Heteroaromatic Chemistry LECTURE 6 Pyridines: properties, syntheses & reactivity

Similar documents
Chemistry II (Organic)

Chemistry II (Organic)

Solution problem 22: Non-Benzoid Aromatic Sytems

Chapter 5 N S. Typical Reactivity of Pyridines, Quinolines and Isoquinolines

Lecture 28 Organic Chemistry 1

Nucleophilic Addition Reactions of Carboxylic Acid Derivatives

CHEM 303 Organic Chemistry II Problem Set II Chapter 13 Answers

CHEMISTRY. Module No and Title Module-, Electrophilic Aromatic Substitution: The ortho/para ipso attack, orientation in other ring systems.

Introduction to Organic Chemistry

Lecture Topics: I. Electrophilic Aromatic Substitution (EAS)

AROMATIC & HETEROCYCLIC CHEMISTRY

Synthesis of Nitriles a. dehydration of 1 amides using POCl 3 : b. SN2 reaction of cyanide ion on halides:

Problem Set #3 Solutions

Amines Reading Study Problems Key Concepts and Skills Lecture Topics: Amines: structure and nomenclature

Suggested solutions for Chapter 30

Lecture Notes Chem 51C S. King. Chapter 20 Introduction to Carbonyl Chemistry; Organometallic Reagents; Oxidation & Reduction

SIX MEMBERED AROMATIC HETEROCYCLES

Chapter 19: Amines. Introduction

Page 1 of 9. Sessional Examination (November 2017) Max Marks: 20 Date: Time: One Hour. Model Answers

Chemistry Final Examinations Summer 2006 answers

Organic Chemistry. Second Edition. Chapter 19 Aromatic Substitution Reactions. David Klein. Klein, Organic Chemistry 2e

Amines. Amines are organic compounds containing a nitrogen functionality. primary secondary tertiary quaternary

Pyridines. Pyridine is the simplest heterocycle of the azine type. It is derived from benzene by replacement of a CH group by a N-atom.

23.5 Nucleophilic Substitution in Nitro-Substituted Aryl Halides

Organic Chemistry CHM 224

Suggested solutions for Chapter 29

Lecture Notes Chem 51B S. King I. Conjugation

2016 Pearson Education, Inc. Isolated and Conjugated Dienes

Synthesis Using Aromatic Materials

Structure and Reactivity: Prerequired Knowledge

11/5/ Conjugated Dienes. Conjugated Dienes. Conjugated Dienes. Heats of Hydrogenation

CHEM50002: Orbitals in Organic Chemistry- Stereoelectronics. LECTURE 2 Stereoelectronics of Ground States Conformational Analysis

Learning Guide for Chapter 17 - Dienes

PAPER No. 5: REACTION MECHANISM MODULE No. 2: Types of Organic Reaction Mechanisms

Frost Circles a Great Trick

PAPER No. 05: TITLE: ORGANIC CHEMISTRY-II MODULE No. 12: TITLE: S N 1 Reactions

Chapter 16 Chemistry of Benzene: Electrophilic Aromatic Substitution

Lecture Notes Chemistry 342 Mukund P. Sibi Lecture 33 Amines

CHAPTER 19: CARBONYL COMPOUNDS III

Chapter 22: Amines. Organic derivatives of ammonia, NH 3. Nitrogen atom have a lone pair of electrons, making the amine both basic and nucleophilic

KOT 222 Organic Chemistry II

Benzene and Aromatic Compounds. Chapter 15 Organic Chemistry, 8 th Edition John McMurry

Chapter 15: Conjugated Systems, Orbital Symmetry, and UV Spectroscopy

REASONING QUESTIONS FROM ORGANIC CHEMISTRY (CH. 1 & 2)

PAPER No. 5:Organic Chemistry-2(Reaction Mechanism-1) MODULE No. 6: Generation, Structure, Stability and Reactivity of Carbocations

CARBONYL COMPOUNDS: OXIDATION-REDUCTION REACTION

Chapter 17. Reactions of Aromatic Compounds

Reactions. Reactions. Elimination. 2. Elimination Often competes with nucleophilic substitution. 2. Elimination Alkyl halide is treated with a base

1. Which of the following reactions would have the smallest energy of activation?.

THE CHEMISTRY OF THE CARBONYL GROUP

4 - BENZENE: AROMATICITY, CONJUGATION AND ASSOCIATED REACTIVITY

Additions to the Carbonyl Groups

Elimination. S N 2 in synthesis. S N 2 and E2. Kinetics. Mechanism bimolecular

Some Answers to Hour Examination #1, Chemistry 302/302A, 2004

18.8 Oxidation. Oxidation by silver ion requires an alkaline medium

16. Chemistry of Benzene: Electrophilic Aromatic Substitution. Based on McMurry s Organic Chemistry, 7 th edition

Chapter 20 Carboxylic Acid Derivatives Nucleophilic Acyl Substitution

Pyrrole reaction. Assis.Prof.Dr.Mohammed Hassan Lecture 4

Chemistry 234 Exam 1 (Gray) The Periodic Table

Aldehydes and Ketones : Aldol Reactions

b.p.=100 C b.p.=65 C b.p.=-25 C µ=1.69 D µ=2.0 D µ=1.3 D

There are two main electronic effects that substituents can exert:

17.3 REACTIONS INVOLVING ALLYLIC AND BENZYLIC ANIONS

Ketones and Aldehydes Reading Study Problems Key Concepts and Skills Lecture Topics: Structure of Ketones and Aldehydes Structure:

NO 2 O NH 2. Br Br. Br CF 3

Hour Examination # 1

Nuggets of Knowledge for Chapter 17 Dienes and Aromaticity Chem 2320

Pericyclic reactions

Organic Chemistry. M. R. Naimi-Jamal. Faculty of Chemistry Iran University of Science & Technology

Electrophilic Aromatic Substitution

Section Practice Exam II Solutions

240 Chem. Aromatic Compounds. Chapter 6

Benzene and Aromaticity

Benzenes & Aromatic Compounds

ζ ε δ γ β α α β γ δ ε ζ

and Ultraviolet Spectroscopy

Chemistry I (Organic) Aromatic Chemistry. LECTURE 4 Electrophilic Substitution (part 3)

Suggested solutions for Chapter 34

CHEM1902/ N-8 November Consider the following reaction sequences beginning with the carboxylic acid, E.

MCAT Organic Chemistry Problem Drill 10: Aldehydes and Ketones

b.(12) Where is pyrrole protonated under strong acidic conditions? Why this site of protonation?

Treatment of cyclooctatetrene with potassium gives you a dianion. Classify the starting material and product as aromatic, antiaromatic or

Benzene and Aromatic Compounds

Amines. Introduction Organic derivatives of ammonia. Many are biologically active.

Ch.16 Chemistry of Benzene: Electrophilic Aromatic Substitution

Aldol Reactions pka of a-h ~ 20

1/4/2011. Chapter 18 Aldehydes and Ketones Reaction at the -carbon of carbonyl compounds

CHE1502. Tutorial letter 201/1/2016. General Chemistry 1B. Semester 1. Department of Chemistry CHE1502/201/1/2016

Acid-Base -Bronsted-Lowry model: -Lewis model: -The more equilibrium lies to the right = More [H 3 O + ] = Higher K a = Lower pk a = Stronger acid

p Bonds as Electrophiles

Organic Chemistry II KEY March 27, Which of the following reaction intermediates will form the fastest in the reaction below?

Chapter 20 Carboxylic Acid Derivatives. Nucleophilic Acyl Substitution

75. A This is a Markovnikov addition reaction. In these reactions, the pielectrons in the alkene act as a nucleophile. The strongest electrophile will

Reactions of Benzene Reactions of Benzene 1

Chapter 13: Alcohols and Phenols

Chemistry of Benzene: Electrophilic Aromatic Substitution

Chapter 7 Substitution Reactions 7.1 Introduction to Substitution Reactions Substitution Reactions: two reactants exchange parts to give new products

25.3 THE CHEMISTRY OF FURAN, PYRROLE, AND THIOPHENE

Answers To Chapter 1 In-Chapter Problems.

Suggested solutions for Chapter 28

Transcription:

1 Chemistry II (rganic) eteroaromatic Chemistry LECTURE 6 Pyridines: properties, syntheses & reactivity Alan C. Spivey a.c.spivey@imperial.ac.uk Mar 2012

2 ormat & scope of lecture 6 Pyridines: structure, bonding & properties syntheses via cycloadditions via cyclisations reactivity electrophilic addition at (-oxides etc.) S E Ar S Ar tallation Supplementary slides 1-4 ybridisation and pka -oxides reactivity revision of S Ar mechanism

Pyridines Importance atural products: C 2 P 3 2 niacin - vitamin B3 (skin growth promotor) pyridoxal phosphate (cofactor for transaminases) nicotine (tobacco alkaloid stimulant) Pharmaceuticals: 5-T 1A receptor antagonist (antidepressant) Cl 2 S 2 sulpharpyridine (antibacterial) 2 isoniazide (antituberculosis) Agrochemicals: Cl C Cl Cl C dowco 263 (fungicide) 2 parinol (fungicide) Cl phenoxynicotinamide (herbicide) C 3

Benzene Pyridine Pyridine can be considered as benzene in which one C unit has been replaced by an iso-electronic unit it is no longer C6-symmetric but it retains 6p electrons and is still aromatic: sp 2 lone pair in the plane of the ring T involved in aromatic sextet C C C C C sp 2 hybrid C sp 2 hybrid : The M diagram for pyridine resembles that for benzene (lecture 1) but loss of symmetry loss of degeneracy: benzene 6 e's E 0 pyridine 6 e's E 0 As for pyrrole the energy match and orbital overlap between the -centred p-orbital and the adjacent C-centred p-orbitals is relatively poor so the resonance energy is lower than for benzene: 117 kjmol -1 cf. 152 kjmol -1

Pyridine: Calculated Electron Density Reactivity Like benzene, pyridine has 6 -electrons distributed over 6 atoms; owever, both induction and resonance effects draw electron density towards the atom so that the carbon framework is ELECTR DEICIET = The distribution of -electron density is manifested in its calculated -electron density and dipole moment (although this latter property is dominated by the sp 2 lone pair): The REACTIVITY of pyridine shows aspects which resemble the reactivity of: -electron density: dipole moment: 1.004 0.988 0.976 1.048 benzene: substitution reactions; resistance to addition/ring-opening (to avoid loss of resonance energy) tert-amines: protonation, alkylation, -oxide formation & co-ordination to Lewis acids by the lone pair: 2.2 D all 1.000 0 D e.g. m-cpba cf. m-cpba conjugated imines/carbonyl compounds: susceptibility to attack by nucleophiles at a/c2 and g/c4 positions: e.g. a u u hard u soft u g cf. a 2 u u u u g 4

Pyridine Structure and Properties A liquid bp 115 C Bond lengths, 1 and 13 C MR chemical shifts and coupling constants as expected for an aromatic system: bond lengths: 1.39 Å 1.39 Å 1.34 Å cf. ave C-C 1.48 Å ave C=C 1.34 Å ave C- 1.45 Å 13 C and 1 MR: 135.7 ppm 123.6 ppm 149.8 ppm 7-9 z 7.7 ppm 7.4 ppm 4-6 z 8.6 ppm Resonance energy: 117 kjmol -1 [i.e. lower than benzene (152)] can undergo nucleophilic addition reactions (particularly pyridinium salts) Electron density: electron deficient cf. benzene reactive towards nucleophilic substitution (S Ar), poorly reactive towards electrophilic substitution (S E Ar) = Basic (pk a 5.2) because the lone pair is T part of the aromatic sextet of electrons. Less basic than a tert-amine (e.g. Et 3, pk a 11) because of difference in hybridisation (sp 2 vs. sp 3 ; see supplementary slide 1):

Pyridines Syntheses Pyridines can be prepared by cycloaddition or cyclisations/cyclocondensation: some common approaches are:

Pyridines Synthesis by cycloaddition CYCLADDITI REACTIS: aza-diels-alder between aza-1,3-dienes and alkenes/alkynes (usually inverse electron demand) generally give non-aromatic heterocycles extrusion of small molecule(s) aromatic species 2-Aza-1,3-dienes: e.g. inverse electron demand hetero-diels-alder cycloaddition of 1,2,4-trazine with an enamine: 1-Aza-1,3-dienes: e.g. inverse electron demand hetero-diels-alder cycloaddition of a 1,2,3-trazine with an enamine:

Pyridines Synthesis by cyclisation/cyclocondensation Paal-Knorr (Type I): 1,5-dicarbonyl with 3 Guareschi (Type II): 1,3-dicarbonyl with 1 enamine antzsch: 1,3-dicarbonyl( 2) & aldehyde with 3 then oxidation (typically with 3, lecture 2)

Pyridines Reactivity Electrophilic addition to the pyridyl : Cr 2 7 & Cr 3 Cl PDC & PCC (oxidising agents) Ts PPTS (mild acid) Cr 2 7 S 3 sulfonylating agent Ts S 3 [] RCX R X acylpyridinium salts B 3.Et 2 -oxides B 3 Lewis acid dipolar adducts [] = e.g. m-cpba # Cl -oxides are particularly valuable because they: are more susceptible to S E Ar than pyridines: but react at C4 cf. C3 for pyridines (see later) are more susceptible to S Ar than pyridines: same selectivity: i.e. C4 > C2 >> C3 (see later) promote ortho-metallation (i.e. deprotonation) allow some synthetically useful rearrangements for details see supplementary slides 2-3

Pyridines Reactivity cont. Electrophilic substitution: via addition-elimination (S E Ar) reactivity: unreactive towards most electrophiles (E + ); <<benzene (relative rate 10-12 ); similar to nitrobenzene Two factors: 1) -deficient ; 2) salt formation via lone pair: regioselectivity: the kinetic 3- & 5-products predominate; reaction at these positions avoid unfavourable positive charge build-up on nitrogen in the Wheland-type intermediate: e.g. sulfonylation: (E + = S 3 + ) c. 2 S 4, gs 4 220 C S 3 [70%]

Pyridines Reactivity cont. ucleophilic substitution: via addition-elimination (S Ar) reactivity: reactive towards strong nucleophilies (u - ) regioselectivity: substitution at 4 & 2 positions (C4 > C2) isenheimer intermediates have negative charge stabilised on the electronegative nitrogen leaving group (LG) can be but Cl, Br, 2 etc. more facile nucleophiles include alkoxides, amines, thiolates, organolithiums and Grignard reagents u LG 4 rds addition u LG elimination u LG isenheimer intermediate...negative charge on nitrogen e.g. the Chichibabin reaction: (u - = 2-, LG = ) e.g. hydrazination: (u - = 2 4, LG = ) 4 2 4 2 4 2 2

Pyridines Reactivity cont. tallation ortho to : deprotonation by strong bases ortho to the with lithium amide bases possible but more facile on -oxide derivatives: i.e. the ortho directing effect of the LiBoc group overrides that of the ring but not that of the -oxide B. or an overview & mechanistic discussion see LECTURE 7 (also: Joule & Smith (5 th Ed) chapter 4). tallation at benzylic C2 & C4 positions: have similar acidity to protons a-to a carbonyl (pk a ~25) and can be readily deprotonated (even with alkoxides) to give enaminate anion:

Supplementary Slide 1 itrogen Basicity ybridisation of Lone Pair The basicity of a lone pair depends critically on its hybridisation state: e.g. sp 3 (25% s character) sp 2 (33% s character) sp (50% s character) cf. R R R R pk a = +11 pk a = +5.2 pk a = -10 R R R R R pk a = +50 pk a = +40 pk a = +25 R R rationale greater s-character: lower energy orbital (= more electronegative ) less able to carry +ive charge more able to carry -ive charge

Supplementary Slide 2 Pyridine--oxide reactivity S E Ar & S Ar Pyridine--oxides are more reactive towards S E Ar than pyridines & react at C4 (cf. C3 ) because: 1) the lone pair is no longer available to form unreactive salts ( faster reactions) 2) a resonance form in which an oxygen lone pair can help stabilise the positive charge in the Wheland intermediate is possible for reaction at C4 (& C2) ( different regioselectivity): Pyridine--oxides are also more reactive towards S Ar than pyridines because a resonance form in which the negative charge in the isenheimer intermediate is localised on the electronegative oxygen is possible for reaction at C4 & C2 (i.e. same regioselectivity as for pyridine): u u u C2 u u u C4

Supplementary Slide 3 Pyridine--oxide reactivity metallation & rearrangements Pyridine--oxides are more readily metallated (i.e. deprotonated) at the ortho positions than pyridines this is because the -oxide decreases pair-pair electron repulsions and increases chelation: Boc 1) LDA (2eq) T, -78 C 2) PhC [80%] Ph Boc cf. Boc 1) LDA (2eq) T, -78 C 2) PhC Ph Boc Pyridine--oxides also undergo some useful rearrangements to give oxygenated pyridines: 2-acetoxylation: Ac 2 100 C Ac nucleophilic attack at C-2 Ac 2 2 Ac Ac benzylic acetoxylation: Ac 2 100 C Ac C 2 benzylic deprotonation Ac Ac

2 2 2 Supplementary Slide 4 ucleophilic Aromatic Substitution: S Ar chanism: addition-elimination Rate = k[arx][y - ] (bimolecular but rate determining step does T involve departure of LG (cf. S 2) e.g. 4-fluoro nitrobenzene: 2 Y addition slow Y (rds) Y 2 isenheimer intermediate cf. Wheland Y Y elimination fast Y Y 2 notes Intermediates: energy minima Transition states: energy maxima isenheimer intermediate is T aromatic but stabilised by delocalisation Generally under kinetic control TS # 1 TS # 2 G u u reaction co-ordinate

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback