Present State and Future Outlook of Ammonia Production through Photocatalytic Nitrate Reduction

Abstract: Ammonia (NH3) production has gained increasing attention owing to its versatility in both industrial and agricultural applications, as well as its potential as a next‐generation energy carrier with a high hydrogen density. Given the energy‐intensive and environmentally impactful nature of the Haber–Bosch process, there is a pressing need for a sustainable NH3 synthesis method under ambient conditions. Nitrate (NO3−) emerges as a compelling nitrogen source due to its numerous advantages over inert nitrogen (N2)… Show more

“…This has led to significant interest in photocatalytic nitrogen (N 2 ) fixation, which utilizes solar energy to convert abundant atmospheric N 2 into NH 3 . , Nevertheless, the process faces major challenges due to the high dissociation energy, limited aqueous solubility, and low proton affinity of N 2 molecules, resulting in low NH 3 yields. , Nitrate (NO 3 – ) offers a compelling alternative for ammonia production due to its lower dissociation energy (204 kJ/mol vs 941 kJ/mol of N 2 ), high water solubility, and strong proton affinity. A significant amount of nitrate contamination (132 Tg N yr –1 ) in surface and groundwater arises from the use of nitrogen-containing fertilizers in agriculture and emissions from industrial waste. , The presence of nitrates in drinking water can cause numerous health risks, such as blue baby syndrome, birth defects, and cancer . The photocatalytic reduction of NO 3 – to NH 3 , powered by solar energy, presents a groundbreaking solution that addresses both environmental pollution and the rising demand for NH 3 .…”

Advancing the Understanding of Photocatalytic Nitrate Reduction for Ammonia Synthesis: Copper Catalysts and Formic Acid Synergy

“…This has led to significant interest in photocatalytic nitrogen (N 2 ) fixation, which utilizes solar energy to convert abundant atmospheric N 2 into NH 3 . , Nevertheless, the process faces major challenges due to the high dissociation energy, limited aqueous solubility, and low proton affinity of N 2 molecules, resulting in low NH 3 yields. , Nitrate (NO 3 – ) offers a compelling alternative for ammonia production due to its lower dissociation energy (204 kJ/mol vs 941 kJ/mol of N 2 ), high water solubility, and strong proton affinity. A significant amount of nitrate contamination (132 Tg N yr –1 ) in surface and groundwater arises from the use of nitrogen-containing fertilizers in agriculture and emissions from industrial waste. , The presence of nitrates in drinking water can cause numerous health risks, such as blue baby syndrome, birth defects, and cancer . The photocatalytic reduction of NO 3 – to NH 3 , powered by solar energy, presents a groundbreaking solution that addresses both environmental pollution and the rising demand for NH 3 .…”

Advancing the Understanding of Photocatalytic Nitrate Reduction for Ammonia Synthesis: Copper Catalysts and Formic Acid Synergy

Comprehensive analysis of catalysts, reaction mechanisms, and efficiency factors in photocatalytic nitrate-to-ammonia conversion

Preparation of nanoporous TiOx powder and its enhanced photocatalytic N2 to NH3 conversion by solar-driven interfacial water evaporation