# Methodological Insights into Implementing cellular automata models for simulating seagrass dynamics: Responses to global change effects

**Authors:** Pedro Beca-Carretero, Marlene Meister, Mirta Teichberg, Agustin Moreira-Saporiti, Fabian Schneekloth, Hauke Reuter

PMC · DOI: 10.1016/j.mex.2024.102936 · MethodsX · 2024-08-28

## TL;DR

This paper presents a new method using cellular automata models to simulate how seagrass ecosystems respond to global environmental changes.

## Contribution

The paper introduces a detailed procedural framework for implementing cellular automata models in seagrass dynamics.

## Key findings

- The methodology was successfully applied to Mediterranean and Zanzibari seagrass ecosystems.
- CA models can capture impacts of climate change, invasive species, and nutrient regimes on seagrass.
- The model has limitations in parameterization and validation, requiring future improvements.

## Abstract

This study introduces an innovative methodology employing Cellular Automata (CA) models to simulate seagrass dynamics in response to global environmental changes. The primary objective is to outline a procedural framework for constructing and deploying CA models applied to seagrass ecosystems, and potentially to other marine or terrestrial environments. The methodology encompasses various components, including conceptualization, workflow delineation, model parameterization, and execution steps. By utilizing Mediterranean and Zanzibari (East Africa) seagrass ecosystems as case studies, we demonstrate the versatility and applicability of the proposed approach across diverse geographical regions, species composition and model components. Through these case studies, we demonstrated how CA models can effectively capture the dynamics of seagrass communities subjected to climate change, invasive species, and nutrient regimes. Despite its strengths, the proposed CA model has limitations, including parameterization complexity and uncertainties related to species-specific environmental thresholds, growth rates and species interactions, alongside the difficulty of validating our models with real-world scenarios. Addressing these limitations in future studies will enhance the model's accuracy and applicability. This study serves as a foundation for future research in other regions and ecosystems, facilitating a better understanding of the complex interactions driving ecosystem dynamics.•This study introduces a methodology using Cellular Automata (CA) models to simulate seagrass dynamics detailing conceptualization, workflow, parameterization, and execution.•Case studies in Mediterranean and East Africa ecosystems demonstrate the versatility of CA models in capturing the impacts of climate change, invasive species, and nutrient regimes.•Despite strengths, the CA model has limitations and uncertainties like parameterization complexity and model validations suggesting future research to enhance accuracy and applicability.

This study introduces a methodology using Cellular Automata (CA) models to simulate seagrass dynamics detailing conceptualization, workflow, parameterization, and execution.

Case studies in Mediterranean and East Africa ecosystems demonstrate the versatility of CA models in capturing the impacts of climate change, invasive species, and nutrient regimes.

Despite strengths, the CA model has limitations and uncertainties like parameterization complexity and model validations suggesting future research to enhance accuracy and applicability.

Image, graphical abstract

## Full-text entities

- **Diseases:** H. uninervis (MESH:D000848), CA (MESH:D004806), Mortality (MESH:D003643), CS (MESH:D006223)
- **Chemicals:** phosphate (MESH:D010710), water (MESH:D014867), DIN (-), carbon (MESH:D002244)
- **Species:** Posidonia oceanica (species) [taxon 55489], Cymodocea serrulata (species) [taxon 55449], Halophila stipulacea (species) [taxon 83836], Halodule uninervis (species) [taxon 319738], Thalassia hemprichii (species) [taxon 55496], Cymodocea nodosa (species) [taxon 55448]

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11829100/full.md

## References

25 references — full list in the complete paper: https://tomesphere.com/paper/PMC11829100/full.md

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Source: https://tomesphere.com/paper/PMC11829100