Nutrient Fluxes and their Effects on Food Web Stability in Aquatic Systems

Abstract

Nutrient dynamics are essential in determining the structure, functionality, and long-term stability of food chains and food webs within ecosystems. Through major biogeochemical cycles, such as those of nitrogen, phosphorus, carbon, and sulphur; nutrients are continually cycled and exchanged between living organisms and their physical environment. These cycles govern the availability of critical nutrients necessary for primary producers, thereby shaping the foundational levels of trophic systems and driving the flow of energy through successive trophic levels. Changes in nutrient supply influence species diversity, trophic relationships, and the overall productivity of biomass. While balanced nutrient inputs support biodiversity and promote ecosystem stability, excessive nutrient loading can disrupt food web dynamics, triggering problems such as eutrophication, loss of species, and imbalances across trophic levels; commonly referred to as the "paradox of enrichment." Additionally, nutrient recycling through detritus-based processes and consumer activities creates feedback mechanisms that can either buffer or amplify ecological fluctuations depending on prevailing environmental factors. Overall, the interactions between nutrient cycles and trophic dynamics underscore the critical need to manage nutrient inputs carefully to preserve ecological health across both aquatic and terrestrial ecosystems