ζ ε δ γ β α α β γ δ ε ζ

Similar documents
Chem 263 Nov 19, Cl 2

Chem 263 Nov 14, e.g.: Fill the reagents to finish the reactions (only inorganic reagents)

Aldehydes and Ketones : Aldol Reactions

Alpha Substitution and Condensations of Enols and Enolate Ions. Alpha Substitution

Chap 11. Carbonyl Alpha-Substitution Reactions and Condensation Reactions

Reactions at α-position

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

Ch 22 Carbonyl Alpha ( ) Substitution

CHAPTER 19: CARBONYL COMPOUNDS III

Chapter 19. Carbonyl Compounds III Reaction at the α-carbon

Aldol Reactions pka of a-h ~ 20

When we deprotonate we generate enolates or enols. Mechanism for deprotonation: Resonance form of the anion:

Chem 263 Nov 7, elimination reaction. There are many reagents that can be used for this reaction. Only three are given in this course:

Enols and Enolates. A type of reaction with carbonyl compounds is an α-substitution (an electrophile adds to the α carbon of a carbonyl)

20.3 Alkylation of Enolate Anions

Chem 263 March 28, 2006

Chem 263 Nov 3, 2016

A. Review of Acidity and pk a Common way to examine acidity is to use the Bronsted-Lowry acid-base equation:

MCAT Organic Chemistry Problem Drill 10: Aldehydes and Ketones

Carbonyl Chemistry IV + C O C. Lecture 10. Chemistry /30/02

Chem 263 Nov 24, Properties of Carboxylic Acids

Background Information

acetaldehyde (ethanal)

Lecture 3: Aldehydes and ketones

Chapter 19. Synthesis and Reactions of b-dicarbonyl Compounds: More Chemistry of Enolate Anions. ß-dicarbonyl compounds. Why are ß-dicarbonyls useful?

Another Equilibrium: Reaction At The α-position

Chapter 22 Enols and Enolates

Chapter 23. Alpha Substitution of Carbonyl Compounds.

Lecture 19. Carboxylic Acids O C OH O R C O - + H + O - Chemistry 328N

Chapter 19. Organic Chemistry. Carbonyl Compounds III. Reactions at the a-carbon. 4 th Edition Paula Yurkanis Bruice

Electrophile = electron loving = any general electron pair acceptor = Lewis acid, (often an acidic proton)

Lecture Notes Chem 51C S. King Chapter 24 Carbonyl Condensation Reactions

What is in Common for the Following Reactions, and How Do They Work?

Chem 263 Notes March 2, 2006

Nucleophilic Addition Reactions of Carboxylic Acid Derivatives

Chapter 8: Nucleophilic Substitution 8.1: Functional Group Transformation By Nucleophilic Substitution

Organic Chemistry Review: Topic 10 & Topic 20

7. Haloalkanes (text )

Module No and Title. PAPER No: 5 ; TITLE : Organic Chemistry-II MODULE No: 25 ; TITLE: S E 1 reactions

12/27/2010. Chapter 15 Reactions of Aromatic Compounds

ORGANIC - BRUICE 8E CH CARBONYL COMPOUNDS III: REACTIONS AT THE ALPHA-CARBON

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

(c) The intermediate carbocation resulting from 3-bromobut-1-ene is resonance stabilized.

Chapter 20 Carboxylic Acid Derivatives Nucleophilic Acyl Substitution

Chapter 10: Carboxylic Acids and Their Derivatives

Chapter 15 Reactions of Aromatic Compounds

18.8 Oxidation. Oxidation by silver ion requires an alkaline medium

But in organic terms: Oxidation: loss of H 2 ; addition of O or O 2 ; addition of X 2 (halogens).

Chapter 6 Ionic Reactions-Nucleophilic Substitution and Elimination Reactions of Alkyl Halides"

Chapter 6: Organic Halogen Compounds; Substitution and Elimination Reactions

CHAPTER 23 HW: ENOLS + ENOLATES

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

Chapter 17. Reactions of Aromatic Compounds

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

Elimination Reactions Heating an alkyl halide with a strong base causes elimination of a. molecule of HX

CHEM Chapter 23. Carbonyl Condensation Reactions (quiz) W25

CHE1502. Tutorial letter 203/1/2016. General Chemistry 1B. Semester 1. Department of Chemistry

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

Carboxylic Acids and Nitriles

Lecture 13A 05/11/12. Amines. [Sn2; Hofmann elimination; reduction of alkyl azides, amides, nitriles, imines; reductive amination; Gabriel synthesis]

Chem 263 March 7, 2006

C h a p t e r T w e n t y - o n e : Enols, Enolates, and Aldol-like Condensations

Homework problems Chapters 6 and Give the curved-arrow formalism for the following reaction: CH 3 OH + H 2 C CH +

Chapter 7: Alcohols, Phenols and Thiols

Lecture Topics: I. Electrophilic Aromatic Substitution (EAS)

Aldehydes and Ketones

Chapter 9. Nucleophilic Substitution and ß-Elimination

Aldehydes, Ketones and Carboxylic acids

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

Chapter 20 Carboxylic Acid Derivatives. Nucleophilic Acyl Substitution

CH 3 CHCH 3 CH 3 CHCH 3 Isopropyl cation. Oxomium ion intermediate. intermediate (an electrophile)

(Neither an oxidation or reduction: Addition or loss of H +, H 2 O, HX).

12. Aldehydes & Ketones (text )

ANSWER GUIDE APRIL/MAY 2006 EXAMINATIONS CHEMISTRY 249H

Chapter 16 Aldehydes and Ketones I. Nucleophilic Addition to the Carbonyl Group

Organic Chemistry, Third Edition. Chapter 24 Carbonyl condensations

Summary of π Bond Chemistry

Preparation of Alkyl Halides, R-X. Reaction of alkanes with Cl 2 & Br 2 (F 2 is too reactive, I 2 is unreactive): R + X X 2.

Topic 9. Aldehydes & Ketones

The Claisen Condensation

Important Concepts. Problems. Chapter Problems. Cuprate additions followed by enolate alkylations. 15. Michael Addition (Section 18-11)

Organic Chemistry, 7 L. G. Wade, Jr. Chapter , Prentice Hall

(1) Recall the different types of intermolecular interactions. (2) Look at the structure and determine the correct answer.

Organic Reactions Susbstitution S N. Dr. Sapna Gupta

Chapter 17 Reactions of Aromatic Compounds. Electrophilic Aromatic Substitution

Loudon Chapter 14 Review: Reactions of Alkynes Jacquie Richardson, CU Boulder Last updated 1/16/2018

Chapter 15. Reactions of Aromatic Compounds. Electrophilic Aromatic Substitution on Arenes. The first step is the slow, rate-determining step

CHEM 234: Organic Chemistry II Reaction Sheets

CARBONYL COMPOUNDS: OXIDATION-REDUCTION REACTION

Chapter 8. Substitution reactions of Alkyl Halides

Name. Department of Chemistry SUNY/Oneonta. Chem Organic Chemistry II Examination #3 - March 31, 2003

REACTIONS OF HALOALKANES - SUBSTITUTION AND ELIMINATION

Chapter 9 Aldehydes and Ketones Excluded Sections:

THE CHEMISTRY OF THE CARBONYL GROUP

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

Lecture Notes Chemistry Mukund P. Sibi Lecture 36 Synthesis of Amines

18.10 Conjugate Additions O O. O X BrCH 2 CH 2 CH 2 CCH 3 ± ± BrCH 2 CH 2 CH 2 CH 3. TsOH 1 O C O O W 3 CH 3 CCH 3 CH 3 CCH 2 CH 2 CH 2 CH 3

Organic Chemistry CHM 314 Dr. Laurie S. Starkey, Cal Poly Pomona Alkyl Halides: Substitution Reactions - Chapter 6 (Wade)

BSc. II 3 rd Semester. Submitted By Dr. Sangita Nohria Associate Professor PGGCG-11 Chandigarh 1

Transcription:

hem 263 Nov 17, 2016 eactions at the α-arbon The alpha carbon is the carbon adjacent to the carbonyl carbon. Beta is the next one, followed by gamma, delta, epsilon, and so on. 2 ε 2 δ 2 γ 2 2 β α The positions of the carbons are shown in Greek letters. Similarly, the hydrogens attached to a carbon at a particular position are named the same as the carbon at that position. For example, the hydrogens attached to the alpha (α) carbon are known as alpha hydrogens, the hydrogens attached to the beta (β) carbon are called beta hydrogens, and so on. The hydrogen attached to the carbonyl carbon in an aldehyde is called the aldehyde hydrogen or formyl hydrogen (not an alpha hydrogen). Do not get these confused. The atoms in ketones are described similarly to aldehydes: ζ ε δ γ β α α β γ δ ε ζ ζ ε δ γ β α α β γ δ ε ζ Example: α Β α Β Β Β Due to polarization of the carbonyl bond, the carbons nearby have alternating partial negative and positive charge associated with them. The carbons that are farther away from the carbonyl experience less polarization than the carbon in the alpha position.

δ + δ + δ + δ + δ + δ + Alpha hydrogens are acidic (pka ~ 20). These hydrogens can be deprotonated to make an enolate, which can go on to react with electrophiles. eview: Keto-enol tautomerism enol keto The process of converting between the keto and enol forms is called tautomerism. Tautomers are rapidly interconverting structural isomers (different molecules because the hydrogen has moved in its position of attachment therefore not stereoisomers). For most molecules, the equilibrium lies on the right, with the keto form being the more stable form. Enolates are the conjugate bases of enols and can be prepared using a strong base: B enol B enolate The two structures shown above of the enolate are resonance forms (different pictures of the same molecule; no atom has moved and only the positions of the electrons have been moved). Many bases can be used, but a common base used to irreversibly form an enolate at low temperature is lithium diisopropyl amide (LDA). The pka of diisopropyl amine (conjugate acid of LDA) is around 36. Potassium tert-butoxide (K-t-Bu or t-buk) can also be used, but this reaction is reversible as the pka of tert-butyl alcohol is 19. In general, a good nucleophile is likely to attack the carbonyl group to form a tetrahedral intermediate. n the other hand, a good base deprotonates the alpha hydrogen as shown below:

' Good Nucleophile Nu ' pk a ~ 20 :Nu Good base ' Below are the structures of LDA and t-buk, two common strong bases. N Y: N Li Y: Li pka ~ 36 LDA Diisopropyl amine 3 3 3 K Y: 3 K Y: 3 3 pka ~ 19 tbu0k tert-butyl alcohol Why does LDA remove the alpha-hydrogen instead of attacking the carbonyl? Answer: LDA is a bulky base. The approach to the carbonyl carbon is somewhat sterically hindered. Instead, it pulls off the hydrogen at the alpha position, as the alpha hydrogen has a partial positive charge associated with it. Generally, nucleophiles are best if they are unhindered (not bulky). Bases are better if they are bulky, to avoid nucleophilic attack.

General eaction E E B The reaction can be irreversible for both steps (depending on the conditions). The electrophile E + can be X + from X 2 (halogens) or + from alkyl halide (-X), amongst other things. eactions of Enolates: X X X 2 alogenation Alkylation Aldol eaction X + where X = l, Br, I + e.g. - 2 -X X Acylation eg. X Enolate halogenation LDA l 2 l hloroacetone is used in tear gas. chloroacetone In this reaction, chlorine is the electrophile that reacts with the nucleophilic enolate. The first step of the reaction is the formation of the enolate by using lithium diisopropylamide (LDA) (also depicted as :B - in some cases below). LDA is a strong, bulky base, which will remove the alpha hydrogen to produce the resonance stabilized enolate anion. In the second step, the enolate attacks chlorine and breaks the weak l-l bond to form the halo ketone and the chloride anion. The l-l bond is susceptible to attack because the two electronegative chlorines pull electrons out of the bond making it weak.

N l l N Li l + l - + B- Li or: K-t-Bu In the above example, the addition of chlorine makes the alpha hydrogens of the product (chloroacetone) even more acidic due to the electron withdrawing effect of the chlorine. Side reactions, including multiple chlorinations are possible, as shown in the next section. The aloform eaction (Not discussed in class) A problem with doing the above reaction under basic conditions using sodium hydroxide is due to a side reaction called the haloform reaction. The haloform reaction converts a methyl ketone into a carboxylic acid salt and a haloform (chloroform, l 3 ; bromoform, Br 3 ; or iodoform, I 3 ) and may be used as a qualitative test for methyl ketones. A sample of an unknown structure (which may be a methyl ketone) is dissolved in TF or ether, and dilute solutions of aqueous Na and I 2 are added. Formation of a yellow precipitate of solid iodoform signals a positive test and indicates that the sample is a methyl ketone as shown below in the general example. X 2 Na 3 Na X 3 2 - Na + + X 3 X = l, Br, I When acetone is reacted with excess l 2 and aqueous Na, multiple chlorinations occur to form trichloroacetone as shown before. This is then followed by attack of the hydroxide ion on the carbonyl to form a tetrahedral intermediate. This intermediate then displaces the -l 3 group by donation of a lone pair of electrons from the oxygen to reform the carbonyl. The l 3 group leaves as a stabilized anion because the three electron withdrawing chlorine atoms are capable of stabilizing the negative charge. Proton transfer then leads to the products.

l 2 l 3 Na l 3 l 3 Na + l 3 Enol Formation (Under acidic conditions) Enols behave as nucleophiles and react with electrophiles in much the same way as enolates. The main difference between the two is that enols are formed under acidic conditions and enolates under basic conditions. The general mechanism of enol formation is shown below. Protonation of the carbonyl oxygen makes the alpha proton more acidic and deprotonation at the alpha carbon occurs to form the enol. The enol and keto forms are tautomers (interconverting structural isomers). An electron pair from the enol oxygen reforms the double bond and attacks an electrophile, forming a new carbon-electrophile bond. Loss of a proton from the oxygen yields a neutral alpha-substitution product as the carbonyl is reformed. + E + E - + E keto form enol form An example is the chlorination of acetone under acidic conditions. Monochlorination is hard to control under aqueous basic conditions and there is the competing haloform reaction (see above). Under acidic conditions, this is easy to do with 1 molar equivalent (1 eq.) of chlorine gas. l l 2 (1 eq.) l Enolate Alkylation eactions An important reaction of enolate ions is their alkylation by treatment with an alkyl halide. The alkylation reaction is useful because it forms a new - bond. Alkylation occurs when a nucleophilic enolate ion reacts with the electrophilic alkyl halide in an S N 2 reaction and displaces the leaving group by backside attack as shown in the general mechanism below.

B X B- 2 X Alkylation reactions are subject to all the rules that affect all S N 2 reactions. The leaving group X in the alkylating agent can be chloride, bromide, iodide, or tosylate. The alkyl halide works best if it is primary and preferably allylic or benzylic. Secondary halides react poorly, and tertiary halides don t react at all because of competing E2 elimination. Vinylic and aryl halides are also unreactive, because S N 2 attack is sterically prevented. The below example shows the ant alarm pheromone, (S)-4-methylheptan-3-one. This compound is synthesized using the alkylation reaction of an enolate. There are two possible enolates that can be used in this reaction. The first possibility is the use of the enolate of 3-pentanone and reaction with 1-iodopropane. The second possibility is the use of the enolate of 3-heptanone and reaction with methyl iodide. (S)-4-methylheptan-3-one I 3 I

Acidic ydrogens Both enolates lead to same product I The alkylation of 3-heptanone with methyl iodide is a poor choice for this synthesis. Upon enolate formation of 3-heptanone, two possible enolates can be formed because the molecule is unsymmetrical. Therefore, alkylation can occur at the 2 and 4 positions of 3- heptanone. base 3 -I The alkylation of 3-pentanone with 1-iodopropane is the best choice because upon enolate formation, there is only one enolate formed because the molecule is symmetrical. In this reaction is important to know that the alkylation product is racemic (1:1 mixture of enantiomers) because there is no stereochemical control. base I An example is the alkylation of 2,2-dimethylcyclohexanone with LDA and benzyl chloride to give the benzyl substituted product shown below. The enolate undergoes an S N 2 attack of the methylene bearing the chloride to give the final product. LDA l

An additional example of an alkylation of 2,2-dimethylcyclohexanone with LDA and isopropyl iodide. K 2 equiv I 2 equiv The same reaction with a tertiary alkyl halide will not proceed because it s too hindered for S N 2 I X No Sn2 Aldol Formation The base induced aldol formation is a general reaction for ketones and aldehydes with alpha hydrogen atoms. If the ketone or aldehyde does not have alpha hydrogens, the aldol reaction cannot occur. Aldol condensations occur by nucleophilic addition of the enolate ion of the donor molecule to the carbonyl group of the acceptor molecule, yielding a tetrahedral intermediate that is protonated to give the aldol product (a β-hydroxy carbonyl compound). This reaction is completely reversible under aqueous conditions, and can revert to the starting materials in the presence of base and water. LDA + Another example: an aldol B tetrahedral intermediate Aldol β-hydroxy ketone

Aldol Formation with Dehydration The β-hydroxy ketones and β-hydroxy aldehydes formed in the aldol process can easily be dehydrated (- 2 ) to yield conjugated enones called α,β-unsaturated carbonyl compounds by the application of heat with acid or base. Aldol β-hydroxy ketone + or base Δ α,β-unsaturated carbonyl compound + 2 An example is the aldol condensation of 2,2-dimethylcyclohexanone with benzaldehyde. The aldol product dehydrates readily to form the extended conjugated system. LDA + then workup add water or base Enolate Acylation (addition of an acyl group) ecall that acylium groups are and that you can add an acylium group using one of the three following reagents l Similar to above, enolates can attack an acyl group to form a tetrahedral intermediate and release a good leaving group next to the carbonyl group. The general mechanism is as shown below:

Base Y Y = l, Br, I,, Y Y An example: Treat acetophenone with LDA first, and then with acetyl chloride to yield a diketone. 1) LDA 2) l

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