EBK CHEMISTRY: AN ATOMS FIRST APPROACH
EBK CHEMISTRY: AN ATOMS FIRST APPROACH
2nd Edition
ISBN: 9780100552234
Author: ZUMDAHL
Publisher: YUZU
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Chapter 8, Problem 162CP

a)

Interpretation Introduction

Interpretation: The partial pressure of ammonia after the completion of given reaction need to be determined.

Concept introduction:

  • Balanced equation of a reaction is written according to law of conservation of mass.
  • According toideal gas law: the pressure of gas is directly proportional to the number of moles of gas at constant volume and temperature.

Pn=RTV , P and n are proportional.

Mathematically, for two gases (1 and 2) at constant V and T,

P1n1=P2n2P1P2=n1n2

  • According toideal gas law, the volume of gas is directly proportional to the number of moles of gas at constant pressure and temperature.

Vn=RTP , V and n are proportional.

Mathematically, for two gas mixtures (1 and 2) at constant P and T,

V1n1=V2n2V1V2=n1n2

  • Mole ratios between the reactant and products of a reaction are depends upon the coefficients of respective reactant in a balanced chemical equation.
  • Partial pressure of a gas in a mixture of gases is the pressure of that gas when it alone.
  • Total pressure of a flask containing mixture of gases is the sum of individual partial pressures of constituted gases.

To determine: the partial pressure of ammonia after the completion of given reaction.

a)

Expert Solution
Check Mark

Answer to Problem 162CP

The partial pressure of NH3 in the container is 1.00atm .

Explanation of Solution

To find: the balanced chemical equation of the given reaction.

N2+3H22NH3

The reactants of the given reaction are N2 and H2 gases.

The product of the given reaction is NH3 .

Therefore,

The chemical equation of the reaction given is,

N2+H2NH3

This equation is not balanced, Balanced equation is the chemical equation of a reaction which is written according to law of conservation of mass the mass of reactant molecules should conserve in product molecules.

The balanced chemical equation of the given reaction is,

Balance the molecules in both sides of arrow in order of atoms other than hydrogen then hydrogen atoms.

Therefore, the balanced chemical equation of the given reaction will be,

N2+3H22NH3

Hence,

The balanced chemical equation for the given reaction is, N2+3H22NH3 .

To find: the limiting reagent in the given reaction of N2 and H2 .

H2 is the limiting reagent in the given reaction.

The partial pressures of each reactant gases are given as 1.00atm .

Therefore,

The partial pressure of N2 is 1.00atm .

The partial pressure of H2 is 1.00atm .

Initially the volume and temperature is constant.

According to ideal gas law, the pressure of gas is directly proportional to the number of moles of gas at constant volume and temperature.

Pn=RTV , P and n are proportional.

Mathematically, for two gases (1 and 2) at constant V and T,

P1n1=P2n2P1P2=n1n2

The partial pressures N2 and H2 are equal.

Therefore,

The number of moles N2 and H2 should be equal.

The balanced chemical equation for the given reaction is, N2+3H22NH3 .

Here, 1 mole of N2 is reacting with 3 moles of H2 . But in the given reaction the number of moles N2 and H2 are equal, so the H2 will finish first.

Limiting reagent: limiting reagent is a reactant, which consumes completely in the chemical reaction. The quantity of the product depends on this limiting reagent, it can be determined with the help of balanced chemical equation for the reaction.

Hence,

H2 is the limiting reagent in the given reaction.

#assumes the number of moles of N2 and H2 is as x.

To find: the number of moles produced NH3 , reacted N2 andremaining N2 in the given reaction.

The number of moles produced NH3 is 2x3mol .

The number of moles reacted N2 is x3mol .

The number of moles remaining N2 is 2x3mol .

The limiting reagent in the given reaction is H2 .

The balanced equation of given reaction is N2+3H22NH3 .

The mole ratio between NH3 and H2 is 2:3or1:32 .

If the number of moles of H2 is x, then the number of moles produced NH3 is,

xmolH2×2molNH33molH2=2x3molNH3

The mole ratio between reacted N2 and H2 is 1:3 .

If the number of moles of H2 is x, then the number of moles reacted N2 is,

xmolH2×1molN23molH2=x3molN2

The number of moles of taken N2 is x mole and the number of moles reacted N2 is x3mol .

Therefore,

The number of moles remaining N2 is xmolx3mol=2x3mol .

Hence,

The number of moles produced NH3 is 2x3mol .

The number of moles reacted N2 is x3mol .

The number of moles remaining N2 is 2x3mol .

To determine: the partial pressure of ammonia after the completion of given reaction.

The partial pressure of NH3 in the container is 1.00atm .

The initial total pressure of the container is given as 2atm . Since the pressure is constant in the entire reaction process, so after the completion of reaction also the pressure of the container will be 2atm .

The gaseous molecules presented after the completion of reaction are remaining N2 gas and produced NH3 .

The number of moles produced NH3 is calculated as 2x3mol .

The number of moles remaining N2 is calculated as 2x3mol .

So after the completion of reaction, the volume and temperature is constant.

According to ideal gas law, the pressure of gas is directly proportional to the number of moles of gas at constant volume and temperature.

Pn=RTV , P and n are proportional.

Mathematically, for two gases (1 and 2) at constant V and T,

P1n1=P2n2P1P2=n1n2

Therefore,

The partial pressures of NH3 and remaining N2 should be equal.

The total pressure of the container is given as 2atm .

That means,

PNH3+PN2=2atmPNH3=PN2=1atm

Hence,

The partial pressure of NH3 in the container is 1.00atm .

b)

Interpretation Introduction

Interpretation: The volume of the given container after the completion of given reaction are needed to be determined.

Concept introduction:

  • Balanced equation of a reaction is written according to law of conservation of mass.
  • According toideal gas law: the pressure of gas is directly proportional to the number of moles of gas at constant volume and temperature.

Pn=RTV , P and n are proportional.

Mathematically, for two gases (1 and 2) at constant V and T,

P1n1=P2n2P1P2=n1n2

  • According toideal gas law, the volume of gas is directly proportional to the number of moles of gas at constant pressure and temperature.

Vn=RTP , V and n are proportional.

Mathematically, for two gas mixtures (1 and 2) at constant P and T,

V1n1=V2n2V1V2=n1n2

  • Mole ratios between the reactant and products of a reaction are depends upon the coefficients of respective reactant in a balanced chemical equation.
  • Partial pressure of a gas in a mixture of gases is the pressure of that gas when it alone.
  • Total pressure of a flask containing mixture of gases is the sum of individual partial pressures of constituted gases.

To determine: the volume of the given container after the completion of given reaction.

b)

Expert Solution
Check Mark

Answer to Problem 162CP

The volume of the given container after the completion of given reaction is 10L .

Explanation of Solution

To determine: the volume of the given container after the completion of given reaction.

The volume of the given container after the completion of given reaction is 10L .

The number of moles produced NH3 is calculated as 2x3mol .

The number of moles remaining N2 is calculated as 2x3mol .

Therefore,

The total number of moles after the completion of given reaction is 2x3mol+2x3mol=4x3mol .

The initial number of moles is taken as nN2+nH2=x+x=2x .

The initial volume of container is given as 15L .

The reaction is carried under constant pressure and temperature.

According to ideal gas law, the volume of gas is directly proportional to the number of moles of gas at constant pressure and temperature.

Vn=RTP , V and n are proportional.

Mathematically, for two gas mixtures (1 and 2) at constant P and T,

V1n1=V2n2V1V2=n1n2

Therefore,

  • The relationship between final volume of the container to initial volume of container is,

    15LVinitial=4x3mol2x=23

That means,

The volume of the given container after the completion of given reaction is,

15L×23=10L .

Hence, the volume of the given container after the completion of given reaction is 10L .

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Chapter 8 Solutions

EBK CHEMISTRY: AN ATOMS FIRST APPROACH

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