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Blow-up and global existence of solutions for a time fractional diffusion equation

  • Yaning Li EMAIL logo und Quanguo Zhang
Veröffentlicht/Copyright: 9. Februar 2019
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Fractional Calculus and Applied Analysis
Aus der Zeitschrift Fractional Calculus and Applied Analysis Band 21 Heft 6

Abstract

In this paper, we study the blow-up and global existence of solutions to the following time fractional nonlinear diffusion equations

0CDtαuu=0It1γ(|u|p1u),xRN,t>0,u(0,x)=u0(x),xRN,

where 0 < α < γ < 1, p > 1, u0C0(ℝN), 0Itθ denotes left Riemann-Liouville fractional integrals of order θ. 0CDtαu=t0It1α (u(t, x) − u(0, x))}. Let β = 1 − γ. We prove that if 1 < p < p = max{1+βα,1+2(α+β)αN} , the solutions of (1.1) blows up in a finite time. If N < 2(α+β)β , pp or N2(α+β)β , p > p, and ∥u0Lqc(ℝN) is sufficiently small, where qc=Nα(p1)2(α+β) , the solutions of (1.1) exists globally.

MSC 2010: Primary 26A33; Secondary 34A08; 33K15
Key Words and Phrases: fractional calculus; blow-up; global existence; nonlinear memory

Acknowledgements

This paper has been partially supported by NSF of China (11801276, 11626132, 11601216, 71501101), NSF of JiangSu Province(BK20150928) and the Project of Philosophy and Social Science Research in Colleges and Universities in Jiangsu Province (2015SJB063).

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Received: 2018-01-02
Published Online: 2019-02-09
Published in Print: 2018-12-19

© 2018 Diogenes Co., Sofia

Artikel in diesem Heft

  1. Frontmatter
  2. Editorial Note
  3. FCAA related news, events and books
  4. Research Paper
  5. Sensitivity analysis for optimal control problems described by nonlinear fractional evolution inclusions
  6. Finite-time attractivity for semilinear tempered fractional wave equations
  7. Geometry of curves with fractional-order tangent vector and Frenet-Serret formulas
  8. Extrapolating for attaining high precision solutions for fractional partial differential equations
  9. Time optimal controls for fractional differential systems with Riemann-Liouville derivatives
  10. Inverses of generators of integrated fractional resolvent operator functions
  11. A variational approach for boundary value problems for impulsive fractional differential equations
  12. Infinitely many solutions to boundary value problem for fractional differential equations
  13. A semi-analytic method for fractional-order ordinary differential equations: Testing results
  14. Blow-up and global existence of solutions for a time fractional diffusion equation
  15. A note on the Blaschke-Petkantschin formula, Riesz distributions, and Drury’s identity
  16. Short Paper
  17. Fractal dimension of Riemann-Liouville fractional integral of 1-dimensional continuous functions
https://doi.org/10.1515/fca-2018-0085
Schlagwörter für diesen Artikel
fractional calculus; blow-up; global existence; nonlinear memory

Artikel in diesem Heft

  1. Frontmatter
  2. Editorial Note
  3. FCAA related news, events and books
  4. Research Paper
  5. Sensitivity analysis for optimal control problems described by nonlinear fractional evolution inclusions
  6. Finite-time attractivity for semilinear tempered fractional wave equations
  7. Geometry of curves with fractional-order tangent vector and Frenet-Serret formulas
  8. Extrapolating for attaining high precision solutions for fractional partial differential equations
  9. Time optimal controls for fractional differential systems with Riemann-Liouville derivatives
  10. Inverses of generators of integrated fractional resolvent operator functions
  11. A variational approach for boundary value problems for impulsive fractional differential equations
  12. Infinitely many solutions to boundary value problem for fractional differential equations
  13. A semi-analytic method for fractional-order ordinary differential equations: Testing results
  14. Blow-up and global existence of solutions for a time fractional diffusion equation
  15. A note on the Blaschke-Petkantschin formula, Riesz distributions, and Drury’s identity
  16. Short Paper
  17. Fractal dimension of Riemann-Liouville fractional integral of 1-dimensional continuous functions
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