Date of Award
2026
Degree Type
Restricted to Claremont Colleges Dissertation
Degree Name
Information Systems and Technology, PhD
Program
Center for Information Systems and Technology
Advisor/Supervisor/Committee Chair
Claudia Caceres
Dissertation or Thesis Committee Member
June Hilton
Dissertation or Thesis Committee Member
Itamar Shabtai
Terms of Use & License Information

This work is licensed under a Creative Commons Attribution 4.0 License.
Rights Information
© 2026 Fares Alrewily
Subject Categories
Geographic Information Sciences
Abstract
Peter Drucker once said, "The best way to predict the future is to create it." This idea captures the essence of using artificial intelligence (AI) to shape sustainable agricultural futures in a world facing accelerating climate change, resource depletion, and land degradation. Key crops can be made more resilient through effective frameworks that combine environmental science with artificial intelligence and machine learning. As evidenced in the literature, the olive tree has high economic, cultural, and ecological value; however, it is highly sensitive to climate change. Rising temperatures and declining rainfall in drier and semi-drier regions, such as the northern part of Saudi Arabia, are threatening olive cultivation. Al-Jouf is considered a rapidly emerging center for olive production; however, these stresses threaten long-term agricultural sustainability. The framework we propose integrates ecological niche modeling (ENM), maximum entropy (MaxEnt), and geographic information systems (GIS) to capture complex, nonlinear interactions among bioclimatic, topographic, and soil variables. By employing AI and machine learning to enhance ecological modeling, this research establishes a foundation for predictive, data-driven decision -making in sustainable agriculture and contributes to Saudi Vision 2030 objectives for environmental stewardship, food security, and climate resilience. In short, this study develops an AI-driven species distribution model integrated into a geospatial data-science workflow to assess current and future olive suitability in Al-Jouf under CMIP6 climate scenarios.
ISBN
9798244856125
Recommended Citation
Alrewily, Fares. (2026). AI-Driven Suitability Modeling for Sustainable Olive Cultivation: An Environmental Assessment in a Changing Climate. CGU Theses & Dissertations, 1085. https://scholarship.claremont.edu/cgu_etd/1085.