Understanding Boiling Points and Intermolecular Forces

Both have a molar mass of 126 g/mol

Both have a molar mass of 128 g/mol

126 g/mol for nonane and 128 g/mol for 2,3,4-trifluoropentane

128 g/mol for nonane and 126 g/mol for 2,3,4-trifluoropentane

It has a higher molar mass

It has fewer intermolecular forces

It has more intermolecular forces

It has a lower molar mass

Nonane has a higher molar mass

Nonane has weaker intermolecular forces

Nonane has more polar bonds

Nonane has longer carbon chains

It is less polar than the carbon-hydrogen bond

It is non-polar

It is more polar than the carbon-hydrogen bond

It is easier to break than the carbon-hydrogen bond

Longer chains have weaker London dispersion forces

Longer chains have stronger London dispersion forces

Chain length does not affect London dispersion forces

Shorter chains have stronger London dispersion forces

Boiling involves breaking covalent bonds

Boiling involves breaking intermolecular forces

Boiling is unrelated to molecular structure

Boiling is determined by molar mass

It suggests nonane has more polar bonds

It suggests boiling points are unrelated to polarity

It suggests 2,3,4-trifluoropentane has stronger intermolecular forces

It suggests nonane has a lower boiling point

Nonane has more polar bonds

Nonane has fewer carbon atoms

Nonane's carbon chains are further apart

Nonane's carbon chains are closer together

Nonane has weaker intermolecular forces

Nonane has longer carbon chains

Nonane has more polar bonds

Nonane has a higher molar mass

Molar mass

Intermolecular forces

Covalent bond strength

Electronegativity