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Organic Mechanisms. Basic Ideas Behind A ll M echanisms. Substances can be broken into 2 categories: Electrophile – electron loving Acts as Lewis Acid Accepts a pair of electrons ex. Carbons in alkane chains, hydrogen Ions Nucleophile – nucleus loving Acts as Lewis Base
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Basic Ideas Behind All Mechanisms • Substances can be broken into 2 categories: • Electrophile – electron loving • Acts as Lewis Acid • Accepts a pair of electrons • ex. Carbons in alkane chains, hydrogen Ions • Nucleophile – nucleus loving • Acts as Lewis Base • Donates a pair of electrons • ex. Halogens, Double bonds
Strengths of Nucleophiles • Related to Kb value. • More negative charge makes it stronger (same particle) ex. OH- stronger than H2O • Decreases as you go to the right on the periodic table. Ex. Ammonia is stronger than water • Solvation impedes nucleophilicity Ex. Iodine is a larger anion so the solvent doesn’t surround as easily making it easier for Iodine to react. • Causes an increase as you go down a column on the periodic table.
Nucleophilic Power continued • Increasing polarizability increases power. • Larger atoms are more polarizable (dispersion forces) • Overall strength • H3C->HS->Br->OH->CN->NH3>Cl->F->H2O>ROH
Organic Redox • Oxidation is defined as any process that adds electronegative atoms or removes hydrogen. • Adding oxygen to carbon in combustion • Alcohol to aldehyde or ketone • Reduction is any process that adds hydrogen and removes electronegative elements. • Adding hydrogens to a double bond • Aldehyde or ketone to alcohol
Biochemistry • The body uses complex catalysts to help with these organic reactions, but the principles and products are the same. • Ex. Alcohol in the body. • NAD+ is called a dehydrogenase (enzyme) because it removes two hydrogens each time. • It is also the electron acceptor in the redox.
Oxidation of Alcohols, Aldehydes, Ketones and Carboxylic Acids 1˚ primary alchohol • Aldehyde • Carboxylic Acid 2˚ primary alchohol • Ketone
Homo and heterolytic cleavage • When a bond is broken, each fragment gets one of the electrons from the bond and is left with an extra unpaired electron • This is called homolysis or homolytic cleavage. • The result is two free radicals • Usually free radicals are intermediates and are high energy. • A-B → A. + B. • If a bond is broken and both electrons go to one fragment, then they both become ions • This is called heterolytic cleavage. • A-B → A+ + :B-
Organic Reactions • Pyrolysis • Substitution • -halogenation – with a halogen • -SN2 – with a nucleophile • -SN1 or hydrolysis (solvolysis) – substitution by solvent • E1 - Elimination – removes halogen and makes alkene • E2 – Elimination – same as E1 but different mechanism • Hydrogenation – double bond eliminated by hydrogen • Hydration – double bond is eliminated and makes an alcohol. • Dehydration – water is released. • Electrophilic addition – double bond is broken by a strong acid. • Polymerization – taking alkenes and linking them into (essentially) unending chains.
Pyrolysis • When alkanes are exposed to high temperatures, C-H and C-C bonds begin to break leaving two radicals. • The radicals can combine to form smaller chains. • Process is called cracking. • Heat can also cause hydrogen to be lost from the radical leaving an alkene • Called hydrogen abstraction. • CH3CH2.+ CH3CH2CH2.→ CH3CH3 + CH3CH=CH2 • Zeolytes (catalysts like sodium aluminosilicates) help specialize what products will be made.
Hyperconjugation • When the electron is removed from the molecule, an sp3 orbital is left half empty. • The electron in the orbital delocalizes into a p orbital leaving the other bonds in a planar formation. • Resonance and hyperconjugation are forms of delocalization of electrons. • Resonance is of a πbond overlap of p-orbitals • Hyperconjugation is delocalization with σbonds.
Substitution Reaction A general reaction type in which an atom or group of atoms in a molecule is replaced by another atom or group of atoms. Halogenation reactions are one type:
Halogenation • Activity series determines which halogen is most likely to react and substitute • Fluorine is exothermic, the rest are increasingly endothermic. • UV light breaks the halogen bond enabling the reaction. • Secondary carbons are more likely to substitute than primary. • Tertiary are more likely than secondary.
SN2 mechanism • Reaction mechanisms provide a powerful way to organize the vast amount of information about organic reactions. • SN2 mechanism • One very important reaction mechanism. • The symbol (SN2) stands for substitution nucleophilic bimolecular. • Nucleophile • “Nucleus loving.” A species that is attracted by a positive charge. • OH-, I-, NH3, CH3O-, NC-
SN2 mechanism • Example • HO- + CH3Br (aq) CH3OH (aq) + Br- • For this reaction: • HO- is the nucleophile. Increases with increasing negative charge, decreases to right on periodic table • CH3Br is the substrate - a species that undergoes reaction. • Br- is the leaving group. Because it is replaced by HO-. Weak bases are good leaving groups.
SN2 mechanism • The mechanism takes place in a single step. This is supported by the observed rate law. • Rate = k [HO-][CH3Br] • SN2 reactions also take place with inversion of configuration.
SN2 mechanism d+ d- To account for the inversion, the nucleophile must approach from the back of the carbon The nucleophile acts as a Lewis base and the substrate as a Lewis acid. d- d+
SN2 mechanism • Predicting whether an SN2 reaction will occur is possible. • The SN2 reaction • Nuc:- + RX RNuc + X- • is similar to a Bronsted-Lowry acid base reaction • B:- + HX HB + X-
SN2 mechanism • To predict whether a SN2 reaction will occur, you must consider the relative base strength of the nucleophile and the leaving group. • If the nucleophile is a stronger base, the reaction will occur. • Relative base strength • OH- > Cl- > Br- > I- • Second order based on concentration of the base and the halide.
Hydrolysis (SN1) • Haloalkane reacts with water solvent. • Halogen ionizes away from a carbon leaving a carbocation. • Tertiary carbocations are the best while primary are the worst. • Due to hyperconjugation the positive charge is stabilized in the tertiary formation. • Polar water is attracted to carbocation. • Extra hydrogen is attracted to next water molecule to create a hydronium ion. • First order based on concentration of halide.
E1 Elimination • Haloalkanes react with a base or nucleophile. • Alternate SN1 pathway. • Instead of adding water, it kicks out another proton (H+) and forms a double bond between carbons in its place. • Leaves you with an alkene and a halogenated acid. • Weak bases give substitutions SN1and SN2, strong bases give eliminations E1. • First order reaction: only dependent on the concentration of the halide.
E2 - Elimination • Second order reaction due to concentration of both the halide and the base. • Base attacks a hydrogen on a carbon away from the halide. • Hydrogen leaves donating its electron pair to the carbon giving it four pairs. • Carbon makes double bond with the other carbon which causes the release of the halogen ion.
Hydrogenation • A carbonyl group from an aldehyde or a ketone or a double bond in an alkene is attacked by hydrogen gas or some other hydride in the presence of a catalyst. • Catalyst is usually heterogeneous (insoluble) like platinum, palladium, or nickel deposited on carbon. • Results in an alcohol when an aldehyde or ketone is involved, and an alkane when an alkene is involved.
Hydration: The addition of water, in the presence of a strong acid catalyst, to a multiple bond to give an alcohol product.
Dehydration • A strong acid is added to an alcohol making a halide and water. • HBr + C2H5OH → C2H5Br + H2O • A carboxylic acid and alcohol react in the presence of an acid to make an ester. • Called esterfication. • An alcohol in acid (sulfuric) make an ether and water. • An alcohol with an acid and heat will make an alkene
Electrophilic Addition • The acid attacks the pi bond breaking it an leaving a carbocation. • The halogen attaches to the ion to make a halide. • Also called hydrohalogenation. • Product can be determined using Markalnikov’s rule.
Hydrohalogenation Hydrochoric and hydrobromic acids are hydrohalides HCl, HBr
Markovnikov’s rule In the addition of HX to an alkene, the H attaches to the carbon that already has the most H’s, and the X attaches to the carbon that has fewer H’s.
Markonvnikov’s Rule Only one product is produced because of the mechanism of hydrohalogenation
Use Markovnikov’s rule to predict the product for a hydration as well.
Alkynes • It is important to note that all reactions that occur with alkenes will occur in alkynes. • Each step in the mechanism just has to happen twice.