Approximation technique for fractional evolution equations with nonlocal integral conditions. (English) Zbl 1387.35604
Summary: We consider a class of fractional evolution equations with nonlocal integral conditions in Banach spaces. New existence of mild solutions to such a problem are established using Schauder fixed-point theorem, diagonal argument and approximation techniques under the hypotheses that the nonlinear term is Carathéodory continuous and satisfies some weak growth condition, the nonlocal term depends on all the value of independent variable on the whole interval and satisfies some weak growth condition. This work may be viewed as an attempt to develop a general existence theory for fractional evolution equations with general nonlocal integral conditions. Finally, as a sample of application, the results are applied to a fractional parabolic partial differential equation with nonlocal integral condition. The results obtained in this paper essentially extend some existing results in this area.
MSC:
| 35R11 | Fractional partial differential equations |
| 47D06 | One-parameter semigroups and linear evolution equations |
| 47J35 | Nonlinear evolution equations |
Keywords:
fractional evolution equations; nonlocal integral condition; approximation technique; compact semigroupReferences:
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