Problem 93
Question
Ammonium nitrate dissolves spontaneously and endothermally in water at room temperature. What can you deduce about the sign of \(\Delta S\) for this solution process?
Step-by-Step Solution
Verified Answer
In this exercise, we are asked to deduce the sign of the change in entropy, \(\Delta S\), for the dissolution of ammonium nitrate in water. The dissolution is spontaneous and endothermic at room temperature. We know that for a process to be spontaneous, the Gibbs Free Energy change, \(\Delta G\), must be negative. Furthermore, the enthalpy change, \(\Delta H\), is positive since the process is endothermic. Analyzing the \(\Delta G\) equation, we can deduce that the sign of \(\Delta S\) must be positive, as this allows \(\Delta G\) to be negative, which is necessary for a spontaneous process.
1Step 1: Identify the given information
We know that the dissolution of ammonium nitrate in water is spontaneous and endothermic at room temperature. Spontaneous means that the process occurs without any external influence, and endothermic means that it absorbs heat from its surroundings.
2Step 2: Use the Gibbs Free Energy formula
The Gibbs Free Energy change, \(\Delta G\), can be used to determine the spontaneity of a process. The formula for Gibbs Free Energy change is:
\[ \Delta G = \Delta H - T\Delta S \]
where \(\Delta G\) is the change in Gibbs Free Energy, \(\Delta H\) is the change in enthalpy (heat), \(\Delta S\) is the change in entropy, and \(T\) is the temperature in Kelvin.
3Step 3: Determine the sign of the enthalpy change
Since we are given that the dissolution is endothermic, this means that the process absorbs heat from its surroundings. Therefore, the enthalpy change, \(\Delta H\), is positive.
4Step 4: Analyze the spontaneity
For a process to be spontaneous, the Gibbs Free Energy change, \(\Delta G\), must be negative. Since we know that \(\Delta H\) is positive in this case, we can deduce the sign of \(\Delta S\) by analyzing the \(\Delta G\) equation:
- If \(\Delta S\) is negative, the \(-T\Delta S\) term would be positive, making \(\Delta G\) positive and the process non-spontaneous.
- If \(\Delta S\) is positive, the \(-T\Delta S\) term would be negative, and since \(\Delta H\) is also positive, the overall \(\Delta G\) could be negative and the process can be spontaneous.
5Step 5: Conclusion
Based on the given information, we can deduce that the sign of the change in entropy, \(\Delta S\), for the dissolution of ammonium nitrate in water must be positive. This is because it allows the Gibbs Free Energy change, \(\Delta G\), to be negative, which is necessary for a spontaneous process.
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