Loading…

Loading grant details…

Completed RESEARCH GRANT UKRI Gateway to Research

Dinitrogen Activation Using Heterobimetallic Complexes Supported by an Extended Cryptand Ligand

£2.01M GBP

Funder Engineering and Physical Sciences Research Council
Recipient Organization King's College London
Country United Kingdom
Start Date May 03, 2021
End Date Jul 30, 2022
Duration 453 days
Number of Grantees 1
Roles Principal Investigator
Data Source UKRI Gateway to Research
Grant ID EP/V04897X/1
Grant Description

Fertilisers. Detergents. Nylons.

All of these products are derived from ammonia, which is produced on a megaton scale every year by the Haber-Bosch process. This is one of the world's most important industrial processes: it is the only commercially viable method for transforming nitrogen from the atmosphere into ammonia. However, the environmental impact of the Haber-Bosch process is huge: between 1-2% of the global energy demand, and 1.4% of global CO2 emissions, are a direct result of this process.

Despite over a century of research, no commercially viable alternatives have been developed to mitigate this damage.

One of the reasons that the Haber-Bosch process consumes so much energy is the need to break the very strong triple bond between two nitrogen atoms, followed by the reaction with hydrogen to generate ammonia. This project aims to develop an entirely new method for synthesising ammonia by using a single molecule as a catalyst to break that triple bond and form ammonia, all in one step.

The key feature of the single molecule is that it will incorporate two different transition metal atoms. One metal will be responsible for binding and activating nitrogen, whilst the other metal atom will carry out the hydrogenation to form ammonia.

Using two different metal atoms means that each metal can be the best one for the job it needs to do, whereas more traditional metal-based catalysts have to compromise on one (or both) parts of this reaction. By selecting the best metals for the job, the energy demand of the reaction will be substantially reduced. This will translate into lower CO2 emissions and lower energy consumption on a global scale.

All Grantees

King's College London

Advertisement
Apply for grants with GrantFunds
Advertisement
Browse Grants on GrantFunds
Interested in applying for this grant?

Complete our application form to express your interest and we'll guide you through the process.

Apply for This Grant