It is necessary to carefully consider a number of factors in order to predict the fate of persistent organic pollutants in the atmosphere, including their fundamental physical and chemical characteristics, distribution, and transport within and between compartments, organic phenomena, abiotic transformation processes, and effects on living things, including humans. It is frequently exciting to simulate in a lab the processes that control the chemical behavior of organic molecules in the atmosphere in order to gain a deeper understanding as well as to identify the fundamental traits required for successful environmental modelling. However, laboratory exercises that simulate environmental processes are incredibly uncommon. The key abiotic and organic phenomenon processes that affect rates of dissipation should always be taken into consideration when assessing the ecotoxicological effects of chemicals on the aquatic atmosphere. These processes should also be taken into consideration when assessing the concentration of pesticides and metabolites found. Although it is simple to calculate the bioconcentration and bioaccumulation potentials of pesticides in aquatic organisms based on their properties, it is still necessary to take into account the effects of important abiotic and organic phenomenon processes on such pesticides to realise a more precise understanding of how they will have within the natural environment. A flawed environmental impact assessment could be produced by relying primarily on chemical properties. Rates of chemical dissipation and buildup within the aquatic atmosphere are influenced by a variety of factors. Regulators, academics, and industry have all given this important issue of determining how xenobiotic exposures affect aggregate populations, communities, or entire ecosystems more attention in recent decades. This buildup is concerning because it will result in a buildup of highly carcinogenic chemical compounds in the body, which could be harmful to human health and the environment.