Respuesta :
Explanation:
The given data is as follows.
Mass of ice dropped = 325 g
Initial temperature = [tex]30^{o}C[/tex] = (30 + 273) K = 303 K
Final temperature = [tex]0.0^{o}C[/tex] = (0 + 273) K = 273 K
Now, using density of water calculate the mass of ice as follows.
[tex]m_{ice} = \frac{500 ml \times 1.0 g/mol}{1 ml}[/tex]
= 500 g
As the relation between heat energy, specific heat and change in temperature is as follows.
Q = [tex]m \times C_{p} \times dT[/tex]
= [tex]\frac{500 g}{18 g/mol} \times 75.3 J/K/mol \times (303 - 273)K[/tex]
= 62750 J
Also, relation between heat energy and latent heat of fusion is as follows.
Q = m L
= [tex]\frac{325 g}{18 g/mol} \times 6 \times 10^{3}[/tex]
= 108300 J
Therefore, we require [tex]\frac{325 g}{18 g/mol} J[/tex] heat but we have 40774.95 J.
So, [tex]mass_{ice} = \frac{m \times C_{p} \times (T_{f} - T_{i})}{\Delta H_{f}}[/tex]
= [tex]\frac{62750 J}{333}[/tex]
= 188.4 g
Hence, the mass of ice = 325 g - 188.4 g
= 137 g
Therefore, we can conclude that 137 g of ice will still be present when the contents of the pitcher reach a final temperature.
