A data-driven exploration of Stratospheric Ozone dynamics : Bridging regional Ozone insights with environmental policy
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BRAC University
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Abstract
The stratospheric ozone can be very crucial in protecting the Earth against harmful
UV radiation, as well as its restoration after the 1987 Montreal protocol, is unevenly
spread in various regions. This research is a data-based examination of the longterm
dynamics of the ozone in various countries despite having different climatic and
geographical settings, which showed specific recovery in various regions. The study
models complex seasonal and nonlinear ozone behavior, using the support of more
complex feature engineering, which incorporates lag variables, rolling averages, and
temporal indicators based on advanced deep-learning models: LSTM, GRU, TCN,
Transformer, and hybrid solutions. Model assessment, which is based on the combination
of accuracy measures and uncertainty estimation, indicates that LSTM is the
best in terms of explanatory performance, and GRU achieves the lowest in terms
of MAE and RMSE in all six climatic regions. Another meta-analysis conducted
across all regions further synthesizes recovery slopes and prediction error and levels
of uncertainty, with strong recovery rates in the Tropical, Temperate regions, and
slower or more erratic rates in Polar, Subpolar, and Arid regions. A policy modeling
framework based on the use of data-driven insights to inform climate-aligned policies
in SDG 13 (Climate Action), the mitigation of UV-risks in SDG 3 (Good Health
and Well-being), and the improvement of environmental planning in SDG 11 (Sustainable
Cities and Communities) is also introduced in the study. This framework
offers an evidence-based and scalable policy instrument to monitor the environment
in the long term and make decisions to bridge long-term ozone recovery and policy
action recommendations to sustainable climate decisions.
Description
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 91-93).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2025.
Includes bibliographical references (pages 91-93).
This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Science in Computer Science, 2025.
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Thesis