Abstract:
This research investigates the effect of two
independent first-order reactions occurring concurrently within
a given temperature range. A theoretical simulation-based
approach was employed to analyze the influence of these
concurrent reactions on the kinetic parameters obtained using
the Friedman isoconversion method. A novel technique for
separating the kinetic parameters of two reactions is also
discussed here. The results demonstrate that, in most cases, the
disparity between the actual activation energies of the two
reactions and the values obtained through the Friedman
isoconversion method is minimal, with an error of less than 1%.
However, when the two first-order reactions exhibit DTG peaks
within the same temperature range, the error can escalate to as
high as 15%.
This investigation provides valuable insights into the errors
associated with kinetic parameter estimations on multiple
simultaneous reactions. The findings contribute to a more indepth
understanding of reaction kinetics and offer important
substances for experimental design and reaction optimization in
various fields.
Citation:
P. S. S. Panawala, P. K. Kanchana, D. A. S. Amarasinghe, D. Attygalle, A. M. P. B. Samarasekara and V. S. C. Weragoda, "Feasibility Assessment of Obtaining Kinetic Parameters for Independent Simultaneous First-Order Reactions Using Friedman Isoconversion Analysis," 2023 Moratuwa Engineering Research Conference (MERCon), Moratuwa, Sri Lanka, 2023, pp. 556-561, doi: 10.1109/MERCon60487.2023.10355525.