Abstract
A generalization of fractional vector calculus (FVC) as a self-consistent mathematical theory is proposed to take into account a general form of non-locality in kernels of fractional vector differential and integral operators. Self-consistency involves proving generalizations of all fundamental theorems of vector calculus for generalized kernels of operators. In the generalization of FVC from power-law nonlocality to the general form of nonlocality in space, we use the general fractional calculus (GFC) in the Luchko approach, which was published in 2021. This paper proposed the following: (I) Self-consistent definitions of general fractional differential vector operators: the regional and line general fractional gradients, the regional and surface general fractional curl operators, the general fractional divergence are proposed. (II) Self-consistent definitions of general fractional integral vector operators: the general fractional circulation, general fractional flux and general fractional volume integral are proposed. (III) The general fractional gradient, Green’s, Stokes’ and Gauss’s theorems as fundamental theorems of general fractional vector calculus are proved for simple and complex regions. The fundamental theorems (Gradient, Green, Stokes, Gauss theorems) of the proposed general FVC are proved for a wider class of domains, surfaces and curves. All these three parts allow us to state that we proposed a calculus, which is a general fractional vector calculus (General FVC). The difficulties and problems of defining general fractional integral and differential vector operators are discussed to the nonlocal case, caused by the violation of standard product rule (Leibniz rule), chain rule (rule of differentiation of function composition) and semigroup property. General FVC for orthogonal curvilinear coordinates, which includes general fractional vector operators for the spherical and cylindrical coordinates, is also proposed.
Highlights
Vector differential and integral operators are important in various fields of mechanics and physics
The general fractional (GF) gradient theorem should be considered for the line GF Gradient, the FG Stockes theorem should be considered for the surface GF Curl operator, and the GF Green theorem should be considered for the regional GF Divergence
This is due to violation of the chain rule for general fractional derivatives
Summary
Vector differential and integral operators are important in various fields of mechanics and physics. (3) The third stages of the development of fractional vector calculus began in 2021 At this stage, the fractional vector calculus as a self-consistent mathematical theory is generalized for general form of non-locality and general form of kernels of fractional vector differential and integral operators. Self-consistent mathematical theory involves proving generalizations of all fundamental theorems of vector calculus for generalized kernels of operators. This stage began with the work of D’Elia, Gulian, Olson and Karniadakis [40] published in 2021 and based on the generalization of the Meerschaert, Mortensen and Wheatcraft approach to FVC [30]. We use general fractional derivatives (GFDs), general fractional integrals (GFIs) and fundamental theorems of GFC as mathematical tools to formulate General FVC.
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