{"title":"$$L_p$$ -solvability and Hölder regularity for stochastic time fractional Burgers’ equations driven by multiplicative space-time white noise","authors":"Beom-Seok Han","doi":"10.1007/s40072-024-00329-w","DOIUrl":null,"url":null,"abstract":"<p>This paper establishes <span>\\(L_p\\)</span>-solvability for stochastic time fractional Burgers’ equations driven by multiplicative space-time white noise: </p><span>$$\\begin{aligned} \\partial _t^\\alpha u = a^{ij}u_{x^ix^j} + b^{i}u_{x^i} + cu + {\\bar{b}}^i u u_{x^i} + \\partial _t^\\beta \\int _0^t \\sigma (u)dW_t,\\quad t>0;\\quad u(0,\\cdot ) = u_0, \\end{aligned}$$</span><p>where <span>\\(\\alpha \\in (0,1)\\)</span>, <span>\\(\\beta < 3\\alpha /4+1/2\\)</span>, and <span>\\(d< 4--2(2\\beta -1)_+/\\alpha \\)</span>. The operators <span>\\(\\partial _t^\\alpha \\)</span> and <span>\\(\\partial _t^\\beta \\)</span> are the Caputo fractional derivatives of order <span>\\(\\alpha \\)</span> and <span>\\(\\beta \\)</span>, respectively. The process <span>\\(W_t\\)</span> is an <span>\\(L_2(\\mathbb {R}^d)\\)</span>-valued cylindrical Wiener process, and the coefficients <span>\\(a^{ij}, b^i, c, {\\bar{b}}^{i}\\)</span> and <span>\\(\\sigma (u)\\)</span> are random. In addition to the uniqueness and existence of a solution, the Hölder regularity of the solution is also established. For example, for any constant <span>\\(T<\\infty \\)</span>, small <span>\\(\\varepsilon >0\\)</span>, and almost sure <span>\\(\\omega \\in \\varOmega \\)</span>, </p><span>$$\\begin{aligned} \\sup _{x\\in \\mathbb {R}^d}|u(\\omega ,\\cdot ,x)|_{C^{\\left[ \\frac{\\alpha }{2}\\left( \\left( 2-(2\\beta -1)_+/\\alpha -d/2 \\right) \\wedge 1 \\right) +\\frac{(2\\beta -1)_{-}}{2} \\right] \\wedge 1-\\varepsilon }([0,T])}<\\infty \\end{aligned}$$</span><p>and </p><span>$$\\begin{aligned} \\sup _{t\\le T}|u(\\omega ,t,\\cdot )|_{C^{\\left( 2-(2\\beta -1)_+/\\alpha -d/2 \\right) \\wedge 1 - \\varepsilon }(\\mathbb {R}^d)} < \\infty . \\end{aligned}$$</span><p>The Hölder regularity of the solution in time changes behavior at <span>\\(\\beta = 1/2\\)</span>. Furthermore, if <span>\\(\\beta \\ge 1/2\\)</span>, then the Hölder regularity of the solution in time is <span>\\(\\alpha /2\\)</span> times that in space.</p>","PeriodicalId":48569,"journal":{"name":"Stochastics and Partial Differential Equations-Analysis and Computations","volume":"57 1","pages":""},"PeriodicalIF":1.4000,"publicationDate":"2024-04-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Stochastics and Partial Differential Equations-Analysis and Computations","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1007/s40072-024-00329-w","RegionNum":3,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"MATHEMATICS, APPLIED","Score":null,"Total":0}
引用次数: 0
Abstract
This paper establishes \(L_p\)-solvability for stochastic time fractional Burgers’ equations driven by multiplicative space-time white noise:
$$\begin{aligned} \partial _t^\alpha u = a^{ij}u_{x^ix^j} + b^{i}u_{x^i} + cu + {\bar{b}}^i u u_{x^i} + \partial _t^\beta \int _0^t \sigma (u)dW_t,\quad t>0;\quad u(0,\cdot ) = u_0, \end{aligned}$$
where \(\alpha \in (0,1)\), \(\beta < 3\alpha /4+1/2\), and \(d< 4--2(2\beta -1)_+/\alpha \). The operators \(\partial _t^\alpha \) and \(\partial _t^\beta \) are the Caputo fractional derivatives of order \(\alpha \) and \(\beta \), respectively. The process \(W_t\) is an \(L_2(\mathbb {R}^d)\)-valued cylindrical Wiener process, and the coefficients \(a^{ij}, b^i, c, {\bar{b}}^{i}\) and \(\sigma (u)\) are random. In addition to the uniqueness and existence of a solution, the Hölder regularity of the solution is also established. For example, for any constant \(T<\infty \), small \(\varepsilon >0\), and almost sure \(\omega \in \varOmega \),
The Hölder regularity of the solution in time changes behavior at \(\beta = 1/2\). Furthermore, if \(\beta \ge 1/2\), then the Hölder regularity of the solution in time is \(\alpha /2\) times that in space.
期刊介绍:
Stochastics and Partial Differential Equations: Analysis and Computations publishes the highest quality articles presenting significantly new and important developments in the SPDE theory and applications. SPDE is an active interdisciplinary area at the crossroads of stochastic anaylsis, partial differential equations and scientific computing. Statistical physics, fluid dynamics, financial modeling, nonlinear filtering, super-processes, continuum physics and, recently, uncertainty quantification are important contributors to and major users of the theory and practice of SPDEs. The journal is promoting synergetic activities between the SPDE theory, applications, and related large scale computations. The journal also welcomes high quality articles in fields strongly connected to SPDE such as stochastic differential equations in infinite-dimensional state spaces or probabilistic approaches to solving deterministic PDEs.