Modeling the Siege of Syracuse: Resources, strategy, and collapse

The Siege of Syracuse ($214-212$ BC) was a decisive event in the Second Punic War, leading to the city's fall to Rome despite its formidable defenses, including the war machines devised by Archimedes. In this work, we propose a mathematical model to describe the dynamics of the siege, incorporating the depletion of resources, the decline of Syracuse's population, and the persistence of the Roman army. Our analysis reveals the existence of a critical threshold $\lambda_{c}$, which determines the outcome of the siege. This threshold marks a phase transition: if the effectiveness of Syracuse's defenses, represented by $\lambda$, had exceeded $\lambda_{c}$, the city could have withstood the Roman assault. However, since history records Syracuse's fall, we conclude that $\lambda < \lambda_{c}$. This result provides a quantitative framework to understand the inevitability of the city's conquest and demonstrates how mathematical modeling can offer new insights into historical military conflicts. We also explore different scenarios and assess the impact of key factors such as siege duration, supply constraints, and defensive capabilities. The results provide insight into how strategic elements influenced the eventual fall of Syracuse and demonstrate the applicability of mathematical modeling in historical military analysis.