Electrostatic potential is map shows the charge distributions of a molecule in 3 D space. This helps us to analyse the behaviour of a molecule. Ex: Maximum electron density chemical region, minimum electron density region, shape and size of a molecule from the electrostatic potential map for ethylene oxide( CH 2 ) 2 O Predict interaction of ethylene oxide with another. Draw structure formula using the three- dimensional bond notation. Concept introduction: Electrostatic potential maps which shows the charge distribution a molecule in 3 D space. Electrostatic potential map is very similar to the fundamental structure of the two dimensional molecular structure. Red colour shows the lowest electrostatic potential, green show the highest electrostatic potential & intermediate colour show the intermediate. Potentials: Form this it becomes clear that red region shows higher electron density and blue region shows lower electron density.

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Chapter 11, Problem 105E

Interpretation Introduction

Interpretation:

Electrostatic potential is map shows the charge distributions of a molecule in 3D space.

This helps us to analyse the behaviour of a molecule.

Ex: Maximum electron density chemical region, minimum electron density region, shape and size of a molecule from the electrostatic potential map for ethylene oxide(CH₂)₂O

Predict interaction of ethylene oxide with another. Draw structure formula using the three- dimensional bond notation.

Concept introduction:

Electrostatic potential maps which shows the charge distribution a molecule in 3D space. Electrostatic potential map is very similar to the fundamental structure of the two dimensional molecular structure.

Red colour shows the lowest electrostatic potential, green show the highest electrostatic potential & intermediate colour show the intermediate.

Potentials: Form this it becomes clear that red region shows higher electron density and blue region shows lower electron density.

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