{"id":413,"date":"2025-11-29T13:30:56","date_gmt":"2025-11-29T13:30:56","guid":{"rendered":"https:\/\/pulsemss.net\/index.php\/2025\/11\/29\/hidden-copper-switch-supercharges-green-ammonia-production\/"},"modified":"2025-11-29T13:30:56","modified_gmt":"2025-11-29T13:30:56","slug":"hidden-copper-switch-supercharges-green-ammonia-production","status":"publish","type":"post","link":"https:\/\/pulsemss.net\/index.php\/2025\/11\/29\/hidden-copper-switch-supercharges-green-ammonia-production\/","title":{"rendered":"Hidden copper switch supercharges green ammonia production"},"content":{"rendered":"

A hidden shift in copper oxide catalysts to form metallic copper mid-reaction has been identified as the key to supercharging green ammonia production. This surprise discovery offers a clear path toward developing cleaner, more efficient fertiliser synthesis<\/h2>\n

Researchers at Tokyo Metropolitan University have made a discovery that could revolutionise the production of ammonia<\/a>, a vital component of agricultural fertiliser. They found that a common catalyst, copper oxide, undergoes a dramatic, hidden transformation mid-reaction to form metallic copper, which acts as the true powerhouse for boosting ammonia output.<\/p>\n

This development outlines a critical roadmap for developing cleaner, more efficient technologies to produce ammonia, potentially sidestepping the massive carbon footprint associated with current industrial methods.<\/p>\n

The urgent need for green ammonia<\/h3>\n

Ammonia is indispensable to modern agriculture, primarily serving as the backbone of fertilisers that sustain the global food supply. However, its current production method, the Haber-Bosch process, is extremely energy-intensive. This traditional approach requires combining nitrogen and hydrogen under immense temperatures and pressures and is estimated to contribute about 1.4% of global carbon dioxide emissions.<\/p>\n

Given ammonia\u2019s central role in food security, there is an urgent and powerful motivation to find green alternatives that can operate under milder, less energy-demanding conditions.<\/p>\n

Investigating a low-temperature alternative<\/h3>\n

A research group led by Professor Fumiaki Amano at Tokyo Metropolitan University has focused on the electrochemical nitrate reduction reaction. This emerging technique offers a more environmentally friendly route, synthesising ammonia from nitrates at room temperature and normal atmospheric pressure. In this setup, electrodes are immersed in a chemical solution with a voltage applied to drive the reaction. While earlier studies had identified individual steps in this process, the complete sequence of catalytic events remained unclear.<\/p>\n

Unmasking the catalyst\u2019s transformation<\/h3>\n

The team used copper oxide as the electrocatalyst, which is known to be one of the strongest materials for this reaction. To understand its function, they employed operando X-ray absorption, an advanced measurement technique that allows scientists to examine the catalyst’s electronic behaviour and structural changes as the reaction occurs.<\/p>\n

By applying an increasingly negative voltage to small copper oxide particles attached to carbon fibres, the researchers observed two critical phases:<\/p>\n