Abstract:
The Schrödinger equation is one of the fundamentals of quantum theory, which deals
with the study of microparticles. The time-dependent Schrödinger equation (TDSE)
encodes the information of a non-relativistic quantum mechanical system. In this study,
we have investigated the numerical solution techniques to solve TDSE, which involve
partial differential equations (PDEs). The Crank-Nicolson scheme is the average of the
explicit scheme of forward time-centered space and the implicit scheme of backward
time-centered space of finite difference methods. This scheme is derived from the
Taylor series expansion of second-order accuracy and given a better approximation
with exact solutions. We have chosen this scheme in this study because it is
unconditionally stable and attractive for computing unsteady PDE problems. Also, the
accuracy of this scheme can be enhanced without losing the stability of the problem at
the same computational cost per time step. Further, the scheme converges faster than
other numerical methods for the solutions of PDEs. We have examined the complex
valued TDSE using the Crank-Nicolson method with different initial and boundary
condition testing examples. We have also used the simulation techniques of the
MATLAB software to get the numerical results and two-dimensional graphical
representations for the various parameters involving the initial and boundary conditions.
When comparing the numerical results obtained, we have observed a pattern that is
approximately converging by decreasing the time and space interval steps. Similarly,
there is a pattern of increasing the accuracy by increasing the total time values.
