Based on the characteristics of the MO diagram of cyclobutadienyl dication, it is to be determined if it is aromatic, antiaromatic, or nonaromatic. Concept introduction: To derive the relative energies of pi molecular orbitals, a Frost method is used. This method is applicable to any species with a fully conjugated, cyclic pi system. This method involves drawing a polygon that represents the cyclic compound’s line structure, with one of the vertices pointing directly upwards. Each of the four vertices then represents the energy of a π MO (π 1 , π 2 , π 3 , and π 4 * ) , and the center of the square represents the energy of each unhybridized p atomic orbitals. Aromatic compounds have cyclic π systems that are unusually stable. Antiaromatic compounds have cyclic π systems that are unusually unstable. Nonaromatic compounds are neither unusually stable nor unusually unstable.

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Chapter 14, Problem 14.14P

Interpretation Introduction

Interpretation:

Based on the characteristics of the MO diagram of cyclobutadienyl dication, it is to be determined if it is aromatic, antiaromatic, or nonaromatic.

Concept introduction:

To derive the relative energies of pi molecular orbitals, a Frost method is used. This method is applicable to any species with a fully conjugated, cyclic pi system. This method involves drawing a polygon that represents the cyclic compound’s line structure, with one of the vertices pointing directly upwards. Each of the four vertices then represents the energy of a π MO (π1, π2, π3, and π4*), and the center of the square represents the energy of each unhybridized p atomic orbitals.

Aromatic compounds have cyclic π systems that are unusually stable.

Antiaromatic compounds have cyclic π systems that are unusually unstable.

Nonaromatic compounds are neither unusually stable nor unusually unstable.

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