Write a Lewis structure for \(\mathrm{SbCl}_{5}\). Is the octet rule obeyed in this molecule?

Understanding valence electrons is crucial when it comes to forming Lewis structures. Valence electrons are the electrons located in the outermost shell of an atom, which are responsible for chemical bonding. For instance, the antimony (Sb) atom has 5 valence electrons, as it belongs to Group 15 of the periodic table. Chlorine (Cl), found in Group 17, has 7 valence electrons. When determining the number of valence electrons in a molecule like (SbCl_5), you would add up the valence electrons of the central atom (Sb) with those of all the surrounding atoms (Cl). For SbCl_5, this results in a total of 40 valence electrons, which are used to form bonds and fill the outer shells of the atoms.In summary, counting valence electrons correctly is an essential first step in predicting the molecular structure and reactivity.

The octet rule is a chemical rule of thumb that states atoms tend to combine in such a way that they each have eight electrons in their valence shell, obtaining a noble gas electron configuration. This rule guides the bonding behavior of most atoms, leading to a more stable molecular structure. However, there are exceptions. Molecules like (SbCl_5) showcase these exceptions. While chlorine atoms conform to the octet rule, the central antimony atom does not. Instead, it holds 10 electrons in its outer shell, surpassing the octet. This is possible because antimony is in the third period of the periodic table, which means it has d orbitals available that can accommodate more than eight electrons, leading to what is known as an 'expanded octet.'The realization that the octet rule is not universally applicable allows for a broader understanding of complex molecules and their bonding patterns.

Lewis structures are diagrams that represent the valence electron distribution around atoms within a molecule. They are fundamental for predicting the geometry and reactivity of molecules. Drawing Lewis structures involves several steps: counting valence electrons, constructing a skeletal structure, fulfilling the octet rule (when applicable), and minimizing formal charges to obtain the most stable structure.For (SbCl_5), as described in the step-by-step solution, you start by drawing the antimony atom (Sb) as the central atom, surrounded by chlorine atoms (Cl). Single bonds connect Sb to each Cl. After using 10 electrons to create these bonds, placing pairs around each Cl to complete their octets consumes the remaining 30 electrons. This results in each Cl atom having a full octet, while Sb exceeds it. Such diagrams are useful not just for visualizing the atoms’ connections but also for predicting molecular properties and the arrangement of electrons, which is vital for understanding chemical reactions.