Ray | Fractional Calculus with Applications for Nuclear Reactor Dynamics | E-Book | sack.de
E-Book

E-Book, Englisch, 235 Seiten

Ray Fractional Calculus with Applications for Nuclear Reactor Dynamics


E-Book, Englisch, 235 Seiten

ISBN: 978-1-4987-2728-0
Verlag: CRC Press
Format: PDF
 Kopierschutz: Adobe DRM (»Systemvoraussetzungen)

Introduces Novel Applications for Solving Neutron Transport Equations

While deemed nonessential in the past, fractional calculus is now gaining momentum in the science and engineering community. Various disciplines have discovered that realistic models of physical phenomenon can be achieved with fractional calculus and are using them in numerous ways. Since fractional calculus represents a reactor more closely than classical integer order calculus, Fractional Calculus with Applications for Nuclear Reactor Dynamics focuses on the application of fractional calculus to describe the physical behavior of nuclear reactors. It applies fractional calculus to incorporate the mathematical methods used to analyze the diffusion theory model of neutron transport and explains the role of neutron transport in reactor theory.

The author discusses fractional calculus and the numerical solution for fractional neutron point kinetic equation (FNPKE), introduces the technique for efficient and accurate numerical computation for FNPKE with different values of reactivity, and analyzes the fractional neutron point kinetic (FNPK) model for the dynamic behavior of neutron motion. The book begins with an overview of nuclear reactors, explains how nuclear energy is extracted from reactors, and explores the behavior of neutron density using reactivity functions. It also demonstrates the applicability of the Haar wavelet method and introduces the neutron diffusion concept to aid readers in understanding the complex behavior of average neutron motion.

This text:

- Applies the effective analytical and numerical methods to obtain the solution for the NDE

- Determines the numerical solution for one-group delayed neutron FNPKE by the explicit finite difference method

- Provides the numerical solution for classical as well as fractional neutron point kinetic equations

- Proposes the Haar wavelet operational method (HWOM) to obtain the numerical approximate solution of the neutron point kinetic equation, and more

Fractional Calculus with Applications for Nuclear Reactor Dynamics thoroughly and systematically presents the concepts of fractional calculus and emphasizes the relevance of its application to the nuclear reactor.
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Autoren/Hrsg.

Ray, Santanu Saha

Fachgebiete

Weitere Infos & Material

Mathematical Methods in Nuclear Reactor Physics
Analytical Methods and Numerical Techniques for Solving Deterministic Neutron Diffusion and Kinetic Models
Numerical Methods for Solving Stochastic Point Kinetic Equations
Neutron Diffusion Equation Model in Dynamical Systems
Introduction
Outline of the Present Study
Application of the Variational Iteration Method to Obtain the Analytical Solution of the NDE
Application of the Modified Decomposition Method to Obtain the Analytical Solution of NDE
Numerical Results and Discussions for Neutron Diffusion Equations
One-Group NDE in Cylindrical and Hemispherical Reactors
Application of the ADM for One-Group Neutron Diffusion Equations
Conclusion
Fractional Order Neutron Point Kinetic Model
Introduction
Brief Description for Fractional Calculus
FNPKE and Its Derivation
Application of Explicit Finite Difference Scheme for FNPKE
Analysis for Stability of Numerical Computation
Numerical Experiments with Change of Reactivity
Conclusion
Numerical Solution for Deterministic Classical and Fractional Order Neutron Point Kinetic Model
Introduction
Application of MDTM to Classical Neutron Point Kinetic Equation
Numerical Results and Discussions for Classical Neutron Point Kinetic Model Using Different Reactivity Functions
Mathematical Model for Fractional Neutron Point Kinetic Equation
Fractional Differential Transform Method
Application of MDTM to Fractional Neutron Point Kinetic Equation
Numerical Results and Discussions for Fractional Neutron Point Kinetic Equation
Conclusion
Classical and Fractional Order Stochastic Neutron Point Kinetic Model
Introduction
Evolution of Stochastic Neutron Point Kinetic Model
Classical Order Stochastic Neutron Point Kinetic Model
Numerical Solution of the Classical Stochastic Neutron Point Kinetic Equation
Numerical Results and Discussions for the Solution of Stochastic Point Kinetic Model
Application of Explicit Finite Difference Method for Solving Fractional Order Stochastic Neutron Point Kinetic Model
Numerical Results and Discussions for the FSNPK Equations
Analysis for Stability of Numerical Computation for the FSNPK Equations
Conclusion
Solution for Nonlinear Classical and Fractional Order Neutron Point Kinetic Model with Newtonian Temperature Feedback Reactivity
Introduction
Classical Order Nonlinear Neutron Point Kinetic Model
Numerical Solution of Nonlinear Neutron Point Kinetic Equation in the Presence of Reactivity Function
Numerical Results and Discussions for the Classical Order Nonlinear Neutron Point Kinetic Equation
Mathematical Model for Nonlinear Fractional Neutron Point Kinetic Equation
Application of EFDM for Solving the Fractional Order Nonlinear Neutron Point Kinetic Model
Numerical Results and Discussions for Fractional Nonlinear Neutron Point Kinetic Equation with Temperature Feedback Reactivity Function
Computational Error Analysis for the Fractional Order Nonlinear Neutron Point Kinetic Equation
Conclusion
Numerical Simulation Using Haar Wavelet Method for Neutron Point Kinetic Equation Involving Imposed Reactivity Function
Introduction
Haar Wavelets
Function Approximation and Operational Matrix of the General Order Integration
Application of the HWOM for Solving Neutron Point Kinetic Equation
Numerical Results and Discussions
Convergence Analysis and Error Estimation
Conclusion
Numerical Solution Using Two- Dimensional Haar Wavelet Method for Stationary Neutron Transport Equation in Homogeneous Isotropic Medium
Introduction
Formulation of Neutron Transport Equation Model
Mathematical Model of the Stationary Neutron Transport Equation in a Homogeneous Isotropic Medium
Application of the Two-Dimensional Haar Wavelet Collocation Method to Solve the Stationary Neutron Transport Equation
Numerical Results and Discussions for Stationary Integer Order Neutron Transport Equation
Mathematical Model for Fractional Order Stationary Neutron Transport Equation
Application of the Two-Dimensional Haar Wavelet Collocation Method to the Fractional Order Stationary Neutron Transport Equation
Numerical Results and Discussions for Fractional Order Neutron Transport Equation
Convergence Analysis of the Two-Dimensional Haar Wavelet Method
Conclusion
References

Dr. Santanu Saha Ray is an associate professor at the National Institute of Technology, Rourkela, India. He earned a Ph. D. in applied mathematics at Jadavpur University. He is a member of SIAM, the AMS, and the Indian Science Congress Association, and serves as the editor-in-chief for the International Journal of Applied and Computational Mathematics. Dr. Saha Ray has done extensive work in the area of fractional calculus and its role in nuclear science and engineering.

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