Extended Scalar Particle Solutions in Black String Spacetimes with Anisotropic Quintessence

We present new solutions to the Klein-Gordon equation for a scalar particle in a black string spacetime immersed in an anisotropic quintessence fluid surrounded by a cloud of strings, extending the analysis presented in our previous work. These novel solutions are dependent on the quintessence state parameter, $\alpha_{Q}$, and are now valid for a much larger domain of the radial coordinate. We investigate the cases when $\alpha_{Q} = 0,\,1/2,\,1$, encompassing both black hole and horizonless scenarios. We express the resulting radial wave functions using the confluent and biconfluent Heun functions, with special cases represented by Bessel functions. We derive restrictions on the allowed quantum energy levels by imposing constraints on the Heun parameters to ensure polynomial solutions. Furthermore, we investigate the emergence of "dark phases" associated with the radial wave function, focusing on the interesting case of $\alpha_{Q} = 1$. Our findings provide insights into the dynamics of scalar particles in this complex spacetime and the potential impact of dark energy on quantum systems.