Transcript Chapter 10
10. Organohalides Based on McMurry’s Organic Chemistry, 7th edition What Is an Organohalide? An organic compound containing at least one halogen attached to an sp3 hybridized carbon X (F, Cl, Br, I) replaces H Can contain many C-X bonds Properties and some uses Fire-resistant solvents Refrigerants Pharmaceuticals and precursors 2 3 Epibatidine (200X more effective than morphine!) 4 Vancomycin (antibiotic from amycolatopsis orientalis): 5 10.1 Naming Alkyl Halides Name chain is based on longest carbon (Contains double or triple bond if present) Number from end nearest any substituent (alkyl or halogen) Halogens have same priority as alkyl groups 6 7 Naming with Multiple Halides If more than one of the same kind of halogen is present, use prefix di, tri, tetra If there are several different halogens, number them and list them in alphabetical order 8 Naming if Two Halides or Alkyl Are Equally Distant from Ends of Chain Begin at the end nearer the substituent whose name comes first in the alphabet 9 Many Alkyl Halides That Are Widely Used Have Common Names 10 10.2 Structure of Alkyl Halides C-X bond is longer as you go down periodic table C-X bond is weaker as you go down periodic table C-X bond is polarized with slight positive on carbon and slight negative on halogen 11 Properties of the Halomethanes 12 13 10.3: Radical Halogenation Alkane + Cl2 or Br2, initiated by heat or light; replaces C-H with C-X Hard to control for monosubstitution Reacts via a free radical mechanism See mechanism in Figure 10-1 It is usually not a good idea to plan a synthesis that uses this method 14 15 Multiple Substitution 16 Radical Halogenation of Alkanes If there is more than one type of hydrogen in an alkane, the reaction favors replacing the hydrogen at the most highly substituted carbons: 3o>2o>1o The number of available hydrogens is a factor Methyl hydrogens, for example, often outnumber 2o or 3o hydrogens. 17 Chlorination is unselective: 18 Relative Reactivity Based on quantitative analysis of reaction products, relative reactivity is estimated Order parallels stability of radicals (See Figure 10-2) 19 20 21 Bromination is much more selective than chlorination: 22 10.4 Preparing Alkyl Halides Alkyl halide is formed by the addition of HCl, HBr, HI to alkenes to give the Markovnikov product (see Alkenes chapter) Alkyl geminal dihalide from anti addition of bromine or chlorine 23 10.5 Allylic Bromination of Alkenes N-bromosuccinimide (NBS) selectively brominates allylic positions Requires light for activation: a source of bromine atoms at very low concentrations 24 Allylic Bromination of Alkenes 25 26 Allylic Stabilization 27 Allylic Stabilization Allyl radical is delocalized More stable than typical alkyl radical by 40 kJ/mol (9 kcal/mol Allylic radical is more stable than tertiary alkyl radical 28 10.5 Stability of the Allyl Radical: Resonance Revisited Three electrons are delocalized over three carbons Spin density surface shows single electron is dispersed 29 Allylic Resonance: 30 Allylic Radicals as Reaction Intermediates: 31 Use of Allylic Bromination Allylic bromination with NBS creates an allylic bromide Reaction of an allylic bromide with base produces a conjugated diene, useful in synthesis of complex molecules 32 Practice Problem 10.1: Products? 33 Problem 10.5: Draw resonance forms 34 Problem 10.5 35 Problem 10.6: Explain? 36 Problem 10.6: mechanism CH2 CH2 Br2 CH2Br 37 10.6 Preparing Alkyl Halides from Alcohols Reaction of tertiary C-OH with HX is fast and effective Add HCl or HBr gas into ether solution of tertiary alcohol Primary and secondary alcohols react very slowly and often rearrange, so alternative methods are used 38 Reactivity of Alcohols with HX 39 Preparation of Alkyl Halides from Primary and Secondary Alcohols Specific reagents avoid acid and rearrangements of carbon skeleton Thionyl chloride converts alcohols into alkyl chlorides (SOCl2 : ROH to RCl) Phosphorus tribromide converts alcohols into alkyl bromides (PBr3: ROH to RBr) 40 41 Problem 10.23: Products? 42 Prob. 10.8: Synthesize from alcohols? 43 10.7 Reactions of Alkyl Halides: Grignard Reagents Reaction of RX with Mg in ether or THF Product is RMgX – an organometallic compound (alkylmetal bond) R is alkyl 1°, 2°, 3°, aryl, alkenyl X = Cl, Br, I 44 François Auguste Victor Grignard •Born in Cherbourg, 1871 •PhD, University of Lyon, 1901 •Nobel Prize in Chemistry, 1912 45 Grignard Carbon as Nucleophile: 46 Reactions of Grignard Reagents Many useful reactions RMgX behaves as R- (adds to C=O) RMgX + H3O+ yields R-H 47 10.8 Organometallic Coupling Reactions Alkyllithium (RLi) forms from RBr and Li metal RLi reacts with copper iodide to give lithium dialkylcopper (Gilman reagents) Henry Gilman (1893-1986) 48 49 Lithium dialkylcopper reagents react with alkyl halides to give alkanes: 50 Problem 10.23 (continued): 51 Utility of Organometallic Coupling in Synthesis Coupling of two organometallic molecules produces larger molecules of defined structure Aryl and vinyl organometallics also effective Coupling of lithium dialkylcopper molecules proceeds through trialkylcopper intermediate 52 10.9 Oxidation and Reduction in Organic Chemistry In organic chemistry, oxidation occurs when a carbon or hydrogen that is connected to a carbon atom in a structure is replaced by oxygen, nitrogen, or halogen Not easily recognizable as loss of electrons by an atom as in inorganic chemistry Oxidation is a reaction that results in loss of electron density at carbon (as more electronegative atoms replace hydrogen or carbon) Oxidation: loss of H, and/or gain of O, N, X 53 Reduction Reactions Organic reduction is the opposite of oxidation Results in gain of electron density at carbon (replacement of electronegative atoms by hydrogen or carbon) Reduction: gain of H and/or loss of O, N, X 54 55 56 Oxidation Levels Functional groups are associated with specific oxidation levels 57 Practice Problem 10.2: Rank in order of increasing oxidation level 58 Problem 10.13: oxidation or reduction? 59 Problem 10.33: oxidation or reduction? 60 Problem 10.39: Identify reagents 61 Problem 10.39 a = BH3/THF followed by H2O2/OH-1 (hydroboration/oxidation) b = PBr3/ether c = (CH3)2CuLi/ether 62