Respuesta :
Answer:
Final temperature of solution is 27.48[tex]^{0}\textrm{C}[/tex]
Explanation:
Total volume of mixture = (60.0+60.0) mL = 120.0 mL
We know, density = (mass)/(volume)
So mass of mixture = [tex](120.0\times 1.13)g=135.6 g[/tex]
Amount of heat released per mol of [tex]H_{3}PO_{4}[/tex] = [tex]\frac{(m_{mixture}\times C_{mixture}\times \Delta T_{mixture})}{n_{H_{3}PO_{4}}}[/tex]
Where, m represents mass , C represents specific heat, [tex]\Delta T[/tex] represents change in temperature and n is number of moles
As this reaction is an exothermic reaction therefore temperature of mixture will be higher than it's initial temperature.
Let's say final temperature of mixture is T [tex]^{0}\textrm{C}[/tex]
So, [tex]\Delta T_{mixture}=(T-23.43)^{0}\textrm{C}[/tex]
Here [tex]m_{mixture}=135.6 g[/tex] and [tex]C_{mixture}=3.78J/(g.^{0}\textrm{C})[/tex]
Moles of H_{3}PO_{4} are added = [tex]\frac{0.200}{1000}\times 60.0moles[/tex] = 0.012 moles
So, [tex](173.2\times 10^{3})J=\frac{[(135.6g)\times (3.78J.g^{-1}.^{0}\textrm{C}^{-1})\times (T-23.43)^{0}\textrm{C}]}{0.012}[/tex]
or, T = 27.48[tex]^{0}\textrm{C}[/tex]
So, final temperature of solution is 27.48[tex]^{0}\textrm{C}[/tex]
