13.5: Preparation of Alkynes from Alkynyl Anions

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Objectives

After completing this section, you should be able to

write an equation for the reaction that occurs between a terminal alkyne and a strong base, such as sodamide, NaNH₂.
rank a given list of compounds, including water, acetylene and ammonia, in order of increasing or decreasing acidity.
rank a given list of hydrocarbons, such as acetylene, ethylene and ethane, in order of increasing or decreasing acidity.
describe a general method for determining which of two given compounds is the stronger acid.
provide an acceptable explanation of why terminal alkynes are more acidic than alkanes or alkenes.

Key Terms

Make certain that you can define, and use in context, the key terms below.

acetylide anion
acidity order

Study Notes

An acetylide anion is an anion formed by removing the proton from the end carbon of a terminal alkyne:

An acidity order is a list of compounds arranged in order of increasing or decreasing acidity.

The general ideas discussed in this section should already be familiar to you from your previous exposure to chemistry and from the review in Section 2.8. A slightly different account of why terminal alkynes are stronger acids than are alkenes or alkanes is given below. However, the argument is still based on the differences between sp-, sp²- and sp³-hybrid orbitals.

The carbons of a triple bond are sp-hybridized. An sp‑hybrid orbital has a 50% s character and a 50% p character, whereas an sp²‑hybrid orbital is 33% s and 67% p, and an sp³‑hybrid orbital is 25% s and 75% p. The greater the s character of the orbital, the closer the electrons are to the nucleus. Thus in a C(sp)-H bond, the bonding electrons are closer to the carbon nucleus than they are in a C(sp²)-H bond. In other words, compared to a C(sp²)-H bond (or a C(sp³)-H bond), a C(sp)-H bond is very slightly polar: C^δ⁻-H^δ⁺. This slight polarity makes it easier for a base to remove a proton from a terminal alkyne than from a less polar or non-polar alkene or alkane.

As you will appreciate, the reaction between sodium amide and a terminal alkyne is an acid-base reaction. The sodium acetylide product is, of course, a salt. Terminal alkynes can also form salts with certain heavy-metal cations, notably silver(I) and copper(I). In the laboratory component of this course, you will use the formation of an insoluble silver acetylide as a method for distinguishing terminal alkynes from alkenes and non-terminal alkynes:

silver cations react with terminal alkynes in ammonium hydroxide:ethanol to give a silver acetylide, which is a white precipitate. internal alkynes and alkenes do not react under these conditions.svg

Metal acetylides are explosive when dry. They should be destroyed while still wet by warming with dilute nitric acid:

Acidity of Terminal Alkynes: Formation of Acetylide Anions

Terminal alkynes are much more acidic than most other hydrocarbons. Removal of the terminal proton leads to the formation of an acetylide anion, RC≡C:⁻.

Mechanism for reaction of a terminal alkyne with sodium amide to give an acetylide anion plus ammonia..svg

As discussed in Section 2.10, acidity typically increases with the stability of the corresponding conjugate base. The origin of the enhanced acidity of terminal alkynes can be attributed to the stability of the acetylide anion, which has the unpaired electrons in an sp hybridized orbital. The hybridization of an orbital affects its electronegativity. Within a shell, the s orbitals occupy the region closer to the nucleus than the p orbitals. Therefore, the spherical s orbitals are more electronegative than the lobed p orbitals. The relative electronegativity of hybridized orbitals increases as the percent s character increases and follows the order sp > sp² > sp³.

effect of hybridization on anion stability, where alkyl anions (25%s) are least stable, then vinyl anions (33%s), and acetylide anion (50%s) are the most stable.svg

This trend indicates the sp hybridized orbitals of the acetylide anion are more electronegative and better able to stabilize a negative charge than sp² or sp³ hybridized orbitals. There is a strong correlation between s-character in the orbital containing the non-bonding electrons in the anion and the acidity of hydrocarbons. The table below shows how orbital hybridization compares with the identity of the atom when predicting relative acidity. Remember that as the pK_a of a compound decreases its acidity increases.

Table \(\PageIndex{1}\): Akynes
Compound	Conjugate Base	Hybridization	"s Character"	pKa	C-H BDE (kJ/mol)
CH₃CH₃	CH₃CH₂⁻	sp³	25%	50	410
CH₂CH₂	CH₂CH⁻	sp²	33%	44	473
HCCH	HCC⁻	sp	50%	25	523

Acetylene, with a pK_a of 25 is shown to be much more acidic than ethylene (pK_a = 44) or ethane (pK_a = 50). Consequently, acetylide anions can be readily formed by deprotonation of a terminal alkynes with a sufficiently strong base. The amide anion (NH₂^-), in the form of sodium amide (NaNH₂) is commonly used for the formation of acetylide anions.

Example \(\PageIndex{1}\)

ethynylcyclopentane reacts with sodium amide to give an acetylide.svg

Exercise \(\PageIndex{1}\)

Given that the pKa of water is 14.00, would you expect hydroxide ion to be capable of removing a proton from each of the substances listed below? Justify your answers, briefly.

ethanol (pKa = 16)
acetic acid (pKa = 4.72)
acetylene (pKa = 25)

Answer

a. No, not very well. The pKa of ethanol is greater than that of water, thus the equilibrium lies to the left rather than to the right.Add texts here. Do not delete this text first.

b. Yes, very well. There is a difference of 11 pKa units between the pKa of water and the pKa of acetic acid. The equilibrium lies well to the right.

hydroxide reacts with acetic acid to give water and acetate, which favors the products (right hand side).svg

c. No, hardly at all. The hydroxide ion is too weak a base to remove a proton from acetylene. The equilibrium lies well to the left.

Objectives

After completing this section, you should be able to

write an equation to describe the reaction of an acetylide ion with an alkyl halide.
discuss the importance of the reaction between acetylide ions and alkyl halides as a method of extending a carbon chain.
identify the alkyne (and hence the acetylide ion) and the alkyl halide needed to synthesize a given alkyne.
determine whether or not the reaction of an acetylide ion with a given alkyl halide will result in substitution or elimination, and draw the structure of the product formed in either case.

Key Terms

Make certain that you can define, and use in context, the key term below.

alkylation

Study Notes

The alkylation of acetylide ions is important in organic synthesis because it is a reaction in which a new carbon-carbon bond is formed; hence, it can be used when an organic chemist is trying to build a complicated molecule from much simpler starting materials.

The alkyl halide used in this reaction must be primary. Thus, if you were asked for a suitable synthesis of 2,2-dimethyl-3-hexyne, you would choose to attack iodoethane with the anion of 3,3- dimethyl-1-butyne

3,3- dimethyl-1-butyne reaction with iodoethane to give 2,2-dimethylhex-3-yne and iodide anion.svg

rather than to attack 2-iodo-2-methylpropane with the anion of 1-butyne.

2-iodo-2-methylpropane reacts with the anion of 1-butyne to give elimination products.svg

The reasons will be made clear in Chapter 11.

Nucleophilic Substitution Reactions of Acetylides

The presence of lone pair electrons and a negative charge on a carbon, makes acetylide anions are strong bases and strong nucleophiles. Therefore, acetylide anions can attack electrophiles such as alkyl halides to cause a substitution reaction. These substitution reactions will be discussed in detail in Chapter 11.

Mechanism

The C-X bonds in 1^o alkyl halides are polarized due to the high electronegativity of the halogen. The electrons of the C-X sigma bond are shifted towards the halogen giving it a partial negative charge. This also causes electrons to be shifted away from the carbon giving it a partial positive and making it electrophilic. During this reaction, the lone pair electrons on the acetylide anion attack the electrophilic carbon in the 1^o alkyl halide forming a new C-C bond. The formation of this new bond causes the expulsion of the halogen as what is called a leaving group. Overall, this reaction forms a C-C bond and converts a terminal alkyne into a internal alkyne. Because a new alkyl group is added to the alkyne during this reaction, it is commonly called an alkylation.

reaction of a sodium acetylide anion with a primary alkyl halide gives an internal alkyne and NaX via an SN2 reaction.svg

This substitution reaction is often coupled with the acetylide formation, discussed in the previous section, and shown as a single reaction.

Example \(\PageIndex{1}\)

sodium but-1-yn-1-ide reacts with 1-bromobutane to give oct-3-yne.svg

ethynylcyclopentane reacts with 1. sodium amide, then 2. ethylbromide to give but-1-yn-1-ylcyclopentane.svg

Terminal alkynes can be generated through the reaction of acetylene and a 1^o alkyl halide.

acetylene reacts with sodium amide to give an acetylide anion, which then reacts with RCH2X to give a terminal alkyne.svg

Example \(\PageIndex{2}\)

acetylene reacts with 1. sodium amide, then 2. 1-bromopropane to give pent-1-yne.svg

Because the acetylide anion is a very strong base, this substitution reaction is most efficient with methyl or primary halides. Secondary, tertiary, or even bulky primary halogens will give alkenes by the E2 elimination mechanism discussed in Section 11.10. An example of this effect is seen in the reaction of bromocyclopentane with a propyne anion. The reaction produces the elimination product cyclopentene rather than the substitution product 1-propynylcyclopentane.

bromocyclopentane (a secondary alkyl halide) reacts with sodium prop-1-yn-1-ide to give cyclopentene, 1-propyne, and sodium bromide. Substitution product is not observed.svg

Nucleophilic Addition of Acetylides to Carbonyls

Acetylide anions also add to the electrophilic carbon in aldehydes and ketones to form alkoxides, which, upon protonation, give propargyl alcohols. With aldehydes and non-symmetric ketones, in the absence of chiral catalyst, the product will be a racemic mixture of the two enantiomers. These types of reaction will be discussed in more detail in Chapter 19.

acetylide anion attacks a carbonyl carbon to generate an alkoxide, which can be protonated to give an alcohol.svg

Exercise \(\PageIndex{1}\)

The pK_a of ammonia is 35. Estimate the equilibrium constant for the deprotonation of pent-1-yne by sodium amide, as shown below.

Answer: Assuming the pK_a of pent-1-yne is about 25, then the difference in pK_as is 10. Since pentyne is more acidic, the formation of the acetylide will be favored at equilibrium, so the equilibrium constant for the reaction is about 10¹⁰.

Exercise \(\PageIndex{2}\)

Give the possible reactants which could form the following molecules by an alkylation.

a. dec-4-yne and b. 1,2-dicyclohexylethyne.svg

Answer

dec-4-yne can be synthesized from a. hept-1-yne and 1-bromopropane or b. 1-bromopentane and pent-1-yne.svg

1,2-dicyclohexylethyne can be synthesized from ethynylcyclohexane and bromocyclohexane.svg

Exercise \(\PageIndex{3}\)

Propose a synthetic route to produce 2-pentene from propyne and an alkyl halide.

Answer

Exercise \(\PageIndex{4}\)

Using acetylene as the starting material, show how you would synthesize the following compounds

b) but-2-yne

Answer

acetylene reacts with 1. excess sodium amide, then 2. (3-bromopropyl)cyclohexane to give pent-4-yn-1-ylcyclohexane.svg

acetylene reacts with 1. excess sodium amide then 2. methylbromide to give 1-propyne, which reacts with 1. excess sodium amide, then 2. 1-bromopropane to give hex-2-yne.svg

Exercise \(\PageIndex{5}\)

Show how you would accomplish the following synthetic transformation.

acetylene reacts with ? to give 1-(but-1-yn-1-yl)cyclohexan-1-ol.svg

Answer