5 Must Know Facts For Your Next Test

1. The carbon-carbon triple bond in alkynes is formed by the overlap of two sp hybridized carbon atoms, resulting in a linear molecular geometry.
2. Alkynes are classified as a functional group in organic chemistry, characterized by the presence of the carbon-carbon triple bond.
3. The degree of unsaturation, which is a measure of the number of carbon-carbon multiple bonds in a molecule, can be calculated using the formula: Degree of Unsaturation = (2C + 2 - H + N) / 2 + 1, where C is the number of carbon atoms, H is the number of hydrogen atoms, and N is the number of nitrogen atoms.
4. Alkynes are named using the suffix '-yne' added to the parent alkane name, with the triple bond located at the lowest possible position.
5. Alkynes can be prepared through elimination reactions of dihalides, such as the dehydrohalogenation of vicinal dihalides.

Review Questions

• Explain the relationship between the sp hybridization of carbon atoms and the structure of acetylene (ethyne).
  • The carbon-carbon triple bond in acetylene (ethyne) is formed by the overlap of two sp hybridized carbon atoms. In sp hybridization, the s orbital and two of the p orbitals of the carbon atom mix to form three equivalent sp hybrid orbitals, which are arranged in a linear geometry. This allows the carbon atoms in acetylene to form two sigma (σ) bonds and one pi (π) bond, resulting in the characteristic linear structure and triple bond of the alkyne functional group.
• Describe how the degree of unsaturation can be used to identify the presence of alkynes in a molecule.
  • The degree of unsaturation is a useful tool for determining the presence of alkynes in a molecule. The formula for calculating the degree of unsaturation is: Degree of Unsaturation = (2C + 2 - H + N) / 2 + 1, where C is the number of carbon atoms, H is the number of hydrogen atoms, and N is the number of nitrogen atoms. For each carbon-carbon triple bond present in a molecule, the degree of unsaturation increases by 2. Therefore, the presence of an alkyne, with its characteristic carbon-carbon triple bond, will result in a higher degree of unsaturation compared to a saturated hydrocarbon of the same molecular formula.
• Propose a synthetic strategy for the preparation of an alkyne from a dihalide compound, and explain the mechanism of the elimination reaction involved.
  • One common method for the preparation of alkynes is the elimination reaction of dihalide compounds, such as the dehydrohalogenation of vicinal dihalides. In this reaction, the elimination of two halide atoms (e.g., Br or Cl) from adjacent carbon atoms results in the formation of a carbon-carbon triple bond. The mechanism typically involves the use of a strong base, such as an alkoxide or amide, which abstracts a proton from one of the alpha carbon atoms, leading to the formation of a carbanion intermediate. This carbanion then undergoes a second elimination step, expelling the halide from the adjacent carbon and generating the desired alkyne product. This synthetic strategy allows for the controlled introduction of alkynes into organic molecules, which can then be further functionalized through various addition and substitution reactions.

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