consist of varying ratios of RNH2, R2NH, R3N, and R4N+Cl–. • These ratios are difficult to control and, therefore, amines are avoided as nucleophiles in nucleophilic substitutions reactions. Formation of the Benzenediazonium Salt • Aniline reacts with sodium nitrite and hydrochloric acid to produce an important intermediate substrate, benzenediazonium salt. NH2 + NaNO2 + HCl Anilin e (a 1° aromatic amin e) Sodium n itrite H2 O 0°C + N N Cl + H2 O Ben zenediazoniu m chloride • Once formed, the benzenediazonium salt can further react with a large variety of reagents to yield a substituted benzene compound. + N N Cl- + H2 O Benzenediazonium chloride OH + N2 Phenol Reactions of the Benzenediazonium Salt • Benzenediazonium salt reacts with water and an acid catalyst when heated to form phenol. N N H2O OH H+, heat • Benzenediazonium salt reacts with tetrafluoroboric acid when heated to form fluorobenzene. N N HBF4, heat F Reactions of the Benzenediazonium Salt • Benzenediazonium salt reacts with copper(I) chloride, copper(I) bromide or copper(I) cyanide to form chloro-, bromo-, or cyanobenzene. CuCl, CuBr, CuCN N N X • Chemists sometimes think of cyanide as an honorary halogen ion. • Recall that R – C ≡ N is called a nitrile. • Benzenediazonium salt reacts with potassium iodide to form iodobenzene. Reactions of the Benzenediazonium Salt • Benzenediazonium salt reacts with hypophosphorous acid, H3PO2, to replace the diazonium group with hydrogen to form benzene. N N H3PO2 H O H P H O H Reactions of the Benzenediazonium Salt