21.8: Spectroscopic Entropies sometimes disgree with Calorimetric Entropies
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The entropy of gases can be experimentally measured using calorimetry (\(S^\circ_{\text{exp}}\)) or calculated using spectroscopic methods (\(S^\circ_{\text{calc}}\)). For most molecules, the experiment and calculated values are in a good agreement, however, this is not true for all molecules. The discrepancy is referred to as residual entropy:
\[\bar{S}_{\text{calc}}-\bar{S}_{\text{exp}} \nonumber \]
Residual entropy arises from a material that can have many different states a 0 K. The third law of thermodynamics states that at zero kelvin, a substance will have an entropy of zero. In substances, such as glass, ice, and carbon monoxide, the substance can exist in many different configurations; it is not a perfect crystal, but must still have zero entropy according to third law. The material has residual entropy.