To determine the physical states of these molecules at room temperature, we can look at their boiling points. Molecules with lower boiling points are more likely to exist as gases at room temperature. In this case, we can observe that all the molecules listed have relatively low boiling points, indicating that they primarily exist as gases at room temperature.
Now let's discuss the trends in bond length, bond strength, and bond angles within these molecules.
Bond Length Trend:
The bond length is the distance between the nuclei of the bonded atoms. In this case, we can observe that as we move down Group 15 of the periodic table from NH3 to SbH3, the bond length increases. This trend occurs because as we move down the group, the atomic size of the central atom increases. Larger atoms have larger electron clouds, which results in longer bond lengths. Therefore, the observed trend in bond length is that it increases as we move down the group NH3 to SbH3.
Bond Strength Trend:
Bond strength refers to the energy required to break a bond. It is related to the bond length and the nature of the atoms involved. In this case, we can observe that the bond strength gradually decreases as we move down Group 15, from NH3 to SbH3. This trend can be explained by the increasing size of the atoms. As the central atom gets larger, the bond length increases, and the bond strength decreases. This occurs because the larger atom's electrons are more spread out, resulting in weaker electrostatic forces between the atoms. Thus, the observed trend in bond strength is that it decreases as we move down the group NH3 to SbH3.
Bond Angle Trend:
The bond angle refers to the angle between two adjacent bonds in a molecule. In this case, we can observe that all the molecules listed have roughly similar bond angles (~107° for NH3, 93.5° for PH3, and 92° for AsH3 and SbH3). The decrease in bond angles from NH3 to PH3, and then to AsH3 and SbH3, is due to the increasing number of lone pairs of electrons on the central atom. These lone pairs occupy more space in the electron cloud, exerting greater repulsion on the bonding electrons and causing the bond angles to decrease. Therefore, the observed trend in bond angles is a gradual decrease from NH3 to AsH3 and SbH3.
Regarding intermolecular forces, these molecules primarily exhibit weak van der Waals forces between them, as they are nonpolar or weakly polar. These forces arise from temporary fluctuations in electron distributions and are weaker than other intermolecular forces such as hydrogen bonding or dipole-dipole interactions. These weak forces are responsible for the gas state of these molecules at room temperature.
I hope this explanation helps clarify the observed trends in bond length, bond strength, bond angles, and their relationship to intermolecular forces.