The study of rainfall patterns and their impact on climate change and marine ecosystems is essential to understanding contemporary environmental challenges. This chapter introduces two innovative models, fractional Poisson and fractional Gamma, to analyze complex rainfall data, effectively handling zero-inflated occurrences and reducing data overdispersion. These models offer greater accuracy and flexibility in representing climate variations and impacts, contributing to more reliable climate prediction tools.
The second part of the chapter explores the dynamic interaction
between phytoplankton and oxygen production in oceans, illustrating how rising
water temperatures disrupt this delicate balance. By integrating Brownian
motion into the mathematical modeling, we provide a framework that allows for a
deeper understanding of how climate change affects oceanic oxygen levels and
the sustainability of marine ecosystems.
In the final phase, we enhance the modeling by adding fractional
Brownian motion, enabling a more precise representation of long-memory effects
and interwoven impacts within the ecosystem. The findings of this study open
new avenues for developing effective strategies to maintain ecosystem
stability, providing scientific tools to support environmental policies in
addressing climate change.
Author
(s) Details
Khairia El-Said
El-Nadi
Department of Mathematics and Computer Science, Faculty of Science,
Alexandria University, Egypt.
M. A. Abdou
Department of Mathematics, Faculty of Education, Alexandria University,
Egypt.
M. A. Fahmy
Department of Mathematics, Faculty of Education, Alexandria University,
Egypt.
Please see the book here:- https://doi.org/10.9734/bpi/mcsru/v1/3243
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