13. Alcohols and Carbonyl Compounds

Unfortunately, the use of NMO creates an additional green chemistry problem. What is the problem and how might it be solved?

A chronic alcoholic requires a much larger dose of ethanol as an antidote to methanol poisoning than does a nonalcoholic patient. Suggest a reason why a larger dose of the competitive inhibitor is required for an alcoholic.

Predict the products of the reactions of the following compounds with:

1. chromic acid or excess sodium hypochlorite with acetic acid.

2. PCC or NaOCl (1 equivalent) with TEMPO.

d. cyclohexanone

Predict the product(s) that would result when molecules (a)–(p) are allowed to react under the following conditions: (xi) HOCl, H₂O (xii) HIO₄ If no reaction occurs, write 'no reaction.'

(k)

Draw a mechanism for the following oxidation reactions.

(c)

Predict the product of the following oxidation reactions.

(a)

What product is obtained from the reaction of each of the following alcohols with

a. H₂CrO₄?

1. 3-pentanol

2. 1-pentanol

3. 2-methyl-2-pentanol

We have covered several oxidants that use a multi-valent atom (Cr, Cl, S, or I) as their active species, going from a higher oxidation state before the oxidation to a lower oxidation state after oxidizing the alcohol. Draw the Lewis structures of the following atoms, before and after the oxidation of an alcohol to a ketone or aldehyde. How many bonds to oxygen does each atom have before and after the oxidation?

a. the Cr in chromic acid

b. the Cl in sodium hypochlorite

c. the S in the Swern oxidation

Predict the product(s) that would result when molecules (a)–(p) are allowed to react under the following conditions: (xi) HOCl, H₂O (xii) HIO₄. If no reaction occurs, write 'no reaction.'  

(a)

What is the product of the reaction?

Predict the product(s) that would result when molecules (a)–(p) are allowed to react under the following conditions: (ix) PCC; (x) H₂CrO₄ , H₂O. If no reaction occurs, write 'no reaction.'  

(a)

Two unknowns, X and Y, both having the molecular formula C₄H₈O, give the following results with four chemical tests. Propose structures for X and Y consistent with this information.

A chemist attempted to oxidize a primary alcohol to a carboxylic acid using chromic acid. The product shown was obtained as a major component in the mixture. Suggest an arrow-pushing mechanism that accounts for its formation. [Think about what chromic acid would normally do to a phenol and make a list of bonds formed and bonds broken.]

Predict the major products of the following reactions, including stereochemistry where appropriate.

(n) sodium ethoxide + 2-methyl-2-bromobutane

(o) octan-1-ol + DMSO + oxalyl chloride

(p) 4-cyclopentylhexan-1-ol + DMP reagent

Chromic acid oxidation of an alcohol (Section 11-2A) occurs in two steps: formation of the chromate ester, followed by an elimination of H⁺ and chromium. Which step do you expect to be rate-limiting? Careful kinetic studies have shown that Compound A undergoes chromic acid oxidation over 10 times as fast as Compound B. Explain this large difference in rates.