1 / 19

Mechanisms of organic reactions

Mechanisms of organic reactions. mirka.rovenska@lfmotol.cuni.cz. Types of organic reactions. Substitution – an atom (group) of the molecule is replaced by another atom (group) Addition – π-bond of a compound serves to create two new covalent bonds that join the two reactants together

Antony
Télécharger la présentation

Mechanisms of organic reactions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Mechanisms of organic reactions mirka.rovenska@lfmotol.cuni.cz

  2. Types of organic reactions • Substitution – an atom (group) of the molecule is replaced by another atom (group) • Addition – π-bond of a compound serves to create two new covalent bonds that join the two reactants together • Elimination – two atoms (groups) are removed from a molecule which is thus cleft into two products • Rearrangement – atoms and bonds are rearranged within the molecule; thus, isomeric compound is formed

  3. Mechanism • A reaction can proceed by: • homolytic mechanism – each fragment possesses one of the bonding electrons; thus, radicals are formed: A–B  A• + B• • heterolytic mechanism – one of the fragments retains both the bonding electrons; thus, ions are formed: A–B  A+ + :B–

  4. Agents • Radical – possess an unpaired electron (Cl•) • Ionic: • A)nucleophilic – possess an electron pair that can be introduced into an electron-deficient substrate: • i) anions (H–, OH–) • ii) neutral molecules (NH3, HOH) • B)electrophilic – electron-deficient  bind to substrate centres with a higher electron density: • i) cations (Br+) • ii) neutral molecules (for example Lewis acids: AlCl3)

  5. Lewis acids and bases • Lewis base: acts as an electron-pair donor; e.g. ammonia: NH3 • Lewis acid: can accept a pair of electrons; e.g.: AlCl3, FeCl3, ZnCl2. These compounds – important catalysts: generate ions that can initiate a reaction: CH3–Cl + AlCl3 CH3+ + AlCl4- ••

  6. Radical substitution - here: lipid peroxidation: • 1. Initiation – formation of radicals: H2O  OH• + H• • 2. Propagation – radicals attack neutral moleculesgenerating new molecules and new radicals: CH3CH2R + •OH CH3CHR CH3C–O–O• • 3. Termination – radicals react with each other, forming stable products; thus, the reaction is terminated (by depletion of radicals) H R O2 • – H2O fatty acid CH3CH2R CH3C–OOH CH3CHR + • H R

  7. Electrophilic substitution • An electron-deficient agent reacts with an electron-rich substrate; the substrate retains the bonding electron pair,a cation (proton) is removed: R–X + E+ R–E + X+ • Typical of aromatic hydrocarbons: • chlorination • nitration etc.

  8. Aromatic electrophilic substitution using Lewis acids • Halogenation: • Very often, electrophilic substitution is usedto attach an alkyl to the benzene ring(Friedel-Crafts alkylation): benzene carbocation bromobenzene

  9. δ+ <δ+ <δ+ δ- CH3 CH2 CH2 Cl δ+ H CH3 δ+ δ- H C CH3 C δ+ H CH3 Inductive effect • Permanent shift of -bond electrons in the molecule composed of atoms with different electronegativity: • – I effect is caused by atoms/groups with high electronegativity that withdraw electrons from the neighbouring atoms: – Cl, –C=O, –NO2: • +I effect is caused by atoms/groups with low electronegativity that increase electron density in their vicinity: metals, alkyls:

  10. Mesomeric effects • Permanent shift of electron density along the -bonds (i.e. in compounds with unsaturated bonds, most often in aromatic hydrocarbons) • Positive mesomeric effect (+M) is caused by atoms/groups with lone electron pair(s) that donate π electrons to the system: –NH2, –OH, halogens • Negative mesomeric effect (–M) is caused by atoms/groups that withdraw π electrons from the system: –NO2, –SO3H, –C=O

  11. Activating/deactivating groups • If inductive and mesomeric effects are contradictory, then the stronger one predominates • Consequently, the group bound to the aromatic ring is: • activating – donates electrons to the aromatic ring, thus facilitating the electrophilic substitution: • a) +M > – I… –OH, –NH2 • b) only +I…alkyls • deactivating – withdraws electrons from the aromatic ring, thus making the electrophilic substitution slower: • a) –M and –I… –C=O, –NO2 • b) – I > +M…halogens

  12. Electrophilic substitution & M, I-effects • Substituents exhibiting the +M or +I effect (activating groups, halogens) attached to the benzene ring direct next substituent to the ortho, para positions: • Substituents exhibiting the –M and – I effect (–CHO, –NO2) direct the next substituent to the meta position:

  13. + Nucleophilic substitution • Electron-rich nucleophile introduces an electron pair into the substrate; the leaving atom/group retains the originally bonding electron pair: |Nu– + R–Y  Nu–R + |Y– • This reaction is typical of haloalkanes: • Nucleophiles: HS–, HO–, Cl– alcohol is produced

  14. Radical addition • Again: initiation (creation of radicals), propagation (radicals attack neutral molecules, producing more and more radicals), termination (radicals react with each other, forming a stable product; the chain reaction is terminated) • E.g.: polymerization of ethylene using dibenzoyl peroxide as an initiator:

  15. Electrophilic addition • An electrophile forms a covalent bond by attacking an electron-rich unsaturated C=C bond • Typical of alkenes and alkynes • Markovnikov´s rule: the more positive part of the agent (hydrogen in the example below) becomes attached to the carbon atom (of the double bond) with the greatest number of hydrogens:

  16. aldehyde/ketone Nucleophilic addition • In compounds with polar unsaturated bonds, such as C=O: • Nucleophiles – water, alcohols, carbanions – form a covalent bond with the carbon atom of the carbonyl group: – carbon atom carries + used for synthesisof alcohols

  17. hemiacetal hemiacetals glucose Hemiacetals • Addition of alcohol to the carbonyl group yields hemiacetal: • As to biochemistry, hemiacetals are formed by monosaccharides:

  18. 2-phospho-glycerate phosphoenol-pyruvate Elimination • In most cases, the two atoms/groups are removed from the neighbouring carbon atoms and a double bond is formed (-elimination) • Elimination of water = dehydration – used to prepare alkenes: • In biochemistry – e.g. in glycolysis: – H2O

  19. glucose(keto form) enol form fructose Rearrangement • In biochemistry: often migration of a hydrogen atom, changing the position of the double bond • Keto-enol tautomerism of carbonyl compounds: equilibrium between a keto form and an enol form: • E.g.: isomerisation of monosaccharides occurs via enol form: dihydroxyaceton- phosphate glyceraldehyd- 3-phosphate enol form

More Related