What Makes Ethanol Have a Higher Boiling Point Than Methanol and Ethyl Ether?

Why does methanol have a lower boiling point than ethanol even though ethanol is more polar?

Methanol has a lower boiling point than ethanol because ethanol has more electrons and is able to form stronger dipole-dipole interactions (a type of intermolecular force). Moreover, it also can form stronger hydrogen bonds due to its larger size and the presence of two hydrogen atoms.

Why does ethanol have a higher boiling point than ethyl ether, even though ethyl ether has a greater molecular mass?

Ethanol has a higher boiling point than ethyl ether, despite ethyl ether's greater molecular mass, due to ethanol's ability to form hydrogen bonds which are stronger than the dipole-dipole interactions and dispersion forces that ethyl ether can form.

Explanation:

The boiling point of a compound is determined by the strength of the intermolecular forces between its molecules. In the case of methanol and ethanol, although ethanol is more polar, the larger size and ability to form stronger hydrogen bonds make ethanol have a higher boiling point than methanol.

Similarly, ethanol has a higher boiling point than ethyl ether despite ethyl ether's greater molecular mass because ethanol's capacity to form hydrogen bonds surpasses the intermolecular forces that ethyl ether can create. This ability to form stronger hydrogen bonds results in ethanol having a higher boiling point compared to ethyl ether.

When comparing the boiling points of different compounds, it is crucial to consider the intermolecular forces that influence the boiling point. In the case of methanol and ethanol, although ethanol is more polar, the larger size and the presence of two hydrogen atoms allow ethanol to form stronger hydrogen bonds compared to methanol.

Ethanol's higher boiling point compared to ethyl ether can be attributed to its ability to form hydrogen bonds. While ethyl ether has a greater molecular mass, the hydrogen bonds formed by ethanol are stronger than the dipole-dipole interactions and dispersion forces present in ethyl ether. As a result, ethanol exhibits a higher boiling point.

Understanding the molecular structure and intermolecular forces at play provides insights into why ethanol, despite being more polar than methanol or having a greater molecular mass than ethyl ether, has a higher boiling point. The capacity to form stronger hydrogen bonds enhances ethanol's intermolecular forces, leading to a higher boiling point compared to both methanol and ethyl ether.