A new proposal of power series method to solve the Navier-Stokes equations: application contexts and perspectives

P. Lecca, Angela Re
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Abstract

In this work we investigate the possibility of expressing the solution of the Navier-Stokes equations as a power series. Although there have been many studies on this subject, it is still much debated. The existence of such a solution and its uniqueness are debated, especially in the general case of a non-stationary fluid in two or three dimensions. The greater the complexity of the fluid dynamical phenomenon under consideration, the more controversial and therefore uncertain are the deductions about the existence and uniqueness of the solution as a power series. Here, we ask some crucial questions on the matter and try to give an answer from the point of view of applied mathematics and numerical analysis. In particular, by way of example, we construct the Navier-Stokes equations for a compressible, multicomponent and non-stationary fluid from elementary principles of conservation of mass, momentum and energy, and we introduce a bump function model for the presence of different components and/or different phases in the fluid. The bump function is a function of space, time and physical characteristics of the components (and/or phases) such as density. We present a method to calculate it and discuss about its uniqueness. We show that under certain conditions on the bump function, and the forces acting on and in the fluid, the power series solution is unique. We finally discuss the advantages and the limitations of a solution in power series, concluding that, although plagued by limitations, it is a viable way forward even in highly complex case studies.
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幂级数法求解Navier-Stokes方程的一种新方法:应用背景与前景
在这项工作中,我们研究了用幂级数表示Navier-Stokes方程解的可能性。虽然已经有很多关于这个问题的研究,但仍有很多争论。这种解的存在性及其唯一性一直受到争论,特别是在二维或三维非定常流体的一般情况下。所考虑的流体动力现象越复杂,关于解作为幂级数的存在性和唯一性的推论就越有争议,因而也就越不确定。在这里,我们提出了一些关键的问题,并试图从应用数学和数值分析的角度给出答案。特别地,通过举例,我们从质量、动量和能量守恒的基本原理出发,构造了可压缩、多组分和非稳态流体的Navier-Stokes方程,并引入了流体中存在不同组分和/或不同相的碰撞函数模型。凹凸函数是空间、时间和组件(和/或相)的物理特性(如密度)的函数。给出了一种计算它的方法,并讨论了它的唯一性。我们证明了在碰撞函数和作用于流体的力的一定条件下,幂级数解是唯一的。最后,我们讨论了幂级数解的优点和局限性,得出结论,尽管存在局限性,但即使在高度复杂的案例研究中,它也是一种可行的方法。
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