The supercooled Stefan problem and its variants describe the freezing of a supercooled liquid in physics, as well as the large system limits of systemic risk models in finance and of integrate-and-fire models in neuroscience. Adopting the physics terminology, the supercooled Stefan problem is known to feature a finite-time blow-up of the freezing rate for a wide range of initial temperature distributions in the liquid. Such a blow-up can result in a discontinuity of the liquid-solid boundary. In this paper, we prove that the natural Euler time-stepping scheme applied to a probabilistic formulation of the supercooled Stefan problem converges to the liquid-solid boundary of its physical solution globally in time, in the Skorokhod M1 topology. In the course of the proof, we give an explicit bound on the rate of local convergence for the time-stepping scheme. We also run numerical tests to compare our theoretical results to the practically observed convergence behavior.
翻译:超级冷却的Stefan问题及其变体描述了物理学中超冷液的冻结情况,以及财务系统风险模型和神经科学集成和燃烧模型的大规模系统限制。采用物理术语,超级冷却的Stefan问题已知具有一定的特性,即在液体中各种初始温度分布的冷冻率中,这种超冷的Stefan问题及其变体可以有一定的时间爆炸。这种爆炸可能导致液体-固态边界的不连续性。在本文中,我们证明,在Skorokhod M1 地形学中,超冷的Stefan问题自然的Euler时间跨步方法适用于超冷气的系统性配方,在时间上会汇合到其实际解决方案的全球液体-固态边界。在证据过程中,我们明确限定了时间步骤计划当地汇合率。我们还进行了数字测试,将我们的理论结果与实际观察到的趋同行为进行比较。