Geography functions as an integrative spatial science focused on the organization, interaction, and dynamics of physical and human systems. Recent advancements in geospatial technologies have substantially redefined geographic research by enabling a shift from static, descriptive representations toward analytical, dynamic, and predictive spatial frameworks. This study examines the role of geospatial technologies in the development of geography, emphasizing their influence on methodological innovation and interdisciplinary integration. The evolution of geospatial technologies—from conventional cartography and desktop Geographic Information Systems (GIS) to cloud-based platforms, Web GIS, and GeoAI-driven analytical environments—has expanded the scale, resolution, and temporal depth of geographic analysis. The increasing availability of open-source software, freely accessible Earth observation datasets, coding-based spatial workflows, and cloud computing infrastructures has accelerated data-intensive and reproducible geographic research while reducing technical and economic constraints. The integration of GIS with machine learning and deep learning techniques enables advanced pattern recognition, classification, and predictive modeling of complex spatial phenomena. These capabilities enhance analytical perspectives across major branches of geography, including physical geography, human and urban geography, environmental geography, and landscape studies. Applications such as land use and land cover change detection, landscape connectivity assessment, urban expansion modeling, and climate variability analysis—illustrated through examples from the Indian context, including the Western Ghats and rapidly urbanizing regions—demonstrate the capacity of GeoAI-enabled approaches to address non-linear and multi-scale geographic processes. Geospatial technologies function as foundational components of contemporary geographic inquiry by strengthening spatial reasoning, supporting scenario-based analysis, and enhancing decision-oriented research. Continued integration of intelligent geospatial systems is critical for advancing geography as a predictive, process-based, and solution-oriented discipline capable of addressing complex environmental and societal challenges across multiple spatial and temporal scales.
M et al. (Fri,) studied this question.