The value of Δ G ° for following reaction at 25 ° C is to be calculated. N 2 ( g ) + 2 H 2 ( g ) → N 2 H 4 ( l ) Concept introduction: Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by Δ G ° f . The general expression for Δ G ° f is as follows: Δ G ° = Δ G ° f ( product ) − Δ G ° f ( reactant ) For example, formation reaction of ammonia is as follows: N 2 ( g ) + 3 H 2 ( g ) → 2 NH 3 ( g ) Standard free-energy change of 2 mol of ammonia is − 33.0 kJ , thus free-energy change of formation of 1 mole ammonia is equal to − 16.5 kJ .

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Answer 1

Question

Chapter 18, Problem 18.97SP

Interpretation Introduction

Interpretation:

The value of ΔG° for following reaction at 25 °C is to be calculated.

N2(g)+2H2(g)→N2H4(l)

Concept introduction:

Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by ΔG°f. The general expression for ΔG°f is as follows:

ΔG°=ΔG°f(product)−ΔG°f(reactant)

For example, formation reaction of ammonia is as follows:

N2(g)+3H2(g)→2NH3(g)

Standard free-energy change of 2 mol of ammonia is −33.0 kJ, thus free-energy change of formation of 1 mole ammonia is equal to −16.5 kJ.

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Answer 2

Question

Chapter 18, Problem 18.97SP

Interpretation Introduction

Interpretation:

The value of ΔG° for following reaction at 25 °C is to be calculated.

N2(g)+2H2(g)→N2H4(l)

Concept introduction:

Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by ΔG°f. The general expression for ΔG°f is as follows:

ΔG°=ΔG°f(product)−ΔG°f(reactant)

For example, formation reaction of ammonia is as follows:

N2(g)+3H2(g)→2NH3(g)

Standard free-energy change of 2 mol of ammonia is −33.0 kJ, thus free-energy change of formation of 1 mole ammonia is equal to −16.5 kJ.

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Check out a sample textbook solution

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Answer 3

Question

Chapter 18, Problem 18.97SP

Interpretation Introduction

Interpretation:

The value of ΔG° for following reaction at 25 °C is to be calculated.

N2(g)+2H2(g)→N2H4(l)

Concept introduction:

Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by ΔG°f. The general expression for ΔG°f is as follows:

ΔG°=ΔG°f(product)−ΔG°f(reactant)

For example, formation reaction of ammonia is as follows:

N2(g)+3H2(g)→2NH3(g)

Standard free-energy change of 2 mol of ammonia is −33.0 kJ, thus free-energy change of formation of 1 mole ammonia is equal to −16.5 kJ.

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Answer 4

Question

Chapter 18, Problem 18.97SP

Interpretation Introduction

Interpretation:

The value of ΔG° for following reaction at 25 °C is to be calculated.

N2(g)+2H2(g)→N2H4(l)

Concept introduction:

Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by ΔG°f. The general expression for ΔG°f is as follows:

ΔG°=ΔG°f(product)−ΔG°f(reactant)

For example, formation reaction of ammonia is as follows:

N2(g)+3H2(g)→2NH3(g)

Standard free-energy change of 2 mol of ammonia is −33.0 kJ, thus free-energy change of formation of 1 mole ammonia is equal to −16.5 kJ.

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Answer 5

Chapter 18, Problem 18.97SP

Interpretation Introduction

Interpretation:

The value of ΔG° for following reaction at 25 °C is to be calculated.

N2(g)+2H2(g)→N2H4(l)

Concept introduction:

Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by ΔG°f. The general expression for ΔG°f is as follows:

ΔG°=ΔG°f(product)−ΔG°f(reactant)

For example, formation reaction of ammonia is as follows:

N2(g)+3H2(g)→2NH3(g)

Standard free-energy change of 2 mol of ammonia is −33.0 kJ, thus free-energy change of formation of 1 mole ammonia is equal to −16.5 kJ.

Answer 6

Chapter 18, Problem 18.97SP

Interpretation Introduction

Interpretation:

The value of ΔG° for following reaction at 25 °C is to be calculated.

N2(g)+2H2(g)→N2H4(l)

Concept introduction:

Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by ΔG°f. The general expression for ΔG°f is as follows:

ΔG°=ΔG°f(product)−ΔG°f(reactant)

For example, formation reaction of ammonia is as follows:

N2(g)+3H2(g)→2NH3(g)

Standard free-energy change of 2 mol of ammonia is −33.0 kJ, thus free-energy change of formation of 1 mole ammonia is equal to −16.5 kJ.

Answer 7

Chapter 18, Problem 18.97SP

Interpretation Introduction

Interpretation:

The value of ΔG° for following reaction at 25 °C is to be calculated.

N2(g)+2H2(g)→N2H4(l)

Concept introduction:

Standard free-energy of formation use to define the free-energy change for formation of 1 mol of substance in its standard state. The reactants must be in their maximum stable form of constituent elements. It is denoted by ΔG°f. The general expression for ΔG°f is as follows:

ΔG°=ΔG°f(product)−ΔG°f(reactant)

For example, formation reaction of ammonia is as follows:

N2(g)+3H2(g)→2NH3(g)

Standard free-energy change of 2 mol of ammonia is −33.0 kJ, thus free-energy change of formation of 1 mole ammonia is equal to −16.5 kJ.

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Answer 11

Ch. 18 - Which of the following reactions has a decrease in...Ch. 18 - CONCEPTUAL APPLY 18.2 Consider the gas-phase...Ch. 18 - Consider the distribution of ideal gas molec ules...Ch. 18 - (a) Which state has the higher entropy? Explain in...Ch. 18 - Calculate the standard entropy of reaction for...Ch. 18 - The unbalanced reaction for the combustion of...Ch. 18 - Calculate the value of Stotal, and decide whether...Ch. 18 - Use the values of Hof, and So in Appendix B to...Ch. 18 - Consider the decomposition of gaseous N2O4:...Ch. 18 - Prob. 18.10A

Solution Summary: The author explains the value of Delta G° for following reaction at 25° C.

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