Avg. 16.4 / 25 Stnd. Dev. 8.2



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

Experiment 6 Qualitative Tests for Alcohols, Alcohol Unknown, IR of Unknown

Laboratory 22: Properties of Alcohols

Assessment Schedule 2013 Chemistry: Demonstrate understanding of the properties of organic compounds (91391)

Chapter 22 Carbonyl Alpha-Substitution Reactions

Synthesis of Isopentyl Acetate

17.5 ALLYLIC AND BENZYLIC OXIDATION

Saturated NaCl solution rubber tubing (2) Glass adaptor (2) thermometer adaptor heating mantle

Experiment #8 properties of Alcohols and Phenols

ALCOHOLS: Properties & Preparation

Carboxylic Acid Derivatives and Nitriles

CHM220 Nucleophilic Substitution Lab. Studying S N 1 and S N 2 Reactions: Nucloephilic Substitution at Saturated Carbon*

Name. Department of Chemistry and Biochemistry SUNY/Oneonta. Chem Organic Chemistry II Examination #2 - March 14, 2005 ANSWERS

Unit 2 Review: Answers: Review for Organic Chemistry Unit Test

Alcohols. Copyright 2009 by Pearson Education, Inc. Copyright 2009 Pearson Education, Inc. CH 3 CH 2 CH 2 OH 1-propanol OH

Alcohols An alcohol contains a hydroxyl group ( OH) attached to a carbon chain. A phenol contains a hydroxyl group ( OH) attached to a benzene ring.

Electrophilic Aromatic Substitution

Properties of Alcohols and Phenols Experiment #3

Identification of Unknown Organic Compounds

Aldehydes can react with alcohols to form hemiacetals Nucleophilic substitution at C=O with loss of carbonyl oxygen

Chemical Reactions in Water Ron Robertson

IB Chemistry. DP Chemistry Review

Austin Peay State University Department of Chemistry CHEM 1021 TESTING FOR ORGANIC FUNCTIONAL GROUPS

Chapter 11 Homework and practice questions Reactions of Alkyl Halides: Nucleophilic Substitutions and Eliminations

MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

4/18/ Substituent Effects in Electrophilic Substitutions. Substituent Effects in Electrophilic Substitutions

Chapter 12 Organic Compounds with Oxygen and Sulfur

21.9 REDUCTION OF CARBOXYLIC ACID DERIVATIVES

INCOMPATIBILITY OF COMMON LABORATORY CHEMICALS

Carboxylic Acid Structure and Chemistry: Part 2

Unit 2: Quantities in Chemistry

Brønsted-Lowry Acids and Bases


EXPERIMENT 6 (Organic Chemistry II) Identification of Ketones and Aldehydes

Electrophilic Addition Reactions

CH 102 Practice Exam 2 PCC-Sylvania

Chemistry Diagnostic Questions

IB Chemistry 1 Mole. One atom of C-12 has a mass of 12 amu. One mole of C-12 has a mass of 12 g. Grams we can use more easily.

SUMMARY OF ALKENE REACTIONS

Nucleophilic Substitution and Elimination

stoichiometry = the numerical relationships between chemical amounts in a reaction.

Electrophilic Aromatic Substitution Reactions

1. The functional group present in carboxylic acids is called a A) carbonyl group. B) carboxyl group. C) carboxylate group. D) carbohydroxyl group.

Instructions Answer all questions in the spaces provided. Do all rough work in this book. Cross through any work you do not want to be marked.

The Aldol Condensation

Chapter 14 - Acids and Bases

UNIT (9) CARBOXYLIC ACIDS, ESTERS, AMINES, AND AMIDES

methyl RX example primary RX example secondary RX example secondary RX example tertiary RX example

SULFONATE AND INORGANIC ESTER DERIVATIVES OF ALCOHOLS

CHAPTER 7 ALCOHOLS, THIOLS, PHENOLS, ETHERS

ammonium salt (acidic)

Copyright 2010 Pearson Education, Inc. Chapter Fourteen 1

Equilibria Involving Acids & Bases

Stoichiometry. What is the atomic mass for carbon? For zinc?

Q.1 Classify the following according to Lewis theory and Brønsted-Lowry theory.

Unit 3 Notepack Chapter 7 Chemical Quantities Qualifier for Test

CHM220 Addition lab. Experiment: Reactions of alkanes, alkenes, and cycloalkenes*

Organic Chemistry, 5e (Bruice) Chapter 17: Carbonyl Compounds II

CHEM 105 HOUR EXAM III 28-OCT-99. = -163 kj/mole determine H f 0 for Ni(CO) 4 (g) = -260 kj/mole determine H f 0 for Cr(CO) 6 (g)

ORGANIC CHEMISTRY I PRACTICE EXERCISE Sn1 and Sn2 Reactions

Chemistry Assessment Unit AS 1

Summer Holidays Questions

Chapter 8 - Chemical Equations and Reactions

Q.1 Draw out some suitable structures which fit the molecular formula C 6 H 6

CHEMICAL REACTIONS AND REACTING MASSES AND VOLUMES

CHEMISTRY 101 EXAM 3 (FORM B) DR. SIMON NORTH

F322: Chains, Energy and Resources Alcohols

Reactions of Aldehydes and Ketones

Q.1 Carbonyl compounds are formed by oxidation of alcohols;

Introduction to Biodiesel Chemistry Terms and Background Information

Mass Spec - Fragmentation

Chemical Equations & Stoichiometry

Chemistry Notes for class 12 Chapter 13 Amines

REACTIONS OF SOME TRANSITION METAL IONS

Writing a Correct Mechanism

2. Rank the following three compounds in decreasing order of basicity. O NHCCH 3 NH 2

LABORATORY 5 DETECTION OF FUNCTIONAL GROUPS IN ORGANIC COMPOUNDS

ACID-BASE TITRATIONS: DETERMINATION OF CARBONATE BY TITRATION WITH HYDROCHLORIC ACID BACKGROUND

Write the acid-base equilibria connecting all components in the aqueous solution. Now list all of the species present.

IDENTIFICATION OF ALCOHOLS

Chem101: General Chemistry Lecture 9 Acids and Bases

SUBSTITUTION REACTION CHARACTERISTICS. Sn1: Substitution Nucleophilic, Unimolecular: Characteristics

A Grignard reagent formed would deprotonate H of the ethyl alcohol OH.

Q.1 Classify the following according to Lewis theory and Brønsted-Lowry theory.

ALKENES AND ALKYNES REACTIONS A STUDENT WHO HAS MASTERED THE MATERIAL IN THIS SECTION SHOULD BE ABLE TO:

Final Examination, Organic Chemistry 1 (CHEM 2210) December 2000 Version *A* A. B. C. D.

Chapter 17. How are acids different from bases? Acid Physical properties. Base. Explaining the difference in properties of acids and bases

Santa Monica College Chemistry 11

4.1 Stoichiometry. 3 Basic Steps. 4. Stoichiometry. Stoichiometry. Butane Lighter 2C 4 H O 2 10H 2 O + 8CO 2

Chapter 8: Chemical Equations and Reactions

Chapter 4 Chemical Reactions

Number of moles of solute = Concentration (mol. L ) x Volume of solution (litres) or n = C x V

Chapter 2 Polar Covalent Bonds; Acids and Bases

Solution a homogeneous mixture = A solvent + solute(s) Aqueous solution water is the solvent

Everything You Need to Know About Mechanisms. First rule: Arrows are used to indicate movement of electrons

Oxidation of Cyclohexanol to Cyclohexanone

Name Lab #3: Solubility of Organic Compounds Objectives: Introduction: soluble insoluble partially soluble miscible immiscible

Page Which hydrocarbon is a member of the alkane series? (1) 1. Which is the structural formula of methane? (1) (2) (2) (3) (3) (4) (4)

Decomposition. Composition

Safe Storage of Chemicals

Transcription:

QUIZ TREE Avg. 16.4 / 25 Stnd. Dev. 8.2

xidation of Alcohols with Chromium (VI): Jones xidation 2 Alcohols are oxidized by a solution of chromium trioxide in aqueous acetone (2), in the presence of an acid such as 2 S 4. This is called the Jones reagent, and the reaction of this mixture with an alcohol is called Jones oxidation. The acetone moderates the reaction and helps to solubilize the various reactions found in this oxidation. In a typical experiment using Na 2 Cr 2 7 in sulfuric acid, 3-pentanol (9) is converted to 3-pentanone (12) in 57% yield. Recognition that in aqueous solution Cr 3 is in equilibrium with Cr 3 7 2, allows the use Cr 3 as the active oxidizing agent to look at a simplified mechanism. 9 Na 2 Cr 2 7, acetone +, water 12

xidation of Alcohols with Chromium (VI): Jones xidation 3 The oxygen of the alcohol (a Lewis base) donates two electrons to chromium (Cr is a Lewis acid) to form oxonium salt 10. Transfer of the acidic proton of the oxonium salt in 10 to the chromate oxygen (the base) leads to a so-called chromate ester, 11. Formation of the chromate ester makes the hydrogen atom on the α-carbon acidic (marked in red in 11). Removal of that hydrogen by water is an acid-base reaction that leads to loss of the chromium(iii) leaving group, which is an elimination reaction that forms a new π-bond; a carbonyl (C=). If the chromium unit is viewed as a leaving group, then the hydrogen α- to the oxygen is lost to water and the leaving group is Cr 3. This mechanism predicts that the secondary alcohol (9) will be converted to 3-pentanone (12), which is an oxidation. Note the similarity of the oxidation of an alcohol to the elimination reaction of 11 via an E2 reaction (shown in the box) for conversion of an alkyl halide to an alkene. Cr Cr Cr 3 - Cr 3-3 + 9 10 11 12 Br E2 reaction + + Br

xidation of Alcohols with Chromium (VI): Aldehydes 4 Jones oxidation is such a powerful oxidizing medium that unwanted products are possible due to over-oxidation. When a primary alcohol such as 1-pentanol (15) reacts with chromium trioxide and aqueous sulfuric acid, it follows the same mechanistic pathway as 9, with formation of chromate ester 16. Experiments show that the yields of aldehyde from primary alcohols can be very low. 1-Propanol is oxidized to propanal, for example, in only 49% yield, and to obtain the product requires a short reaction time. Very often, a carboxylic acid is formed as a second product or even the major oxidation product rather than the aldehyde. It is known that aldehydes are easily oxidized to carboxylic acids, even by oxygen in the air.

xidation of Alcohols with Chromium (VI): Aldehydes 5 Formation of an aldehyde such as 17 in the presence of a powerful oxidizing agent such as chromium(vi), is usually followed by rapid oxidation of 17 to the corresponding carboxylic acid, pentanoic acid (18). In general, Jones oxidation of simple aldehydes usually gives the carboxylic acid as the major product. If the reaction mixture is heated, over-oxidation to the carboxylic acid is even more rapid. Cr 3 Cr 3, aq. + - Cr 3 Cr 3, aq. + 2-3 + 2 heat 15 16 17 18

xidation of Alcohols with Chromium (VI): Aldehydes 6 When acetone is used as a solvent the rate of oxidation of aldehyde to acid is relatively slow. Acetic acid (ethanoic acid) serves a similar role in many oxidations. This means that cold temperatures and short reaction times favor the aldehyde, but long reaction times and heat favor formation of the acid. The reaction of 19 with Cr 3 in sulfuric acid and aqueous acetic acid for several hours and then heated to 100 C gives carboxylic acid 20 was isolated in 82% yield. If the number molar equivalents of oxidizing agent is diminished, and the temperature is keep low with a short reaction time, aldehyde 21 is isolated in 59% yield. 3 In general, assume that oxidation of a secondary alcohol with chromium (VI) leads to a ketone and oxidation of a primary alcohol leads to an aldehyde if temperature and time are controlled. C 1.3 Cr 3, 2 S 4 2.1 Cr 3, 2 S 4 C aq. C 3 C aq. C 3 C 59% 0-5 C 25 C (overnight) 21 100 C (1 h) heat (10 minutes) 19 20 82%

xidation of Alcohols with Chromium (VI): Steric Effects 7 Alcohol 22 (2-methyl-3-pentanol) is oxidized faster than alcohol 24 (2,2,4,4-tetramethyl-3-pentanol). If both alcohols are converted to the corresponding chromate ester (23 and 25 respectively), the α-hydrogen (marked in red) must be removed in each case to give the ketone. The surrounding methyl groups in 25 create significant steric hindrance around the α-hydrogen, so it is more difficult for the base (water) to approach that hydrogen. The α-hydrogen in 23 is relatively unhindered and is easily removed by the base, so the rate of oxidation is relatively fast for 23 but slower for 25 due to steric hindrance in the chromate ester. The steric hindrance in the chromate ester makes it more difficult for the water to react with the α- proton. Note that the chromate ester is formed in both cases, and the steric hindrance to oxidation occurs in the chromate ester and not in the alcohol. Cr 3 FAST 22 23 2 Cr 3 SLW 24 25 2 very sterically hindered so it is difficult for 2 to collide with

xidation of Alcohols with Chromium (VI): PCC & PDC 8 The reaction of chromium trioxide (5) with pyridine, in aqueous Cl generates a specific compound known as pyridinium chlorochromate (PCC, 31) that is isolated and purified. The Cr 3 forms Cr 4 (6) in dilute aqueous acid, which reacts with Cl to form CrCl 3. Pyridine then reacts as a base with this acidic proton to form PCC. If the reaction conditions are modified to increase the amount of pyridine in the water solution. and the Cl is omitted, the reaction generates pyridinium dichromate (PDC, 32), presumably by reaction of an excess of pyridine with 2 Cr 2 7. In dilute solution, Cr 3 is in equilibrium with 2 Cr 2 7, and pyridine reacts with both acidic hydrogen atoms to produce PDC. Cr 3 Cl N N 31 32 2-2 Cr 2 7

xidation of Alcohols with Chromium (VI): PCC & PDC 9 Both PCC and PDC are less reactive than chromium trioxide in the Jones reagent, but they are very effective for converting primary alcohols to the aldehyde, in good yield and under mild conditions. Secondary alcohols are readily converted to ketones by both reagents. Dichloromethane is typically used as the solvent with both reagents. An example is the reaction of 2-cyclopentylethanol (33) and PCC in dichloromethane gave 1- cyclopentylethanal, 34 in 72% yield. The reaction of 4-propylcyclohexanol (35) and PDC, gives 4-propylcyclohexanone (36) in 97% isolated yield. PCC, C 2 Cl 2 C 72% 33 34 PDC, C 2 Cl 2 35 36 92%

xidation of Alcohols with DMS: Swern xidation 10 An oxidation reagent is derived from the reaction of dimethyl sulfoxide (DMS, 37) and oxalyl chloride (38). When 2-butanol is mixed with these reagents at 60 C, dimethyl sulfide (MeSMe) is observed as a product and 2-butanone (43) is isolated in 78% yield. This particular oxidation of an alcohol to a ketone or aldehyde is called the Swern oxidation. 3 C S 3 C + Cl 37 38 Cl - -60 C Me 41 3 C 3 C S + Me 43

xidation of Alcohols with DMS: Swern xidation 11 The mechanism proposed to explain these observations shows that the oxygen of DMS must attack the acyl carbon of oxalyl chloride in an acyl substitution reaction (chapter 19, section 19.2) to form an acyl-sulfonium derivative, 39. This intermediate decomposes with loss of carbon dioxide (C 2 ) and carbon monoxide (C) to give a chlorosulfonium salt, 40. Sulfonium salt 40 has an electrophilic sulfur that it attacked by the nucleophilic oxygen of an alcohol such as 2-butanol (41), at low temperatures (less than 60 C), to give 42. Intermediate 42 is related to intermediate 16 (the chromate ester of 19 discussed in section 17.2.B) in that a leaving group (Me 2 S) is lost and a hydrogen atom (in red in 42) is removed. Me 3 C 3 C - C 2 3 C S Cl Cl -60 C S - C Cl - 3 C S 41 3 C 3 C Cl 37 38 39 40 - Cl =SMe 2 Me 3 C 3 C + S S 3 C 42 3 C 43 +

xidation of Alcohols 12 Cr 3, 2 S 4 aq. acetone C 2 PDC C 2 Cl 2 C PCC C 2 Cl 2 C 2 DMS, -78 C oxalyl chloride C

xidation of Alkenes: Dihydroxylation 13 Cyclohexene was treated with s 4 (osmium tetroxide) in anhydrous 2-methyl-2-propanol (tert-butyl alcohol) at 0 C. After standing overnight, a 45% yield of cis-1,2cyclohexanediol (44) was isolated. This reaction is a dihydroxylation and the two units have a cis- relationship. Alkenes also react with dilute aqueous potassium permanganate to give a cis-diol. s 4, t-bu, 0 C 44 45%

xidation of Alkenes: Dihydroxylation 14 Both potassium permanganate (KMn 4 ) and osmium tetroxide (s 4 ) react with an alkene via 1,3-dipolar addition to give what is known a manganate ester (45) or an osmate ester (47). In the presence of aqueous hydroxide, 45 reacts to give 1,2-diol 46. In the osmium tetroxide reaction, aqueous sodium thiosulfite (NaS 3 ) or tert-butanol is used to convert 47 to diol 44. The conversion of an alkene to a diol is a formal oxidation Mn Mn 45 46 aq. NaS 3 s s 47 44

2024 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information