IB Docs (2) Team MC test: Intermolecular forces
Multiple choice test on 4.4 Intermolecular forces
Use the following 'quiz' to test your knowledge and understanding of this sub-topic. You will need access to a periodic table (Section 6 of the IB data booklet).
If you get an answer wrong, read through the explanation carefully to learn from your mistakes.
The following substances all possess intermolecular hydrogen bonding. Which one has the highest boiling point?
The boiling points of NH3, HF and CH3OH are −33.3, +19.5 and +64.7 oC respectively. Water has the highest boiling point as it has two non bonding pairs of electrons, the polarity of the O atom is 2δ− and each molecule of water can form hydrogen bonds to two other water molecules.
Which molecule will be polar?
Although they all contain polar bonds the resultant dipole in CO2, CCl4 and BCl3 is zero.
Which are classified as van der Waals' forces of attraction?
I. London (dispersion) forces
II. Dipole-dipole forces
III. Dipole-induced dipole forces
All of these are relatively weak attractive forces and all come under the heading of van der Waals' forces. It is debatable whether hydrogen bonding should also come under this heading. In past IB multiple choice questions the IB has signified that hydrogen bonding is not included but many text books and web sites etc. would disagree with this.
Which is the correct order of increasing forces of attraction between atoms or molecules (weakest first)?
Covalent bonding is much stronger than the other three and London forces are the weakest. Hydrogen bonding is stronger than dipole-dipole.
Butane H3CCH2CH2CH3, propanone H3CCOCH3 and propan-1-ol, H3CCH2CH2OH all have a similar molar mass. Which is the correct order of their increasing boiling points (lowest first)?
Butane molecules have London forces between them, propanone molecules have dipole-dipole as the strongest intermolecular force between them and propan-1-ol molecules can form hydrogen bonds with other propan-1-ol molecules.
Which explains why the boiling points of the halogens increase down the group from fluorine to iodine?
Because all the halogens are simple diatomic molecules they are all non-polar. The only attractive forces between them are weak London (dispersion) forces.
Butan-1-ol, H3CCH2CH2CH2OH and butan-2-ol, H3CCH2CH(OH)CH3 both have the same mass. The boiling point of butan-1-ol is 117.7 oC and the boiling point of butan-2-ol is 99.0 oC. Which best explains why butan-1-ol has a higher boiling point than butan-2-ol.
The polarity of the O−H bond is the same (or at least very similar) in both molecules but the intermolecular forces of attraction also depend upon the contact surface area between the molecules.
Which best describes all the forces of attraction present between butanal (H3CCH2CH2CHO) molecules?
There are always London (dispersion) forces between any two molecules. Butanal is polar so there will also be dipole-dipole forces of attraction but as the hydrogen atom is bonded to carbon not oxygen there will be no hydrogen bonding.
Methoxymethane, H3COCH3 and ethanol, C2H5OH are isomers. Which best explains why ethanol has a considerably higher boiling point than methoxymethane?
Because H is bonded directly to O in ethanol there will be hydrogen bonding between ethanol molecules but in methoxymethane the O is bonded to C, not H, so no hydrogen bonding is possible.
The solubility of alcohols in water decreases in the order methanol > ethanol> propan-1-ol > butan-1-ol with methanol being the most soluble. Why does the solubility of alcohols in water follow this order?
The hydrocarbon chain is non-polar so tends to attract the non-polar hydrocarbon chain of other alcohol molecules through London forces of attraction. This attraction increases as the chain length increases.
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