A Spectral Representation of a Weighted Random Vectorial Field: Potential Applications to Turbulence and the Problem of Anomalous Dissipation in the Inviscid Limit
{"title":"A Spectral Representation of a Weighted Random Vectorial Field: Potential Applications to Turbulence and the Problem of Anomalous Dissipation in the Inviscid Limit","authors":"Steven D Miller","doi":"arxiv-2409.10636","DOIUrl":null,"url":null,"abstract":"Let ${\\mathfrak{G}}\\subset\\mathbb{R}^{3}$ with $vol(\\mathfrak{G})\\sim L^{3}$.\nLet ${\\mathscr{T}}(x)$ be a Gaussian random field $\\forall~x\\in\\mathfrak{G}$\nwith expectation $\\mathbf{E}[{\\mathscr{T}}(x)]=0$ and correlation\n$\\mathbf{E}[{\\mathscr{T}}(x)\\otimes{\\mathscr{T}}(y)]=K(x,y;\\lambda)$, an\nisotropic and regulated kernel with correlation length $\\lambda$. The field has\na Karhunen-Loeve spectral representation\n${\\mathscr{T}}(x)=\\sum_{I=1}^{\\infty}\\mathrm{Z}^{1/2}_{I}f_{I}(x)\\otimes\\mathscr{Z}_{I}$,\nwith eigenvalues $\\lbrace\\mathrm{Z}_{I}\\rbrace$, eigenfunctions $\\lbrace\nf_{I}(x)\\rbrace $ and Gaussian random variables $\\mathscr{Z}_{I}$ with\n$\\mathbf{E}[\\mathscr{Z}_{I}]=0$ and\n$\\mathbf{E}[\\mathscr{Z}_{I}\\otimes\\mathscr{Z}_{J}]=\\delta_{IJ}$. If\n$\\mathfrak{G}$ contains incompressible fluid of viscosity $\\nu$ with velocity\n$u_{a}(x,t)$ that evolves via the Navier-Stokes equations with a high 'Reynolds\nfunction' $\\mathsf{RE}(x,t)=\\tfrac{\\|u_{a}(x,t)\\|L}{\\nu} $ then aspects of a\nturbulent flow with $\\mathsf{RE}(x,t)\\gg \\mathsf{RE}_{*}$, a critical Reynolds\nnumber, might be represented by the 'weighted' random field\n$\\mathscr{U}_{a}(x,t)=\nu_{a}(x,t)+\\mathrm{A}u_{a}(x,t)\\big(\\mathsf{RE}(x,t)-\\mathsf{RE}_{*}\\big)^{\\beta}\\sum_{I=1}^{\\infty}\n\\mathrm{Z}^{1/2}_{I}f_{I}(x)\\otimes\\mathscr{Z}_{I}$ where random fluctuations\nand amplitude scale nonlinearly with $\\mathsf{RE}(x,t)$, with mean\n$\\mathbf{E}[{\\mathscr{U}}_{a}(x,t)] =u_{a}(x,t)$. In the inviscid limit one can\nprove an anomalous dissipation-type law \\begin{align} \\lim_{\\nu\\rightarrow\n0}\\bigg(\\lim_{u_{a}(x,t)\\rightarrow {u}_{a}}\\sup~\\nu\n\\int_{\\mathfrak{G}}\\int_{0}^{T}{\\mathbf{E}}\\bigg[\\bigg|{\\nabla}_{a}{\\mathscr{U}}_{a}(x,s)\\bigg|^{2}\\bigg]d\\mathcal{V}(x)\nds\\bigg)>0 \\end{align} iff $\\beta=\\tfrac{1}{2}$ and\n$\\sum_{I=1}^{\\infty}\\mathrm{Z}_{I}\\int_{{\\mathfrak{G}}}{\\nabla}_{a}f_{I}(x){\\nabla}^{a}f_{I}(x)d\\mathcal{V}(x)>0$.","PeriodicalId":501245,"journal":{"name":"arXiv - MATH - Probability","volume":"103 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - MATH - Probability","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2409.10636","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Let ${\mathfrak{G}}\subset\mathbb{R}^{3}$ with $vol(\mathfrak{G})\sim L^{3}$.
Let ${\mathscr{T}}(x)$ be a Gaussian random field $\forall~x\in\mathfrak{G}$
with expectation $\mathbf{E}[{\mathscr{T}}(x)]=0$ and correlation
$\mathbf{E}[{\mathscr{T}}(x)\otimes{\mathscr{T}}(y)]=K(x,y;\lambda)$, an
isotropic and regulated kernel with correlation length $\lambda$. The field has
a Karhunen-Loeve spectral representation
${\mathscr{T}}(x)=\sum_{I=1}^{\infty}\mathrm{Z}^{1/2}_{I}f_{I}(x)\otimes\mathscr{Z}_{I}$,
with eigenvalues $\lbrace\mathrm{Z}_{I}\rbrace$, eigenfunctions $\lbrace
f_{I}(x)\rbrace $ and Gaussian random variables $\mathscr{Z}_{I}$ with
$\mathbf{E}[\mathscr{Z}_{I}]=0$ and
$\mathbf{E}[\mathscr{Z}_{I}\otimes\mathscr{Z}_{J}]=\delta_{IJ}$. If
$\mathfrak{G}$ contains incompressible fluid of viscosity $\nu$ with velocity
$u_{a}(x,t)$ that evolves via the Navier-Stokes equations with a high 'Reynolds
function' $\mathsf{RE}(x,t)=\tfrac{\|u_{a}(x,t)\|L}{\nu} $ then aspects of a
turbulent flow with $\mathsf{RE}(x,t)\gg \mathsf{RE}_{*}$, a critical Reynolds
number, might be represented by the 'weighted' random field
$\mathscr{U}_{a}(x,t)=
u_{a}(x,t)+\mathrm{A}u_{a}(x,t)\big(\mathsf{RE}(x,t)-\mathsf{RE}_{*}\big)^{\beta}\sum_{I=1}^{\infty}
\mathrm{Z}^{1/2}_{I}f_{I}(x)\otimes\mathscr{Z}_{I}$ where random fluctuations
and amplitude scale nonlinearly with $\mathsf{RE}(x,t)$, with mean
$\mathbf{E}[{\mathscr{U}}_{a}(x,t)] =u_{a}(x,t)$. In the inviscid limit one can
prove an anomalous dissipation-type law \begin{align} \lim_{\nu\rightarrow
0}\bigg(\lim_{u_{a}(x,t)\rightarrow {u}_{a}}\sup~\nu
\int_{\mathfrak{G}}\int_{0}^{T}{\mathbf{E}}\bigg[\bigg|{\nabla}_{a}{\mathscr{U}}_{a}(x,s)\bigg|^{2}\bigg]d\mathcal{V}(x)
ds\bigg)>0 \end{align} iff $\beta=\tfrac{1}{2}$ and
$\sum_{I=1}^{\infty}\mathrm{Z}_{I}\int_{{\mathfrak{G}}}{\nabla}_{a}f_{I}(x){\nabla}^{a}f_{I}(x)d\mathcal{V}(x)>0$.