Abstract
Atmospheric moist available potential energy (MAPE) has traditionally been defined as the potential energy of a moist atmosphere relative to that of the adiabatically sorted reference state defining a global potential energy minimum. Although the Munkres algorithm can in principle find such a reference state exactly, its computational cost has prompted much interest in developing heuristic methods for computing MAPE in practice. Comparisons of the accuracy of such approximate algorithms have so far been limited to a small number of test cases; this work provides an assessment of the performance of the algorithms across a wide range of atmospheric soundings, in two different locations. We determine that the divide‐and‐conquer algorithm is the best suited to practical application, but suffers from the previously unexplored shortcoming that it can produce a reference state with higher potential energy than the actual state, resulting in a negative value of MAPE. Additionally, we show that it is possible to construct an algorithm exploiting a previously derived theoretical expression linking MAPE to Convective Available Potential Energy (CAPE). This approach has a similar accuracy to existing approximate sorting algorithms, whilst providing greater insight into the physical source of MAPE. In light of these results, we discuss possible ways to improve on the construction of Available Potential Energy (APE) theory for a moist atmosphere.
Highlights
Available Potential Energy (APE) theory, as originally outlined by Lorenz (1955), provides a framework to study the energy available to atmospheric motions
To investigate the possibility of using a more physically based approach to compute moist available potential energy (MAPE), we develop an algorithm based on the relationship between Convective Available Potential Energy (CAPE) and MAPE found by Emanuel (1994)
The key challenge for MAPE algorithms stems from the fact that MAPE is a residual arising from the positive work due to the release of CAPE minus the negative work due to compensating subsidence
Summary
Available Potential Energy (APE) theory, as originally outlined by Lorenz (1955), provides a framework to study the energy available to atmospheric motions. Previous methods of calculating MAPE have relied on heuristic approaches involving discretizing atmospheric domains into parcels of equal mass and sorting them according to density at differing pressure levels to obtain a reference state. We apply all the MAPE algorithms to 3,130 soundings from the Atmospheric Radiation Measurement (ARM) station on Nauru and to 584 soundings from the ARM sites on the Southern Great Plains This allows us to assess which of the approximate algorithms is likely to compute a MAPE close to the true value, and to investigate the variation in their accuracy over a large number of soundings. We discuss the implications of our results for the development of a satisfactory theory of APE for a moist atmosphere
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