A viable mathematical modeling for the aspects of material cycling in the context of power plants environment

Generally the environments in the context of power plants are to be streamlined due to the existence of species of pollutants and nutrients. Therefore it is essential to regulate the aspects of material cycling in the case of power plants because of its polluting environment. The passengers of elemental materials like carbon, phosphorus or nitrogen, shows up a linear species chain and either considered the primary production rate to be constant or represented as resource limitations especially by means of a logistic function. Basically the assumption of constant primary production is slightly opposite, when the bio-mass of primary producers does not fall very less and their productivity is limited by some factors other than element being modeled, for example “light”. However in closed systems, the elemental matters needed for primary productions must be provided through re-cycling by mortality and respiration in the case of carbon, or by mortality and excretion in the case of phosphorus or nitrogen. But some of the ecosystems in the power plants environments are closed to carbon, therefore it is very much essential to investigate the issues related to material cycling under the purview of dynamic implications of an elemental nutrient including nitrogen and phosphorus. In this context, a viable mathematical modeling is proposed for regulating the issues of species pollutions in the case of ecosystems in the power plants as a generic model.