A‎ ‎High-Performance‎ ‎Block-Based‎ ‎Computational Scheme for Solving Fractional Nonlinear Equations in Electrospinning Modeling

Document Type : Original Scientific Paper

Authors

‎Department of Mathematics, ‎Faculty of Mathematical Sciences, Alzahra University, Tehran‎, ‎I‎. ‎R‎. ‎Iran

10.22052/mir.2026.257657.1542

Abstract

‎The Bratu-type equation of fractional order possesses considerable theoretical and applied importance‎, ‎as it generalizes a conventional nonlinear differential equation to model phenomena that exhibit inherent memory and non-local interactions‎, ‎which are crucial in fields such as nuclear reactor assessment and the electrospinning process of nanofibers‎. ‎This study presents an innovative block-by-block (multi-step) computational methodology that employs quadratic interpolation to attain high-order accuracy‎. ‎The approach ensures a convergence rate of order $\mathcal{O}(\tau^{4})$‎, ‎significantly enhancing numerical precision concerning the discretization parameter $\tau$‎. ‎Its practical utilization is illustrated through a dedicated algorithm tailored for the fractional Bratu problem‎. ‎The effectiveness and robustness of the proposed method are validated through numerical experiments‎, ‎showcasing its ability to deliver high-fidelity solutions‎.

Keywords

Main Subjects

References

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Mathematics Interdisciplinary Research
Volume 11, Issue 2
In Progress
June 2026
Pages 141-159

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