Answer:
[tex]a=5.65cm[/tex]
Explanation:
Hello,
In this case, for this heat transfer process in which the heat lost by the hot platinum is gained by the cold deuterium oxide based on the equation:
[tex]Q_{Pt}=-Q_{Deu}[/tex]
We can represent the heats in terms of mass, heat capacities and temperatures:
[tex]m_{Pt}Cp_{Pt}(T_f-T_{Pt})=-m_{Deu}Cp_{Deu}(T_f-T_{Deu})[/tex]
Thus, we solve for the mass of platinum:
[tex]m_{Pt}=\frac{-m_{Deu}Cp_{Deu}(T_f-T_{Deu})}{Cp_{Pt}(T_f-T_{Pt})} \\\\m_{Pt}=\frac{-1.00L*1110g/L*4.211J/(g\°C)*(41.9-25.5)\°C}{0.1256J/(g\°C)*(41.9-200.0)\°C} \\\\m_{Pt}=3860.4g[/tex]
Next, by using the density of platinum we compute the volume:
[tex]V_{Pt}=\frac{3860.4g}{21.45g/cm^3}\\ \\V_{Pt}=180cm^3[/tex]
Which computed in terms of the edge length is:
[tex]V=a^3[/tex]
Therefore, the edge length turns out:
[tex]a=\sqrt[3]{180cm^3}\\ \\a=5.65cm[/tex]
Best regards.
