ORGANIC CHEMISTRY Hydrocarbons: Alkenes, Cycloalkenes, Dienes and Alkynes Dr. Geetu Gambhir E-340, Greater Kailash II New Delhi -110048 (31.07.2006) CONTENTS Alkenes Structure Nomenclature of alkenes Methods of preparation Dehydration of Alcohols Properties Regioselectivity Polymerization of Alkenes Industrial Application of ethylene and Propene Cycloalkenes Nomenclature Conformations Reactions Dienes Types of Dienes Nomenclature Allenes Methods of Preparation Reactions 1, 3 – Butadiene Methods of preparation Reactions Alkynes Structure Nomenclature Methods of preparation Properties Acidity of terminal hydrogen Reactions 1 Alkenes Alkenes are the unsaturated hydrocarbons having one or more carbon – carbon double bond. These are also termed as olefins since ethene (or ethylene – common name), the simplest alkene forms an oily liquid when treated with chlorine. General formula: CnH n 2 Structure The double bond geometry of alkenes is typical of that found in ethene. Each of the double bonded carbon atom is Sp2 hybridized, molecular geometry of which requires it to have trigonal planar geometry i.e. all the atoms surrounding each carbon atom lie in the same plane with bond angles approximating 120°. Of the three hybrid orbitals formed by Sp2 hybridization two overlap with s orbital of each hydrogen forming sigma bond. The third hybrid orbital overlapps with the Sp2 hybrid orbital of adjacent carbon atom forming another sigma bond. Pure p orbital on each of the two adjacent carbon atoms undergoes sideways overlap to form a pi bond. As a result of the double bond the carbon bond length is shorter for alkenes in comparison to the alkanes (also because in Sp2 hybrid orbitals there is large amount of s character (33%)and therefore density with in Sp2 orbitals is concentrated closer to the nucleus). e.g. C H 2 2 Nomenclature of alkenes Nomenclature of alkenes can be derived by simply modifying the alkane nomeclature. 1. An unbranched alkene is named by replacing the “ane” suffix in the corresponding alkane with “ene”. 2. Carbon atoms are numbered from one end of the chain to other so that the double bond receives the lowest number. 3. For the branched alkenes, the principal chain is defined as the carbon chain containing the greatest number of double bonds even if it is not the longest (if more than one chain with equal numbers of double bonds then the longer one is the principal chain). 4. The principal chain is numbered from the end that results in the lowest numbers for the carbon of the double bond. 5. Alkene containing the alkyl substituent the position of the double bond and not the position of branch determines the numbering of the chain. 6. Position of the double bond is cited in the name after the name of the alkyl group. 7. If the compound contains more than one double bond, the “ane” ending of the corresponding alkane is replaced by “adiene” or “atriene” and so on for two three or more double bonds. 2 Example: Isomerism Isomeric alkenes that differ in position of the double bond are the constitutional isomers. Alkenes with identical connectivities that differ in the spatial arrangement of their atoms are called stereoisomers. For any alkene with two different groups around the double bonded carbon atom, interchanging the two groups at either carbon of the double bond gives different molecules hence stereoisomers (The two can not be interchanged by simple rotation as any such rotation would break the pi bond). For example: Methods of preparation 1. Partial reduction of alkynes: to form alkenes can be brought about by number of reducing agents like Na/liq NH , hydrogen in presence of palladium poisned with BaSO or CaCO 3 4 3 along with quinoline (Lindlar catalyst) , Hydrogen in presence of nickel boride. 3 2. Dehydrohalogenation of alkyl halides: by action of strong base like ethanolic potassium hydroxide. It proceeds by elimination of hydrogen halide leading to formation of alkene. 4 Mechanism • The reaction is referred as 1,2 elimation or β-elimation • It is a base catalyzed reaction • Hydrogen is abstracted by a base as a proton leaving behind it’s electron pair and the leaving group (halogen ) leaves the substrate molecule (alkylhalide) as halide ion taking its electron pair along with it. An extra electron pair on the carbon atom is responsible for the pi bond between the carbon atoms. • It is a single step bimolecular elimination reaction. • Rate determining step involves cleavage of C - H and C - L bonds. • The energy required to break these bonds come from the energy released due to formation of B-H bond and pi bond • The cleavage of C-X bond in rate determine step implies the reactivity of alkyl halides to follow the order R-1>R-Br>RCl which matched the bond dissociation energy of C-X bond. • A good leaving group is a weakly basic anion or molecule. • The reaction is not accompanied by rearrangement, which favours the given second order kinetics. • The reaction proceeding by E1 mechanism or first order kinetics follows the mechanism where substrate undergoes slow heterolysis to form halide ion and a carbocation. In the second step carbocation rapidly loses a proton to a base and forms the alkene. The carbocation can very well combine with a nucleophile or undergo rearrangement. Example • Ease of dehydrohalogenation of alkyl halides is 3° > 2° >1°. • If the alkyl halide has two or more β carbon atoms then two or more alkenes are possible as products. It is the stability of the alkenes that decides the chief product. According to Saytzeff Rule dehydrohalogation of alkyl halides leads to the formation of that alkene which has maximum number of alkyl groups attached to >C = C< (more substituted alkene is more stable) 5 • If size of the base is increased it is easier to abstract proton from a less substituted β carbon atom of alkyl halide. Therefore less stable alkene is the chief product. This is known as Hoffmann rule • Saytzeff product is the major product for alkyl iodides, alkyl bromides and alkyl chlorides. • Hoffman product is the major product for alkyl flourides. Reason : Increases in carbon - halogen bond dissocation energy makes difficult for leaving group to leave as Xθ. As a result reaction follows the alternate mechanism called elimination from conjugate base. Here the base first removes proton from the β carbon atom forming carbanion as the intermediate. The carbanion then attacks the α-carbon atom causing the removal of F. Dehydration of Alcohols Alcohols when treated in presence of H SO , P O , BF or by passing the vapour of alcohol 2 4 2 5 3 over a catalyst commonly alumina (Al O ) at high temperature undergo a loss of water 2 3 molecule with the formation of alkenes. • Mechanism: Ist step -OH group of alcohol is protonated in a fast reversible reaction (Acid transforms the poor leaving group (-OH) (strongly basic) into a good leaving group O+H (weakly basic water 2 molecule). IInd step Water molecule is lost with the formation of carbonium ion in the rate determining step. 6 IIIrd Step Carbonium ion loses proton from its adjacent carbon atom to form stable alkene. The anion of the acid or another alcohol molecule functions as a base and facilitates the loss of proton. • The ease of dehydration of alcohols 3° > 2° > 1°. Primary alcohols require strong conditions of conc. H SO and high temperature (180° – 2 4 200°) while secondary alcohols dehydrate under milder condition with 85% H PO at 160°C 3 4 or 60% H SO at 100°C. Tertiary alconds can be easily dehydrated by 20% H SO at 85°- 2 4 2 4 90°C Reason: • Alchol reactivity parallels carbocation stability 3° > 2° > 1°. • More stable intermediate (carbocation) implies a lower activation energy (Ea). This can be understood from the Hammonds postulate that for the endothermic conversions (as dissociation of alkyloxinium ion involves bond breaking without any bond making to compensate for energy required) as shown in the figure, the transition state resembles the high energy intermediate or product and tracks the energy of this intermediate if it changes. The change in transition state energy and activation energy is observed as the stability of intermediate (carbocation changes) Since the activation energy path to the formation of more stable carbocation (3° > 2° > 1°) is the lowest, hence the reactivity of the alcohol also follows the similar order. • When more than one alkene can be formed the preferred product is more stable one. 7 • When carbonium in is the intermediate and structure permits rearrangement in which an atom or a cyclic ring expands so that more stable carbonium ion is formed, the rearrangement tends to take place example. • Alkyl sulphonates undergo base promoted elimination closely analogues to dehydrohalogenation. • The leaving group (sulphonyl group) is a weak base. 4. Dehalogenation of vicinal dihalides (where two halogen atoms are attached to the adjacent carbon atom) • The two halogen atoms are lost in two steps and the two align themselves at 180 and in the same plane before they are lost . NaI and Acetone 5. Cleavage of ethers: Treatment with strong bases such as sodamide or alkyl lithium or alkyl sodium, alkenes are generated Mechanism: Reaction takes place through cyclic intermediate 8 • Reaction is aided by e- withdrawing groups at β position 6. Pyrolysis of esters Thermal cleavage of an ester usually acetate, involves the formation of cyclic transition state leading to the elimination of an acid leaving behind alkene as a product. • This is cis elimination where both the leaving groups proton and carboxylate ion are in the cis position. 7. Hoffmann Degradation method: by heating quartenary ammonium hydroxide under reduced pressure and at a temperature between 100ºC and 200ºC • OHθ ion removes proton from β -carbon atom which gives more stable carbanion. 8. Wittig Reaction :Aldehydes and ketones are converted to alkenes by using special class of compounds called phosphorus ylides or wittig regent. The alkyl halide is treated with triphenyl phospine to produce phosphonium halide. A strong base like C H Li or n-C H Li 6 5 4 9 converts it to phosphorane, which is stabilized by resonance. Phosphorane reacts with aldehyde or ketone to produce alkene via a cyclic intermediate. 9. By cracking of petroleum number of alkenes like ethylene propene or butene can be prepared. Properties Physical properties of Alkenes • Like alkanes, alkenes are inflammable, non-polar compounds, less dense than and insoluble in water but soluble in nonpolar solvents like benzene petroleum ether etc. 9 • Lower molecular weight alkenes (C -C ) are gases 2 4 • Sp2 hybridized carbon atom is more electronegative than Sp3 carbon atom so Sp2-Sp3 carbon - carbon bond has a small dipole directed towards Sp2 carbon atom. Dipole moment of the compound is vector sum all the bond dipoles. This is why is cis 2-butene has a net dipole moment, while the dipole moment of trans 2-butane is zero. • Boiling points increases (i) With increasing carbon content (ii) With decrease of branching • cis alkenes boil at some what higher temperature than trans alkene due to its higher dipole moment. • cis alkene have poor symmetry and do not fit in to crystalline lattice as compared to trans isomer therefore cis alkene has low melting point. • Thermal stability of alkenes can be compared by determination of their heats of combustion. Lower is the – ∆H value of combustion, higher is the stability. In general order of stability is. • More substituted alkenes are more stable. Chemical properties • The most characteristic type of alkene reaction is electrophillic addition at carbon-carbon double bond. The pi bond of the alkene and X-Y bond of the reagent are broken and new C-X and C-Y bonds are formed • Majority of these reactions are exothermic due to the fact that the C-C pi bond is weak relative to the sigma bonds formed to the atoms or groups of the reagent. Consequently bond energies of product molecules are greater than the bond energies of the reactants. 1) Hydrogenation ; Hydrogen adds to the double bond under pressure and in presence of catalyst to form alkenes. Heterogeneous catalyst: Catalyst such as finally divided Platinum or palladium black or nickel are useful as hydrogenation catalyst. They are used in conjunction with solid support materials such as alumnia (Al O ), BaSO or activated charcoal. 2 3 4 • These are heterogeneous catalyst as they are insoluble in reaction solution • These noble metal catalysts can be filtered and reused. 10