Collaborative research: Turbulent cascades and dissipation in the 3D Navier-Stokes model

合作研究：3D Navier-Stokes 模型中的湍流级联和耗散

• 批准号: 1515805
• 负责人: Zoran Grujic
• 金额: $ 16.1万
• 依托单位: University of Virginia Main Campus
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-09-01 至 2019-03-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1515805&HistoricalAwards=false
• 关键词: Collaborative; research; Turbulent; cascades; dissipation

GrujicDMS-1515805DascaliucDMS-1516487 Turbulence is everywhere, both disruptive and helpful in technological applications, such as safety and efficiency of transportation, biomedical research, climate studies, or infrastructure design. On one hand, suppressing turbulent drag is key in designing and engineering energy efficient vehicles. Understanding the genesis and dynamics of a turbulent wake behind a large plane is key in maintaining safety of the airspace in the proximity of an airport. On the other hand, turbulent mixing may be desirable -- an example being designing more efficient drug delivery systems. The main theme of the project is a rigorous study of various manifestations of turbulence in three-dimensional fluid flows modeled by the Navier-Stokes equations. This is considered both from the perspective of the mathematical theory of turbulence, and as a physical mechanism underlying possible blow-ups (singularities) of the solutions of the system. Ruling out the possibility of singularity formation in any physical model is a fundamental question, even more so when the model should be applicable to such an omnipresent class of physical phenomena as are 3D fluid flows. Graduate students are included in the work of the project. The project branches into three directions: (1) vortex stretching and local anisotropic diffusion, (2) isotropic diffusion of the velocity field and induced scaling laws, and (3) turbulent transport in non-homogeneous Navier-Stokes model. The first two directions follow from the recent work of the investigators and their collaborators in presenting a numerically and analytically motivated geometric scenario of vortex filaments formation that exhibits logarithmic sub-criticality in the context of the 3D Navier-Stokes regularity problem. In this scenario, the transversal scale of the filaments -- a natural, anisotropic micro-scale of the flow -- triggers the mechanism of local, anisotropic diffusion, preventing the possible formation of singularities. The motivation for the third direction of the study comes from the realm of building and reinforcing mathematical support for Kolmogorov phenomenology in physical scales of the flow. The investigators have recently managed to adopt their physical scales methodology to the study of forced turbulence. This opens up an avenue for studying the influence of the spatial distribution of the force on formation of turbulent cascades, as well as for the study of boundary effects via the masking feedback/volume penalization approach. Graduate students are included in the work of the project.

GrujicDMS-1515805 DascaliucDMS-1516487 湍流无处不在，在技术应用中既具有破坏性又有帮助，例如交通安全和效率，生物医学研究，气候研究或基础设施设计。 一方面，抑制湍流阻力是设计和工程节能车辆的关键。 了解大型飞机后面湍流尾流的起源和动力学是维护机场附近空域安全的关键。 另一方面，湍流混合可能是理想的--一个例子是设计更有效的药物输送系统。 该项目的主题是严格研究由Navier-Stokes方程模拟的三维流体流动中湍流的各种表现。 这被认为是从湍流的数学理论的角度来看，并作为一个物理机制潜在的可能爆破（奇点）的解决方案的系统。 排除任何物理模型中奇点形成的可能性是一个基本问题，当模型应该适用于像3D流体流动这样无所不在的一类物理现象时更是如此。 研究生也参与了该项目的工作。 该项目分为三个方向：（1）涡拉伸和局部各向异性扩散，（2）速度场的各向同性扩散和诱导的标度律，（3）非均匀Navier-Stokes模型中的湍流输运。 前两个方向遵循从最近的工作的调查人员和他们的合作者在提出一个数值和分析动机的几何方案的涡丝形成，表现出对数亚临界的上下文中的三维Navier-Stokes正则性问题。 在这种情况下，细丝的横向尺度--流动的自然、各向异性的微观尺度--触发了局部、各向异性扩散的机制，防止了可能形成的奇点。 第三个方向的研究的动机来自领域的建设和加强数学支持Kolmogorov现象的物理尺度的流动。 研究人员最近成功地将他们的物理尺度方法用于强迫湍流的研究。 这开辟了一条途径，研究的空间分布的力对湍流叶栅的形成的影响，以及通过掩蔽反馈/体积惩罚方法的边界效应的研究。 研究生也参与了该项目的工作。