A 0.500-L sample of 0.200 M NaCl(aq) is added to 0.500 L of 0.200 M AgNO3(aq) in a calorimeter with a known total heat capacity equal to 4.60 × 10³ J·K^−1 at a constant pressure of one bar. The observed temperature change is +1.423 K. Use these data to determine the value of ΔH°rxn for the equation

Question

A 0.500-L sample of 0.200 M [latex]NaCl(aq)[/latex] is added to 0.500 L of 0.200 M [latex]AgNO_{3}(aq)[/latex] in a calorimeter with a known total heat capacity equal to [latex]4.60 × 10^{3}\ J·K^{−1}[/latex] at a constant pressure of one bar. The observed temperature change is +1.423 K. Use these data to determine the value of [latex]ΔH^{\circ}_{rxn}[/latex] for the equation

[latex]AgNO_{3}(aq) + NaCl(aq) → AgCl(s) + NaNO_{3}(aq)[/latex]

Accepted Answer

Stoichiometrically equivalent quantities of [latex]NaCl(aq)[/latex] and [latex]AgNO_{3}(aq)[/latex] are added to each other, and so there is no limiting reactant in this case. The observed increase in temperature arises from the formation of the precipitate [latex]AgCl(s)[/latex]. The number of moles of [latex]AgCl(s)[/latex] formed in the reaction is given by

[latex]moles\ of\ AgCl(s)\ formed = moles\ of\ AgNO_{3}(aq)\ or\ NaCl(aq)= (0.500\ L)(0.200\ mol·L^{–1}) = 0.100\ mol[/latex]

The value of ΔH for the formation of 0.100 moles of [latex]AgCl(s)[/latex] is

[latex]\Delta H = –c_{P,cal}\Delta T = –(4.60 × 10^{3}\ J·K^{–1})(1.423\ K) = –6550\ J[/latex]

his is the value of ΔH for the formation of 0.100 moles; thus, we have

[latex]ΔH^{\circ}_{rxn}=\frac{–6550\ J}{0.100\ mol} = –65.5 × 10^{3}\ J·mol^{–1} = –65.5\ kJ·mol^{–1}[/latex]

for the value of [latex]ΔH^{\circ}_{rxn}[/latex] for the formation of one mole of [latex]AgCl(s)[/latex].

Question 14.14: A 0.500-L sample of 0.200 M NaCl(aq) is added to 0.500 L of ......

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