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Abstract

The regularity of ecosystem size spectra is one of the most intriguing and relevant phenomena on our planet. Aquatic size spectra generally show a log-linearly downtrending shape, following a power-law distribution. A constant log-linear slope has been reported for many marine pelagic ecosystems, often being approximately b = -1. Conversely, there are variable trophic-level-biomass relationships (trophic pyramids). The contrasting observations of a constant biomass (M) spectrum slope and highly variable biomass pyramids may be defined as the constant size spectra-variable trophic dynamics paradox. Here, a 'mass-specific predator-prey-efficiency theory of size spectra' (PETS) is presented and discussed. A thorough analysis of available data, literature and models result in the conclusion that most pelagic marine ecosystems are controlled by trophic processes such as resource-limit stress (bottom-up control) and top-down regulation, with a key role of the maximum carrying capacity of large-sized organisms. This has relevant consequences for the prediction and interpretation of size spectra and the context of fisheries, whaling, and the introduction of exotic predators (e.g., lionfish). The complete size spectrum obtained in situ, including living organisms and non-living particles (e.g., for data from LOPC and UVP) is discussed. This paper is intended as a plea for the integration of modeling approaches, to understand and integrate data and processes across communities including bacteria, phytoplankton, fish and mammals, considering the effect of non-organismic particles.