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Ch.9 - Molecular Geometry and Bonding Theories
All textbooksBrown 14th EditionCh.9 - Molecular Geometry and Bonding TheoriesProblem 93c
Chapter 9, Problem 93c

An AB5 molecule adopts the geometry shown here. (c) Suppose the B atoms are halogen atoms. Of which group in the periodic table is atom A a member: (i) Group 15, (ii) Group 16, (iii) Group 17, (iv) Group 18, or (v) More information is needed?
Diagram of an AB5 molecule showing atom A at the center with five B atoms around it.

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1
Identify the geometry of the AB5 molecule. The image shows a trigonal bipyramidal geometry.
Determine the number of valence electrons for atom A. In a trigonal bipyramidal geometry, atom A must have 5 bonding pairs and no lone pairs.
Recall that halogen atoms (B) belong to Group 17 and each contributes 1 electron to the bond.
Calculate the total number of valence electrons needed for the AB5 molecule. Since there are 5 B atoms, each contributing 1 electron, atom A must provide 5 electrons.
Conclude that atom A must have 5 valence electrons, which corresponds to Group 15 in the periodic table.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Molecular Geometry

Molecular geometry refers to the three-dimensional arrangement of atoms within a molecule. In the case of an AB5 molecule, the central atom A is surrounded by five B atoms, which typically leads to a trigonal bipyramidal geometry. Understanding molecular geometry is crucial for predicting the shape and reactivity of molecules, as it influences properties such as polarity and intermolecular interactions.
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Periodic Table Groups

The periodic table is organized into groups, which are vertical columns that share similar chemical properties. Group 15 includes nitrogen and phosphorus, Group 16 includes oxygen and sulfur, Group 17 includes halogens like fluorine and chlorine, and Group 18 consists of noble gases such as helium and neon. Identifying the group of atom A is essential for understanding its chemical behavior and bonding characteristics with the halogen B atoms.
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Valence Electrons and Bonding

Valence electrons are the outermost electrons of an atom and play a key role in chemical bonding. The number of valence electrons determines how an atom interacts with others, including the formation of covalent bonds. In the context of the AB5 molecule, knowing the valence electron configuration of atom A helps in predicting its ability to bond with five halogen atoms, which typically have seven valence electrons and form single covalent bonds.
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Related Practice
Textbook Question

Ethyl propanoate, CH3CH2COOCH2CH3, gives a fruity pineapple-like smell. (a) Draw the Lewis structure for the molecule, assuming that carbon always forms four bonds in its stable compounds. (b) How many s and how many p bonds are in the molecule?

Textbook Question

Ethyl propanoate, CH3CH2COOCH2CH3, gives a fruity pineapple-like smell. (e) What are the approximate bond angles around each carbon atom in the molecule?

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Textbook Question

An AB5 molecule adopts the geometry shown here. (b) Do you think there are any nonbonding electron pairs on atom A?

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Open Question
The O-H bond lengths in the water molecule 1H2O are 96 pm, and the H-O-H angle is 104.5°. The dipole moment of the water molecule is 1.85 D. (c) Compare your answer from part (b) to the dipole moments of the hydrogen halides (Table 8.3). Is your answer in accord with the relative electronegativity of oxygen?
Textbook Question

The O¬H bond lengths in the water molecule 1H2O2 are 96 pm, and the H¬O¬H angle is 104.5°. The dipole moment of the water molecule is 1.85 D. (b) Calculate the magnitude of the bond dipole of the O¬H bonds. (Note: You will need to use vector addition to do this.)

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Textbook Question

a) Predict the electron-domain geometry around the central S atom in SF2, SF4, and SF6.

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