For the following acid-base reaction balanced molecular, total ionic, and net ionic equations is to be written. Potassium hydroxide ( a q ) + hydrobromic acid ( a q ) → Concept introduction: Strong acids and strong bases are the substance that dissociates completely into its ions when dissolved in the solution. They dissociate completely in water to release H + ions and OH − ions. Weak acids and weak bases are the substance that does not dissociate completely into its ions when dissolved in the solution. They dissociate partially in water to release H + ions and OH − ions. The driving force of the acid-base reaction is the formation of a gaseous product or precipitate in the reaction. There are three types of equations that are utilized to represent an ionic reaction: 1. Molecular equation 2. Total ionic equation 3. Net ionic equation The molecular equation represents the reactants and products of the ionic reaction in undissociated form. In total ionic reaction, all the dissociated ions that are present in the reaction mixture are represented and in net ionic reaction, the useful ions that participate in the reaction are represented.

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Chapter 4, Problem 4.65P

(a)

Interpretation Introduction

Interpretation:

For the following acid-base reaction balanced molecular, total ionic, and net ionic equations is to be written.

Potassium hydroxide(aq)+hydrobromic acid(aq)→

Concept introduction:

Strong acids and strong bases are the substance that dissociates completely into its ions when dissolved in the solution. They dissociate completely in water to release H+ ions and OH− ions.

Weak acids and weak bases are the substance that does not dissociate completely into its ions when dissolved in the solution. They dissociate partially in water to release H+ ions and OH− ions.

The driving force of the acid-base reaction is the formation of a gaseous product or precipitate in the reaction.

There are three types of equations that are utilized to represent an ionic reaction:

1. Molecular equation

2. Total ionic equation

3. Net ionic equation

The molecular equation represents the reactants and products of the ionic reaction in undissociated form. In total ionic reaction, all the dissociated ions that are present in the reaction mixture are represented and in net ionic reaction, the useful ions that participate in the reaction are represented.

(b)

Interpretation Introduction

Interpretation:

For the following acid-base reaction balanced molecular, total ionic, and net ionic equations is to be written.

Ammonia(aq)+hydrochloric acid(aq)→

Concept introduction:

Strong acids and strong bases are the substance that dissociates completely into its ions when dissolved in the solution. They dissociate completely in water to release H+ ions and OH− ions.

Weak acids and weak bases are the substance that does not dissociate completely into its ions when dissolved in the solution. They dissociate partially in water to release H+ ions and OH− ions.

The driving force of the acid-base reaction is the formation of a gaseous product or precipitate in the reaction.

There are three types of equations that are utilized to represent an ionic reaction:

1. Molecular equation

2. Total ionic equation

3. Net ionic equation

The molecular equation represents the reactants and products of the ionic reaction in undissociated form. In total ionic reaction, all the dissociated ions that are present in the reaction mixture are represented and in net ionic reaction, the useful ions that participate in the reaction are represented.

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