Final answer:
The change in entropy of the surroundings when 100 g of ice melts at 0°C is approximately 122 J/K, calculated using the formula for entropy change and the latent heat of fusion for water.
Step-by-step explanation:
The change in entropy of the surroundings when a cube of ice melts can be calculated using the formula ΔS = q/T, where q is the heat absorbed and T is the temperature at which the melting process occurs. Given that 33 kJ of energy is absorbed for the melting of 100 g of ice, and using the melting temperature of ice which is 273 K (0°C), the change in entropy of the surroundings can be calculated as:
ΔS = q/T = (33×1000 J) / 273 K = 120,879 J/K
However, since only 100 g (0.1 kg) of ice is melting, we will use the given value of the latent heat of fusion for water (334 kJ/kg) to find the exact amount of heat absorbed (q):
q = (0.1 kg)(334 kJ/kg) = 33.4 kJ = 33,400 J
Now, we can calculate the change in entropy for the surroundings:
ΔSsurroundings = q/T = 33,400 J / 273 K ≈ 122.344 J/K
Therefore, when 100 g of ice melts at 0°C, the change in entropy of the surroundings is approximately 122 J/K.