Stoichiometric ontogenetic development influences population dynamics: Stage-structured model under nutrient co-limitations

TL;DR

This paper introduces a novel stage-structured model incorporating nutrient co-limitation and food quality, revealing how stoichiometric constraints influence population dynamics and ecosystem stability.

Contribution

It develops the first stoichiometric stage-structure model considering both nutrient co-limitation and food quality, applied to an algae-Daphnia system.

Findings

Stoichiometric constraints affect population equilibria and cycles.

Stage-specific parameters influence bifurcations and stability.

High-light environments amplify nutrient limitation effects.

Abstract

Ecological processes depend on the flow and balance of essential elements such as carbon (C) and phosphorus (P), and changes in these elements can cause adverse effects to ecosystems. The theory of Ecological Stoichiometry offers a conceptual framework to investigate the impact of elemental imbalances on structured populations while simultaneously considering how ecological structures regulate nutrient cycling and ecosystem processes. While there have been significant advances in the development of stoichiometric food web models, these efforts often consider a homogeneous population and neglect stage-structure. The development of stage-structured population models has significantly contributed to understanding energy flow and population dynamics of ecological systems. However, stage structure models fail to consider food quality in addition to food quantity. We develop a stoichiometric stage-structure producer-grazer model that considers co-limitation of nutrients, and parameterize the model for an algae-Daphnia food chain. Our findings emphasize the impact of stoichiometric constraints on structured population dynamics. By incorporating both food quantity and quality into maturation rates, we demonstrate how stage-structured dynamics can influence outcomes in variable environments. Stage-specific parameters, such as juvenile growth and ingestion rates can drive shifts in equilibria, limit cycles, and bifurcation points. These effects are especially significant in high-light environments where nutrient limitations are most pronounced.