Ammonia is a cornerstone of modern society, essential for fertilizer production and increasingly recognized as a potential carbon-free energy carrier. However, conventional ammonia synthesis via the fossil-fuel-based Haber–Bosch process is highly energy intensive and responsible for nearly 400 million tons of CO₂ emissions annually, posing a major challenge to global climate mitigation efforts. Green ammonia offers a sustainable alternative by replacing fossil-derived hydrogen with hydrogen produced through renewable energy-powered water electrolysis and combining it with atmospheric nitrogen to synthesize ammonia with near-zero carbon emissions. The core process involves renewable electricity generation (solar, wind, or hydro), electrolytic hydrogen production, nitrogen separation from air, and ammonia synthesis using modified Haber–Bosch or emerging low-temperature pathways such as electrochemical, plasma-assisted, and protonic ceramic technologies. Beyond decarbonizing fertilizer production, green ammonia serves as an efficient hydrogen carrier and long-term energy storage medium, enabling integration of intermittent renewable energy into energy systems and supporting decarbonization of hard-to-electrify sectors such as shipping and power generation. Life-cycle assessments indicate that green ammonia can reduce greenhouse gas emissions by more than 99% compared to conventional ammonia. Although current production costs remain higher due to electricity prices and capital costs, rapid declines in renewable energy costs, advances in electrolyzer and catalyst technologies, and supportive policy frameworks are expected to make green ammonia economically competitive within the next decade. Overall, green ammonia represents a critical and versatile pathway for reducing the global carbon footprint while supporting both food security and the clean energy transition.
Sofi et al. (Thu,) studied this question.