Accurate sets of solitary solutions for the quadratic-cubic fractional nonlinear Schrodinger equation

The analytical and semi-analytical solutions to the quadratic-cubic fractional nonlinear Schrodinger equation are discussed in this research article. The model's fractional formula is transformed into an integer-order model by using a new fractional operator. The theoretical and computational approaches can now be applied to fractional models, thanks to this transition. The application of two separate computing schemes yields a large number of novel analytical strategies. The obtained solutions secure the original and boundary conditions, which are used to create semi-analytical solutions using the Adomian decomposition process, which is often used to verify the precision of the two computational methods. All the solutions obtained are used to describe the shifts in a physical structure over time in cases where the quantum effect is present, such as wave-particle duality. The precision of all analytical results is tested by re-entering them into the initial model using Mathematica software 12.

Automated summary

The research article discusses analytical and semi-analytical solutions to the quadratic-cubic fractional nonlinear Schrodinger equation. By transforming the fractional formula into an integer-order model using a new fractional operator, theoretical and computational approaches can now be applied to fractional models, yielding a large number of novel analytical strategies. The solutions obtained are used to describe shifts in physical structures over time in the presence of quantum effects, like wave-particle duality, and the precision of all analytical results is tested using Mathematica software 12.