Non-Integer order calculation applied in Quantum Mechanics: Particle in a one-dimensional finite well

Fractional calculus is becoming increasingly important nowadays in studying and understanding fundamental physical phenomena, both simple and complex, through the formulation of generalized models. In the present work, a treatment of non-integer order is developed for the study of the wave function that describes the accessible states of a one-dimensional particle confined in a finite well with finite and constant walls, using a conformable derivative in describing the temporal evolution of the states of the system and Caputo-Fabrizio fractional derivative in describing its spatial evolution. By plotting the complete fractional solution ψ(x,t) for given values ​​of the Kernel indices α, β, γ, we recover the flat-wave front oscillations predicted by the integer-order calculation, whose superposition represents the particle state with uniform probability in all space. However, for another range of values ​​of the indices of the integral transformation, damping effects are observed, which do not seem to have a quantum mechanical physical meaning in themselves, but they do have a special physical-mathematical interest since such effects are related to the nature of the Caputo-Fabrizio operator, which as a non-local operator saves memory, that is, non-local spatial effects entail long-range interactions in a physical region, so the generalized wave function obtained does not depend exclusively on a point in space but on a region of space. When calculating the probability density, the fractional wave function shows a definite parity when γ is unitary, just as expected for a symmetric potential well. The generalized model obtained by incorporating a greater number of free parameters can represent an appropriate alternative formulation in the description of the probabilistic behavior of simple and complex quantum mechanical systems. Palabras clave: Ecuación de Schrödinger fraccional; Derivada fraccionaria de Caputo, derivada fraccionaria de Caputo-Fabrizio, derivada general conformable de Khalil. El cálculo fraccionario cobra hoy en día cada vez mayor importancia en el estudio y descripción de fenómenos físicos fundamentales, tanto simples como complejos, a través de la formulación de modelos generalizados. En el presente trabajo se desarrolla un tratamiento de orden no entero para el estudio de la función de onda que describe los estados accesibles de una partícula unidimensional confinada en un pozo de potencial finito con paredes finitas y constantes, emplea