10: Polyatomic Molecules

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10.1: Hybrid Orbitals Account for Molecular Shape
This page covers valence bond theory, focusing on hybrid orbitals and their importance in understanding molecular structure and bonding in diatomic and polyatomic molecules. It details the formation of hybrid orbitals (such as \(sp\), \(sp^2\), and \(sp^3\)) in compounds like \(H_2\), \(BeH_2\), and \(CH_4\), while highlighting limitations in predicting geometries for polyatomic molecules.
10.2: Hybrid Orbitals in Water
This page explores Valence Bond Theory in relation to water's bonding and structure, specifically addressing its bond angle and lone pairs. It highlights how combining \(2s\) and \(2p\) orbitals through \(sp^3\) hybridization adjusts the bond angle from the theoretical 90° to the observed 104.45°, influenced by electron repulsion from lone pairs.
10.3: BeH₂ is Linear and H₂O is Bent
This page explains the construction of molecular orbitals in water using a linear triatomic model and a multi-centered approach, focusing on LCAO from hydrogen and atom \(A\). It highlights bonding and antibonding characteristics and the need for hybridization in molecules like BeH2.
10.4: Photoelectron Spectroscopy
This page covers photoelectron spectroscopy (PES) techniques, including X-ray (XPS) and Ultraviolet (UPS) spectroscopy, to analyze molecular orbitals and their kinetic energies. It discusses ionization energy concepts (adiabatic vs. vertical), binding energy, and workfunction, using examples like hydrogen and water to illustrate molecular orbital configurations.
10.5: The pi-Electron Approximation of Conjugation
This page discusses Hückel's theory as a method for approximating molecular orbital theory through the independent treatment of σ and π bonding in conjugated hydrocarbons like ethylene, highlighting sp² hybridization and unhybridized 2p_z orbitals. It covers the calculation of π molecular orbital energies, focusing on Coulomb and resonance integrals to derive energy levels and molecular orbitals.
10.6: Butadiene is Stabilized by a Delocalization Energy
This page explores the application of Hückel theory and molecular orbital theory to 1,3-butadiene, focusing on its molecular structure, electronic properties, and delocalization energy. The analysis shows the stability gained from resonant structures and delocalization, relating to the optimization of valence bond wavefunctions.
10.7: Benzene and Aromaticity
This page explains Hückel theory's application to cyclic conjugated hydrocarbons, focusing on benzene. It covers benzene's structure, resonance, and equal bond lengths, along with Hückel's Rule for cyclic polyenes possessing (4n+2) π electrons that exhibit aromaticity. The page highlights benzene's additional stability of 15 kJ mol-1 from double bond conjugation, supported by hydrogenation heat measurements, comparing its thermodynamic stability to other hydrocarbons.

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