{"title":"关于超临界指数增长的平面Kirchhoff型问题","authors":"Limin Zhang, Xianhua Tang, Peng Chen","doi":"10.1515/anona-2022-0250","DOIUrl":null,"url":null,"abstract":"Abstract This article is concerned with the following nonlinear supercritical elliptic problem: − M ( ‖ ∇ u ‖ 2 2 ) Δ u = f ( x , u ) , in B 1 ( 0 ) , u = 0 , on ∂ B 1 ( 0 ) , \\left\\{\\begin{array}{ll}-M(\\Vert \\nabla u{\\Vert }_{2}^{2})\\Delta u=f\\left(x,u),& \\hspace{0.1em}\\text{in}\\hspace{0.1em}\\hspace{0.33em}{B}_{1}\\left(0),\\\\ u=0,& \\hspace{0.1em}\\text{on}\\hspace{0.1em}\\hspace{0.33em}\\partial {B}_{1}\\left(0),\\end{array}\\right. where B 1 ( 0 ) {B}_{1}\\left(0) is the unit ball in R 2 {{\\mathbb{R}}}^{2} , M : R + → R + M:{{\\mathbb{R}}}^{+}\\to {{\\mathbb{R}}}^{+} is a Kirchhoff function, and f ( x , t ) f\\left(x,t) has supercritical exponential growth on t t , which behaves as exp [ ( β 0 + ∣ x ∣ α ) t 2 ] \\exp {[}({\\beta }_{0}+| x\\hspace{-0.25em}{| }^{\\alpha }){t}^{2}] and exp ( β 0 t 2 + ∣ x ∣ α ) \\exp ({\\beta }_{0}{t}^{2+| x{| }^{\\alpha }}) with β 0 {\\beta }_{0} , α > 0 \\alpha \\gt 0 . Based on a deep analysis and some detailed estimate, we obtain Nehari-type ground state solutions for the above problem by variational method. Moreover, we can determine a fine upper bound for the minimax level under weaker assumption on liminf t → ∞ t f ( x , t ) exp [ ( β 0 + ∣ x ∣ α ) t 2 ] {\\mathrm{liminf}}_{t\\to \\infty }\\frac{tf\\left(x,t)}{\\exp {[}({\\beta }_{0}+| \\hspace{-0.25em}x\\hspace{-0.25em}{| }^{\\alpha }){t}^{2}]} and liminf t → ∞ t f ( x , t ) exp ( β 0 t 2 + ∣ x ∣ α ) {\\mathrm{liminf}}_{t\\to \\infty }\\frac{tf\\left(x,t)}{\\exp ({\\beta }_{0}{t}^{2+| x{| }^{\\alpha }})} , respectively. Our results generalize and improve the ones in G. M. Figueiredo and U. B. Severo (Ground state solution for a Kirchhoff problem with exponential critical growth, Milan J. Math. 84 (2016), no. 1, 23–39.) and Q. A. Ngó and V. H. Nguyen (Supercritical Moser-Trudinger inequalities and related elliptic problems, Calc. Var. Partial Differ. Equ. 59 (2020), no. 2, Paper No. 69, 30.) for M ( t ) = 1 M(t)=1 . In particular, if the weighted term ∣ x ∣ α | x\\hspace{-0.25em}{| }^{\\alpha } is vanishing, we can obtain the ones in S. T. Chen, X. H. Tang, and J. Y. Wei (2021) (Improved results on planar Kirchhoff-type elliptic problems with critical exponential growth, Z. Angew. Math. Phys. 72 (2021), no. 1, Paper No. 38, Theorem 1.3 and Theorem 1.4) immediately.","PeriodicalId":51301,"journal":{"name":"Advances in Nonlinear Analysis","volume":"11 1","pages":"1412 - 1446"},"PeriodicalIF":3.2000,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"9","resultStr":"{\"title\":\"On the planar Kirchhoff-type problem involving supercritical exponential growth\",\"authors\":\"Limin Zhang, Xianhua Tang, Peng Chen\",\"doi\":\"10.1515/anona-2022-0250\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abstract This article is concerned with the following nonlinear supercritical elliptic problem: − M ( ‖ ∇ u ‖ 2 2 ) Δ u = f ( x , u ) , in B 1 ( 0 ) , u = 0 , on ∂ B 1 ( 0 ) , \\\\left\\\\{\\\\begin{array}{ll}-M(\\\\Vert \\\\nabla u{\\\\Vert }_{2}^{2})\\\\Delta u=f\\\\left(x,u),& \\\\hspace{0.1em}\\\\text{in}\\\\hspace{0.1em}\\\\hspace{0.33em}{B}_{1}\\\\left(0),\\\\\\\\ u=0,& \\\\hspace{0.1em}\\\\text{on}\\\\hspace{0.1em}\\\\hspace{0.33em}\\\\partial {B}_{1}\\\\left(0),\\\\end{array}\\\\right. where B 1 ( 0 ) {B}_{1}\\\\left(0) is the unit ball in R 2 {{\\\\mathbb{R}}}^{2} , M : R + → R + M:{{\\\\mathbb{R}}}^{+}\\\\to {{\\\\mathbb{R}}}^{+} is a Kirchhoff function, and f ( x , t ) f\\\\left(x,t) has supercritical exponential growth on t t , which behaves as exp [ ( β 0 + ∣ x ∣ α ) t 2 ] \\\\exp {[}({\\\\beta }_{0}+| x\\\\hspace{-0.25em}{| }^{\\\\alpha }){t}^{2}] and exp ( β 0 t 2 + ∣ x ∣ α ) \\\\exp ({\\\\beta }_{0}{t}^{2+| x{| }^{\\\\alpha }}) with β 0 {\\\\beta }_{0} , α > 0 \\\\alpha \\\\gt 0 . Based on a deep analysis and some detailed estimate, we obtain Nehari-type ground state solutions for the above problem by variational method. Moreover, we can determine a fine upper bound for the minimax level under weaker assumption on liminf t → ∞ t f ( x , t ) exp [ ( β 0 + ∣ x ∣ α ) t 2 ] {\\\\mathrm{liminf}}_{t\\\\to \\\\infty }\\\\frac{tf\\\\left(x,t)}{\\\\exp {[}({\\\\beta }_{0}+| \\\\hspace{-0.25em}x\\\\hspace{-0.25em}{| }^{\\\\alpha }){t}^{2}]} and liminf t → ∞ t f ( x , t ) exp ( β 0 t 2 + ∣ x ∣ α ) {\\\\mathrm{liminf}}_{t\\\\to \\\\infty }\\\\frac{tf\\\\left(x,t)}{\\\\exp ({\\\\beta }_{0}{t}^{2+| x{| }^{\\\\alpha }})} , respectively. Our results generalize and improve the ones in G. M. Figueiredo and U. B. Severo (Ground state solution for a Kirchhoff problem with exponential critical growth, Milan J. Math. 84 (2016), no. 1, 23–39.) and Q. A. Ngó and V. H. Nguyen (Supercritical Moser-Trudinger inequalities and related elliptic problems, Calc. Var. Partial Differ. Equ. 59 (2020), no. 2, Paper No. 69, 30.) for M ( t ) = 1 M(t)=1 . In particular, if the weighted term ∣ x ∣ α | x\\\\hspace{-0.25em}{| }^{\\\\alpha } is vanishing, we can obtain the ones in S. T. Chen, X. H. Tang, and J. Y. Wei (2021) (Improved results on planar Kirchhoff-type elliptic problems with critical exponential growth, Z. Angew. Math. Phys. 72 (2021), no. 1, Paper No. 38, Theorem 1.3 and Theorem 1.4) immediately.\",\"PeriodicalId\":51301,\"journal\":{\"name\":\"Advances in Nonlinear Analysis\",\"volume\":\"11 1\",\"pages\":\"1412 - 1446\"},\"PeriodicalIF\":3.2000,\"publicationDate\":\"2022-01-01\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"9\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Advances in Nonlinear Analysis\",\"FirstCategoryId\":\"100\",\"ListUrlMain\":\"https://doi.org/10.1515/anona-2022-0250\",\"RegionNum\":1,\"RegionCategory\":\"数学\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q1\",\"JCRName\":\"MATHEMATICS\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Advances in Nonlinear Analysis","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1515/anona-2022-0250","RegionNum":1,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS","Score":null,"Total":0}
引用次数: 9
摘要
摘要本文讨论了以下非线性超临界椭圆问题:−M(‖õu‖2 2)Δu=f(x,u),在B1(0)中,u=0,在B.1(0)上,\ left \{\begin{array}{ll}-M(\Vert\nabla u{\Vert}_{2}^{2})\Delta u=f\left(x,u),&&hspace{0.1em}\text{in}\space{0.1em}\sspace{0.33em}{B}_{1} \left(0),\\u=0,&&hspace{0.1em}\text{on}\space{0.1em}\sace{0.33em}\partial{B}_{1} \left(0),\end{array}\right。其中B1(0){B}_{1} \left(0)是R 2中的单位球{\mathbb{R}}^{2},M:R+→ R+M:{{\mathbb{R}}^{+}\to{\math bb{R}}^{+}是基尔霍夫函数,f(x,t)f\left(x,t)在t上具有超临界指数增长,表现为exp[(β0+ŞxŞα)t2]\exp{[}β{0}{t}^{2+|x{|}^}\alpha}})与β0{\beta}_{0},α>0\alpha\gt 0。在深入分析和详细估计的基础上,我们用变分法得到了上述问题的Nehari型基态解。此外,我们可以在liminf t上的较弱假设下确定极小极大水平的精细上界→ ∞ t f(x,t)exp[(β0+ŞxŞα)t2]{\mathrm{liminf}}_{-0.25em}x\hspace{-0.25em}{|}^{\alpha}){t}^}2}]}和liminf t→ ∞ 分别为t f(x,t)exp(β0 t 2+ŞxŞα){\mathrm{liminf}}_{t\to\infty}\frac{tf\left(x,t)}{\exp(β_{0}{t}^{2+|x{|}^}\alpha})}。我们的结果推广和改进了G.M.Figueiredo和U.B.Severo(具有指数临界增长的基尔霍夫问题的基态解,Milan J.Math.84(2016),第1,23–39页)和Q.a.Ngó和V.H.Nguyen(超临界Moser-Trudinger不等式和相关椭圆问题,Calc.Var.P偏微分Equ.59(2020),第2页,论文69,30.)对于M(t)=1M(t)=1。特别地,如果加权项ŞxŞα|x\hspace{-0.25em}{|}^{\alpha}正在消失,我们可以立即获得S.T.Chen、x.H.Tang和J.Y.Wei(2021)(关于具有临界指数增长的平面Kirchhoff型椭圆问题的改进结果,Z.Angew.Math.Phys.72(2021),no.1,论文no.38,定理1.3和定理1.4)中的结果。
On the planar Kirchhoff-type problem involving supercritical exponential growth
Abstract This article is concerned with the following nonlinear supercritical elliptic problem: − M ( ‖ ∇ u ‖ 2 2 ) Δ u = f ( x , u ) , in B 1 ( 0 ) , u = 0 , on ∂ B 1 ( 0 ) , \left\{\begin{array}{ll}-M(\Vert \nabla u{\Vert }_{2}^{2})\Delta u=f\left(x,u),& \hspace{0.1em}\text{in}\hspace{0.1em}\hspace{0.33em}{B}_{1}\left(0),\\ u=0,& \hspace{0.1em}\text{on}\hspace{0.1em}\hspace{0.33em}\partial {B}_{1}\left(0),\end{array}\right. where B 1 ( 0 ) {B}_{1}\left(0) is the unit ball in R 2 {{\mathbb{R}}}^{2} , M : R + → R + M:{{\mathbb{R}}}^{+}\to {{\mathbb{R}}}^{+} is a Kirchhoff function, and f ( x , t ) f\left(x,t) has supercritical exponential growth on t t , which behaves as exp [ ( β 0 + ∣ x ∣ α ) t 2 ] \exp {[}({\beta }_{0}+| x\hspace{-0.25em}{| }^{\alpha }){t}^{2}] and exp ( β 0 t 2 + ∣ x ∣ α ) \exp ({\beta }_{0}{t}^{2+| x{| }^{\alpha }}) with β 0 {\beta }_{0} , α > 0 \alpha \gt 0 . Based on a deep analysis and some detailed estimate, we obtain Nehari-type ground state solutions for the above problem by variational method. Moreover, we can determine a fine upper bound for the minimax level under weaker assumption on liminf t → ∞ t f ( x , t ) exp [ ( β 0 + ∣ x ∣ α ) t 2 ] {\mathrm{liminf}}_{t\to \infty }\frac{tf\left(x,t)}{\exp {[}({\beta }_{0}+| \hspace{-0.25em}x\hspace{-0.25em}{| }^{\alpha }){t}^{2}]} and liminf t → ∞ t f ( x , t ) exp ( β 0 t 2 + ∣ x ∣ α ) {\mathrm{liminf}}_{t\to \infty }\frac{tf\left(x,t)}{\exp ({\beta }_{0}{t}^{2+| x{| }^{\alpha }})} , respectively. Our results generalize and improve the ones in G. M. Figueiredo and U. B. Severo (Ground state solution for a Kirchhoff problem with exponential critical growth, Milan J. Math. 84 (2016), no. 1, 23–39.) and Q. A. Ngó and V. H. Nguyen (Supercritical Moser-Trudinger inequalities and related elliptic problems, Calc. Var. Partial Differ. Equ. 59 (2020), no. 2, Paper No. 69, 30.) for M ( t ) = 1 M(t)=1 . In particular, if the weighted term ∣ x ∣ α | x\hspace{-0.25em}{| }^{\alpha } is vanishing, we can obtain the ones in S. T. Chen, X. H. Tang, and J. Y. Wei (2021) (Improved results on planar Kirchhoff-type elliptic problems with critical exponential growth, Z. Angew. Math. Phys. 72 (2021), no. 1, Paper No. 38, Theorem 1.3 and Theorem 1.4) immediately.
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Advances in Nonlinear Analysis (ANONA) aims to publish selected research contributions devoted to nonlinear problems coming from different areas, with particular reference to those introducing new techniques capable of solving a wide range of problems. The Journal focuses on papers that address significant problems in pure and applied nonlinear analysis. ANONA seeks to present the most significant advances in this field to a wide readership, including researchers and graduate students in mathematics, physics, and engineering.
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