Journal of Experimental Agriculture International

Urban and vertical farming systems have attracted considerable global interest as potential solutions to the converging challenges of rapid urbanization, climate change-induced agricultural disruption, supply chain fragility, and escalating demand for fresh, locally produced food. This research paper investigates the productivity potential, resource use efficiency, economic viability, and environmental footprint of controlled environment agriculture (CEA) systems, with particular focus on plant factory with artificial lighting (PFAL), rooftop greenhouse, and building-integrated vertical farm configurations. Using a comparative analysis framework drawing on published experimental data, life cycle assessment studies, and techno-economic models from systems operating in Asia, Europe, and North America, the paper evaluates how system design parameters including lighting technology, growing substrate, climate control architecture, crop selection, and urban location interact to determine overall system performance. Results indicate that well-optimized vertical farming systems achieve crop yields 10-40 times higher per unit land area than conventional field production for leafy vegetable and herb crops, with water use efficiencies 90-95% superior to open-field equivalents. However, the energy intensity of full-spectrum artificial lighting systems remains a critical challenge: electricity consumption of 20-50 kWh per kilogram of produce represents the dominant cost and environmental impact driver in closed PFAL systems, largely determining economic viability and life cycle carbon footprint. The paper further examines the role of renewable energy integration, waste heat recovery, LED spectral optimization, and advanced climate control algorithms in improving the energy balance of vertical farming systems. Emerging research frontiers including photoperiod manipulation for accelerated crop development, microbiome management in hydroponic root zones, robotic harvesting, and AI-driven crop modeling are evaluated for their potential to improve system performance and reduce unit production costs. The findings have direct implications for investment decision-making, urban food policy design, and the technical development priorities of the vertical farming sector.