On moist potential temperatures and their ability to characterize differences in the properties of air parcels

Abstract

A framework is introduced to compare moist `potential' temperatures. The equivalent potential temperature, θe, the liquid water potential temperature, θ, and the entropy potential temperature, θs, are all shown to be potential temperatures, in the sense that they measure the temperatures of certain reference state systems whose entropy is the same as that of the air-parcel. They only differ in the choice of reference state composition: θ describes the temperature a condensate-free state, θe a vapor-free state, and θs a water-free state would require to have the same entropy as the given state. Although in this sense θe, θ, and θs are all different flavors of the same thing, only θ satisfies the stricter definition of a `potential temperature', as corresponding to a reference temperature accessible by an isentropic and closed transformation of a system in equilibrium; both θe and θ measure the `relative' enthalpy of an air parcel at their respective reference states; but only θs measures air-parcel entropy. None mix linearly, but all do so approximately, and all reduce to the dry potential temperature, θ in the limit as the water mass fraction goes to zero. As is well known, θ does mix linearly and inherits all the favorable (entropic, enthalpic, and potential temperature) properties of its various -- but descriptively less rich -- moist counterparts. All, involve quite complex expressions, but admit relatively simple and useful approximations. Of the three moist `potential' temperatures, θs is the least familiar, but the most well mixed in the broader tropics, a property that merits further study as a possible basis for constraining mixing processes.