A stochastic perturbation approach to nonlinear bifurcating problems

Incorporating probabilistic terms in mathematical models is crucial for capturing and quantifying uncertainties of real-world systems. However, stochastic models typically require large computational resources to produce meaningful statistics. For such reason, the development of reduction techniques becomes essential for enabling efficient and scalable simulations of complex scenarios while quantifying the underlying uncertainties. In this work, we study the accuracy of Polynomial Chaos (PC) surrogate expansion of the probability space on a bifurcating phenomena in fluid dynamics, namely the Coand\u{a} effect. In particular, we propose a novel non-deterministic approach to generic bifurcation problems, where the stochastic setting gives a different perspective on the non-uniqueness of the solution, also avoiding expensive simulations for many instances of the parameter. Thus, starting from the formulation of the Spectral Stochastic Finite Element Method (SSFEM), we extend the methodology to deal with solutions of a bifurcating problem, by working with a perturbed version of the deterministic model. We discuss the link between the deterministic and the stochastic bifurcation diagram, highlighting the surprising capability of PC polynomials coefficients of giving insights on the deterministic solution manifold.