Answer:
[tex]49^oC[/tex]
Explanation:
At [tex]25^oC[/tex], the heat of vaporization of water is given by:
[tex]\Delta H^o_{vap} = 43988 J/mol\cdot \frac{1 mol}{18.016 g} = 2441.6 J/g[/tex]
The water here condenses and gives off heat given by the product between its mass and the heat of vaporization:
[tex]Q_1 = \Delta H^o_{vap} m_w[/tex]
The block of aluminum absorbs heat given by the product of its specific heat capacity, mass and the change in temperature:
[tex]Q_2 = c_{Al}m_{Al}(t_f - t_i)[/tex]
According to the law of energy conservation, the heat lost is equal to the heat gained:
[tex]Q_1 = Q_2[/tex] or:
[tex]\Delta H^o_{vap} m_w = c_{Al}m_{Al}(t_f - t_i)[/tex]
Rearrange for the final temperature:
[tex]\Delta H^o_{vap} m_w = c_{Al}m_{Al}t_f - c_{Al}m_{Al}t_i[/tex]
We obtain:
[tex]\Delta H^o_{vap} m_w + c_{Al}m_{Al}t_i = c_{Al}m_{Al}t_f[/tex]
Then:
[tex]t_f = \frac{\Delta H^o_{vap} m_w + c_{Al}m_{Al}t_i}{c_{Al}m_{Al}} = \frac{2441.6 J/g\cdot 0.48 g + 0.903 \frac{J}{g^oC}\cdot 55 g\cdot 25^oC}{0.903 \frac{J}{g^oC}\cdot 55 g} = 49^oC[/tex]
