Abstract:
From microscopic to the macroscopic level, complexity has emerged as a
unifying aspect of our environment. In the domain of complex systems, ranging from
physical to biological processes, it is critical to improving our understanding and
skills. Moving in this direction, one must give due attention to transportation, one
of the key factors on which the complex systems heavily rely. Vehicular flow is one of
the most evident processes which arises in our commute to work, stores, hospitals,
schools, and universities, etc. Some not so visible yet important transportation
processes happen inside our body at the intracellular level too. These include the
movement of motor proteins on micro-tubules that transport the cargo within the
cell. In the aforementioned phenomena, the movement of entities, namely, vehicles
and motor proteins are powered by fuel and ATP, respectively, thereby categorizing
them into a special class of non-equilibrium processes, known as the driven di↵usive
systems. The characteristic feature of such systems is the existence of a non-zero
current even when other properties are unchanging with time.
Over the years, an exclusion model, particularly, Totally Asymmetric Simple
Exclusion Process (TASEP) has emerged as one of the paradigms to study the driven
di↵usive systems. This model is characterized by the unidirectional flow of particles
representing the vehicles, motor proteins, etc., on a discrete lattice portraying their
respective pathways with a constant rate. Relying on this framework, we contribute
to a comprehensive understanding of the collective behavior of particles in variations
of the single and multi-lane models. Motivated by the movement of motor proteins,
we analyze the impact of an inhomogeneity in the system in the form of a stochastic
blockage on a non-conserving TASEP model. We implore the non-trivial e↵ects
of the defect dynamics, as well as the non-conserving kinetics in terms of density
profiles, phase diagrams, etc. Moving forward, we explore the behavior of biological
and physical systems where the total entities remains conserved. In this direction,
we study ring-like lattice where the entities may move at the non-constant rate which
can be a↵ected by two factors: the position on the lattice, as well as the neighboring
entities. In the recent years, a modification of TASEP has emerged where both the
ends of the discrete lattice is connected to a finite reservoir, thus reflecting the limited
availability of resources in a real system. Instigated by these considerations, we work
on a TASEP model where the entry and exit of particles from the inhomogeneous
lattice are regulated by the occupancy of the reservoir. Moreover, this inhomogeneity
in the lattice is introduced as an impact of the stochastic blockage. We investigate
the collective e↵ect of these dynamics on the system properties. Furthermore,
we analyze a TASEP model where the entities can attach to or detach from the
entirety of the lattice under the constraint of available resources and the crowding of reservoir. Stepping forward, we also study a bidirectional TASEP model, where
the particles move in opposite directions classifying them into two distinct species
in a conserved environment where the reservoir modulates the entry-exit of entities.
Finally, we examine a model having two lattices with strategically placed distinct
reservoirs together forming a ring-like structure which opens up the domain of
studying the interplay of these reservoirs.
In brief, we utilized mathematical modeling to comprehend the previously
unknown diculties that may arise in transport processes, which are also seen
through simulations, making it critical to understand the collective dynamics of
moving entities.