Effect of rotation on anisotropic scattering suspension of phototactic algae

In this article, the effect of rotation on the onset of phototactic bioconvection is investigated using linear stability theory for a suspension of forward-scattering phototactic algae in this article. The suspension is uniformly illuminated by collimated flux. The bio-convective instability is characterized by an unstable mode of disturbance that transitions from a stationary (overstable) to an overstable (stationary) state as the Taylor number varies under fixed parameters. It is also observed that the suspension has significant stabilizing effect due to rotation of the system

Effect of forward scattering and rigid top surface on the onset of phototactic bioconvection in an algal suspension illuminated by both oblique collimated and diffuse irradiation

The effect of the rigid top surface on the onset of phototactic bioconvection is investigated using linear stability theory for a suspension of forward-scattering phototactic algae in this article. The suspension is uniformly illuminated by both diffuse and oblique collimated flux. The nature of disturbance of bio-convective instability transits from a stationary (overstable) to an overstable (stationary) state as the forward scattering coefficient varies under fixed parameters. In presence of rigid top surface, the suspension becomes more stable as the forward scattering coefficient increases

Phototactic bioconvection with the effect of oblique collimated flux at forward scattering algae suspension in rotating medium

The primary objective of this article is to explore how rotation influences the initiation of phototactic bioconvection. This investigation is conducted through the application of linear stability theory to a suspension composed of forward-scattering phototactic algae. The suspension is uniformly exposed to oblique collimated flux. The bioconvection phenomenon is characterized by an unstable disturbance mode that undergoes a transition from a stationary state to an oscillatory state as the Taylor number varies while keeping other parameters constant. Additionally, it is noteworthy that rotation of the system has a substantial stabilizing effect on the suspension

Rotation and Oblique Irradiation Effects on Phototactic Algal Suspension Instability

In this study, we aim to explore the behavior of microorganisms in response to natural lighting conditions, considering the off-normal angles at which the sun strikes the Earth's surface. To achieve this, we investigate the effect of oblique irradiation on a rotating medium, as this combination represents a more realistic scenario in the natural environment. Our primary focus is on understanding the phototactic behavior of microorganisms, which refers to their movement towards or away from light. Under conditions of low light, microorganisms tend to exhibit positive phototaxis, moving towards the light source, while in intense light, they display negative phototaxis, moving away from the light source. By studying a suspension that is illuminated by oblique collimated flux with a constant radiation intensity applied to the top surface, we can gain insights into how microorganisms respond to varying light conditions and rotation. The stability analysis is conducted using linear perturbation theory, which allows us to predict both the stationary and oscillatory characteristics of the bio-convective instability at the onset of bioconvection. Through this analysis, we observe that rotation plays a significant stabilizing role in the system, while oblique irradiation has a destabilizing effect on the suspension.Comment: arXiv admin note: substantial text overlap with arXiv:2306.1447

Thermal phototactic bioconvection in a suspension of isotropic scattering phototactic microorganism

In this investigation, we explore the thermal effects on a suspension containing isotropic scattering phototactic microorganisms. The setup involves illuminating the suspension with collimated irradiation from the top, coupled with heating or cooling applied from the bottom. The governing equations encompass the Navier-Stokes equations with the Boussinesq approximation, the diffusion equation for motile microorganisms, and the energy equation for temperature. Using linear perturbation theory, we conduct a comprehensive analysis of the suspension's linear stability. The findings of this investigation reveal that the suspension experiences increased stability as a consequence of scattering