Asked by Sarah
Calculate the change in entropy that occurs when 17.68 g of ice at -12.7°C is placed in 54.05 g of water at 100.0°C in a perfectly insulated vessel. Assume that the molar heat capacities for H2O(s) and H2O(l) are 37.5 J K-1 mol-1 and 75.3 J K-1 mol-1, respectively, and the molar enthalpy of fusion for ice is 6.01 kJ/mol.
Answers
Answered by
Jennifer
the heat capacities are given in units of moles and Kelvins, so you'll have to convert everything to these units
The weight of one mole of H2O = 1.008*2 + 15.999 = 18.015 g
17.68 g ice = 17.68g * (1 m / 18.015 g ) = .981 moles ice = .981 mole H20
54.05 g water = 3 moles liquid water
T(Kelvin) = T(Celsius) + 273
-12.7 C = 260.3 K
100 C = 373 K
First, the ice is brought to its melting point of 273 K:
37.5 J K-1 mol-1*.981 mol = 36.79 J K-1
The entropy change for this process is 36.79 ln (Tf - Ti)
where Tf is final temperature (273 K); Ti is initial temperature (260.3 K)
= 36.79 ln(12.7) = 93.5 J/K
Next, the ice melts:
.981 * 6.01 kJ/mol = 5.89 kJ
for a change of state at constant temperature the entropy change is
Q/T = 5.89 kJ / 273 K = 21.6 J/K
Next 17.68 g of ice at 273 K and 54.05 g water reach the same temperature; Using the first law of thermodynamics, deltaQ for this entire process is zero because the container is insulated. Summing up the heats of all the processes to 0:
36.79 J K-1 (273-260.3) + 5890 + .981 *75.3*(Tf-273) + 3*75.3*(Tf - 373) = 0
467.23 + 5890 + 73.87*(Tf-273) + 225.9*(Tf-373) = 0
6356 + 73.87*Tf - 20166 + 225.9*Tf - 84261 = 0
6356 +299.77*Tf - 104427 = 0
299.77*Tf = 98071
Tf = 327 K This is the final temperature of the mixture after it has reached equilibrium.
The change in entropy in bringing the melted ice to this temperature is
.981*75.3*ln(327-273) = 294.6 J/K
The change in entropy in bringing the liquid water down to this temperature is
3*75.3*ln(327-373) = an imaginary number
The total change in entropy is 93.5 J/K + 21.6 J/K + 294.6 J/K = 409.4 J/K
The weight of one mole of H2O = 1.008*2 + 15.999 = 18.015 g
17.68 g ice = 17.68g * (1 m / 18.015 g ) = .981 moles ice = .981 mole H20
54.05 g water = 3 moles liquid water
T(Kelvin) = T(Celsius) + 273
-12.7 C = 260.3 K
100 C = 373 K
First, the ice is brought to its melting point of 273 K:
37.5 J K-1 mol-1*.981 mol = 36.79 J K-1
The entropy change for this process is 36.79 ln (Tf - Ti)
where Tf is final temperature (273 K); Ti is initial temperature (260.3 K)
= 36.79 ln(12.7) = 93.5 J/K
Next, the ice melts:
.981 * 6.01 kJ/mol = 5.89 kJ
for a change of state at constant temperature the entropy change is
Q/T = 5.89 kJ / 273 K = 21.6 J/K
Next 17.68 g of ice at 273 K and 54.05 g water reach the same temperature; Using the first law of thermodynamics, deltaQ for this entire process is zero because the container is insulated. Summing up the heats of all the processes to 0:
36.79 J K-1 (273-260.3) + 5890 + .981 *75.3*(Tf-273) + 3*75.3*(Tf - 373) = 0
467.23 + 5890 + 73.87*(Tf-273) + 225.9*(Tf-373) = 0
6356 + 73.87*Tf - 20166 + 225.9*Tf - 84261 = 0
6356 +299.77*Tf - 104427 = 0
299.77*Tf = 98071
Tf = 327 K This is the final temperature of the mixture after it has reached equilibrium.
The change in entropy in bringing the melted ice to this temperature is
.981*75.3*ln(327-273) = 294.6 J/K
The change in entropy in bringing the liquid water down to this temperature is
3*75.3*ln(327-373) = an imaginary number
The total change in entropy is 93.5 J/K + 21.6 J/K + 294.6 J/K = 409.4 J/K
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