Question

Give two reasons why ethylene glycol has a higher boiling point than ethanol.

Short answer

Ethylene glycol has more hydrogen bonding and a slightly heavier structure than ethanol, leading to a higher boiling point.

Step-by-step solution

Understanding Boiling Points

Boiling points indicate the temperature at which a substance shifts from a liquid to a gas. They depend on the strength and types of intermolecular forces present within a molecule. The stronger these forces, the higher the boiling point.

Identify Intermolecular Forces in Ethanol

Ethanol, a two-carbon alcohol, has the molecular formula C₂H₅OH. The hydroxyl (-OH) group in ethanol allows hydrogen bonding, a relatively strong intermolecular force, which increases its boiling point.

Identify Intermolecular Forces in Ethylene Glycol

Ethylene glycol, C₂H₄(OH)₂, contains two hydroxyl (-OH) groups, which can form more hydrogen bonds than ethanol. More hydrogen bonding leads to stronger intermolecular attractions.

Compare the Number of Hydrogen Bonds

Due to having two -OH groups, ethylene glycol can potentially form double the amount of hydrogen bonds compared to ethanol. This results in a more significant collective strength of hydrogen bonding, raising its boiling point.

Consider Molecular Weight and Structure

Ethylene glycol has a similar molecular weight to ethanol but a slightly bulkier structure due to the additional -OH group. This contributes to increased van der Waals forces, further raising its boiling point.

Key concepts

Boiling Point

The boiling point of a substance is the temperature at which it transitions from a liquid to a gas. This transition occurs when the vapor pressure of the liquid equals the external pressure surrounding the liquid. An important aspect affecting boiling points is the strength of intermolecular forces present within the substance.

• Stronger intermolecular forces result in higher boiling points, as more energy is required to overcome these forces.
• Conversely, weaker intermolecular forces lead to lower boiling points.

Boiling points can also vary based on molecular weight and structure. For example, molecules with larger surface areas might exhibit stronger van der Waals forces. However, the presence of significant interactions like hydrogen bonds usually plays a more crucial role in determining the boiling point.

Hydrogen Bonding

Hydrogen bonding is a special type of intermolecular force that occurs when a hydrogen atom is bonded to a highly electronegative atom such as nitrogen, oxygen, or fluorine. This creates an attraction between the hydrogen and the electronegative atom of a neighboring molecule.

• Hydrogen bonds are relatively strong compared to other types of dipole-dipole interactions, which increases the boiling points of substances that can form them.
• These bonds lead to higher levels of molecular cohesion, requiring additional energy (in the form of heat) to break.

In substances like ethanol and ethylene glycol, the presence of hydroxyl (-OH) groups enables hydrogen bonding, contributing significantly to their respective boiling points. Ethylene glycol, with two -OH groups, forms more hydrogen bonds than ethanol, resulting in a higher boiling point due to increased intermolecular force overall.

Ethylene Glycol

Ethylene glycol is a colorless, sweet-tasting chemical compound with the chemical formula C₂H₄(OH)₂. It is commonly used as an antifreeze and a solvent in various industrial applications.

• Ethylene glycol has two hydroxyl (-OH) groups, which facilitates the formation of extensive hydrogen bonding networks.
• These additional hydrogen bonds strengthen the overall intermolecular forces, leading to a higher boiling point than other substances with fewer -OH groups, like ethanol.

Furthermore, while ethylene glycol has a molecular weight similar to ethanol, its structure allows it to form more robust interactions. This structure, along with increased hydrogen bonding, significantly elevates its boiling point compared to ethanol, making it particularly useful in applications where high thermal stability is required.