Question

Predict the geometric structures of (a) \(\mathrm{BrF}_{3} ;\) (b) IF \(_{5}\); (c) \(\mathrm{Cl}_{3} \mathrm{IF}^{-}\). (Central atom underlined.).

Short answer

The geometric structures of the molecules are: (a) \(\mathrm{BrF}_{3}\) - T-shaped, (b) IF\(_{5}\) - square pyramidal, (c) \(\mathrm{Cl}_{3} \mathrm{IF}^{-}\) - T-shaped

Step-by-step solution

Lewis Structure

Firstly, draw the Lewis structure for each molecule. The Lewis structure is a graphical representation of the molecule that shows how the electrons are arranged around individual atoms in the molecule.

Count electron regions

Using the Lewis structure, identify the regions where electrons are found. These include both bonding (shared) and nonbonding (unshared) electrons. Each bond, single, double or triple, counts as one region. The number of these regions helps determine the electron geometry.

Identify the molecular geometry

From the number of electron regions, use the VSEPR theory to predict the molecular geometry. If there are nonbonding electrons, it will affect the final molecular geometry.

Apply for each molecule

Repeat steps from 1 to 3 for each molecule. The Lewis structure, electron geometry, and molecular geometry for each are,\n (a) \(\mathrm{BrF}_{3}\): According to the VSEPR model, it exhibits a ‘T-shaped’ geometry. (b) IF \(_{5}\): The molecule adopts a square pyramidal geometry. (c) \(\mathrm{Cl}_{3} \mathrm{IF}^{-}\): The molecular geometry of \(\mathrm{Cl}_{3} \mathrm{IF}^{-}\) is T-shaped.

Key concepts

Molecular Geometry

Molecular geometry is the three-dimensional arrangement of atoms within a molecule. It determines both the shape and the angles between bonds, significantly influencing the molecule's chemical behavior and properties. The Valence Shell Electron Pair Repulsion (VSEPR) theory plays a key role in predicting molecular geometry.

VSEPR theory posits that electron pairs around a central atom will position themselves as far apart as possible to minimize repulsion. This arrangement of electron pairs can include both bonding pairs (associated with covalent bonds) and lone pairs (non-bonding pairs). These pairs influence the ideal bond angles, leading to specific geometric shapes.

• The nature and number of electron regions (places electrons are found) help define the molecular geometry. For instance, two electron pairs would generally form a linear shape, while three pairs could lead to a trigonal planar shape.
• The presence of lone pairs can alter the geometry by pushing bonding pairs closer together, as seen in the `T-shaped` formation for \(\mathrm{BrF}_{3}\).

Understanding molecular geometry is essential for grasping how chemical reactions occur, how molecules interact with one another, and predicting their physical properties.

Lewis Structure

The Lewis structure is a simplified representation of a molecule that displays how valence electrons are shared among the atoms. It highlights the bonds within a molecule and any lone pairs of electrons present. Creating a Lewis structure can be broken down into manageable steps:

• First, count the total number of valence electrons for all atoms involved in the molecule.
• Next, arrange the atoms to identify the central atom, typically the least electronegative, and connect other atoms around it using bonding pairs (lines).
• Distribute the remaining electrons as lone pairs to fulfill each atom’s octet (or duet, in the case of hydrogen) needs.

Constructing correct Lewis structures is important because they form the basis for predicting molecular geometry. They showcase how atoms within a molecule are connected, reflecting the molecule's initial three-dimensional arrangement before considering the geometry influenced by VSEPR. By analyzing the Lewis structure, one can identify the central atom’s electron regions, which guide the prediction of molecular shape.

Electron Regions

Electron regions refer to specific zones around the central atom where electrons tend to be concentrated. These can be either bonding pairs or lone pairs of electrons. Understanding these regions is crucial for applying the VSEPR theory effectively and accurately predicting molecular geometry.

In a molecule, each bond counts as one electron region, regardless of whether it is a single, double, or triple bond. Each lone pair of electrons also counts as one electron region. Identifying these regions involves:

• Examining the Lewis structure to count all bonds and lone pairs around the central atom.
• Using the total count of regions to determine the possible geometrical arrangement of these electron pairs around the central atom.

The number and type of electron regions influence the electron geometry, which is pivotal in determining the actual shape of the molecule. For example, five electron regions around a central atom can take on a trigonal bipyramidal arrangement, which might shift to a `T-shaped` molecular geometry when some of these regions consist of lone pairs, as seen in molecules like \(\mathrm{Cl}_{3}\mathrm{IF}^{-}\). By identifying all electron regions, the VSEPR model can be applied to predict molecular shapes accurately.