Organic Chemistry As a Second Language: First Semester Topics
4th Edition
ISBN: 9781119110668
Author: David R. Klein
Publisher: WILEY
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Chapter 4.3, Problem 4.19P
Interpretation Introduction
Interpretation:
The geometry of oxygen atom has to be predicted using VSEPR theory.
Concept Introduction:
Geometry of a compound is how the atoms that are present in the compound is connected in a 3D space. In order to find the geometry of the compound, the first thing that must be known was how the atoms bond with each other. Each and every atom in a compound is connected through bonds and the bonds are formed by overlapping orbitals.
Simple atomic orbitals are s and p orbitals. Generally in
To find the hybridization state of atom we start by counting the number of bonds the atom has and the lone pair of electrons present. The below table can be used to find the hybridization of atom,
| Sum of bonded atoms and lone pairs | Number of hybridized orbitals |
| 4 | 4 |
| 3 | 3 |
| 2 | 2 |
From the hybridization state of the atoms we can identify the geometry of the same. For finding the geometry, the lone pair of electrons also has to be considered. This complete details are given in the following table,
| Hybridization along with lone pair | Geometry |
| Tetrahedral | |
| Trigonal pyramidal | |
| Bent | |
| Trigonal planar | |
| Bent | |
| Linear |
Lone pair of electrons occupy the hybridized orbitals. If the same lone pair of electrons is involved in resonance means, then it does not occupy the hybridized orbital. Hence, the hybridization state of the atom changes which in turn changes the geometry of the atom.
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Chapter 4 Solutions
Organic Chemistry As a Second Language: First Semester Topics
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