Textbook Question
The acid-catalyzed dehydration we learned in this chapter is reversible, as shown below.
(c) Which side of the reaction would be favored by running the reaction at low temperatures?
10. Addition Reactions
Acid-Catalyzed Hydration
Back10. Addition Reactions
Acid-Catalyzed Hydration
- Textbook Question
Suggest a reagent to carry out each of the following conversions to an alcohol.
(b)
- Textbook Question
Predict the product(s) that would result when the following molecules are allowed to react under the following conditions: (iii) H2SO4 , H2O . If there is no reaction, write 'no reaction.'
(a)
- Textbook Question
Predict the product(s) that would result when the following molecules are allowed to react under the following conditions: (v) H2O. If there is no reaction, write 'no reaction.'
(a)
- Textbook Question
Predict the product(s) that would result when the following molecules are allowed to react under the following conditions: (vi) NaOH, H2O . If there is no reaction, write 'no reaction.'
(a)
- Textbook Question
The mechanism of the acid-catalyzed hydration of an alkene to make an alcohol is shown. If this reaction is reversible, draw a mechanism that justifies formation of the alkene from the alcohol under similar conditions. How do you know this mechanism is correct?
- Textbook Question
Would you expect the following to produce an equal or unequal mixture of stereoisomers?
(b)
- Textbook Question
Provide the expected product for the reaction of each of the following alkenes with H₂SO₄ and H₂O.
(d)
- Textbook Question
Provide the expected product for the reaction of each of the following alkenes with H2SO4 and H2O.
(d)
- Textbook Question
A chemist unsuccessfully attempted to produce the 1,4-cyclohexanediol by hydration of the cyclohexene shown.
(a) Provide a mechanism for the formation of the actual product.
(b) Suggest a pathway using acetyl chloride as a protecting group that will allow for the formation of the desired product.
- Textbook Question
The acid-catalyzed dehydration we learned in this chapter is reversible, as shown below.
(d) How might you shift the equilibrium to the right?
- Textbook Question
When combining isoprene equivalents, IPP is never the electrophile. Why might this be? What is special about DPP that allows it to function better as an electrophile? [Draw the carbocation that each becomes.]
- Textbook Question
Suggest a mechanism for the synthesis of farnesol beginning with IPP and DPP.
- Open Question
Draw a mechanism for the acid-catalyzed, nonenzymatic conversion of DPP to IPP. How do you know your mechanism is correct?
- Textbook Question
Provide the expected product for the reaction of each of the following alkenes with H2SO4 and H2O.
(b)