Modelling Financial Contagion And Optimal Policy Design For Bank Runs And Systemic Risk
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Mathematics and Computers in Simulation
Abstract
Bank runs can destabilize individual institutions and, through financial networks, spread
into general economic crises. The study explores the interconnection of systemic risk in the
banking system, emphasizing interbank networks as the primary means of propagating financial
contagion. We propose a compartmental system through which contagion is propagated. The
system classifies the banks in the network into six compartments (undistressed, exposed,
distressed, liquid, run, and failed states). We capture the dynamics of distress transmission
through interbank interactions and depositor behaviours. We derive the basic reproduction
number 0
to characterize the threshold conditions for systemic stability and identify both
risk-free and risk-persistent equilibrium points. Through sensitivity experiments, we identify
the parameters that exert the strongest influence on contagion dynamics—the contact rate
between banks, the level of behavioural compliance, and transition intensities. Building on
these insights, we formulate an optimal-control framework that incorporates three forms of
intervention: deposit-insurance protection, policies aimed at calming depositors, and targeted
liquidity intervention. Using Pontryagin’s Maximum Principle, we derive the time paths of
these interventions that jointly reduce the spread of distress while keeping regulatory costs
manageable. The numerical results highlight the importance of acting early: even a moderate
level of deposit-insurance coverage, when implemented at the right moment, substantially
dampens the transmission of shocks across the network. The study offers practical guidance for
the design of policy tools intended to contain systemic risk in interconnected banking systems.
Description
Research Article
Citation
Gyamerah, S. A., Afrifa, E., Boiquaye, P. A., & Dzupire, N. (2026). Modelling financial contagion and optimal policy design for bank runs and systemic risk. Mathematics and Computers in Simulation.
