Assessing economically viable carbon reductions for the production of ammonia from biomass gasification

TitleAssessing economically viable carbon reductions for the production of ammonia from biomass gasification
Publication TypeJournal Article
Year of Publication2014
AuthorsGilbert, P., S. Alexander, P. Thornley, and J. Brammer
Journal TitleJournal of Cleaner Production
Volume64
Start Page581
Pagination581-589
KeywordsAmmonia, Biomass gasification, climate change, Life cycle assessment, Nitrogen fertiliser production, Techno economic assessment
Abstract

Greenhouse gas emissions from fertiliser production are set to increase before stabilising due to the increasing demand to secure sustainable food supplies for a growing global population. However, avoiding the impacts of climate change requires all sectors to decarbonise by a very high level within several decades. Economically viable carbon reductions of substituting natural gas reforming with biomass gasification for ammonia production are assessed using techno-economic and life cycle assessment. Greenhouse gas savings of 65% are achieved for the biomass gasification system and the internal rate of return is 9.8% at base-line biomass feedstock and ammonia prices. Uncertainties in the assumptions have been tested by performing sensitivity analysis, which show, for example with a ±50% change in feedstock price, the rate of return ranges between -0.1% and 18%. It would achieve its target rate of return of 20% at a carbon price of £32/t CO2, making it cost competitive compared to using biomass for heat or electricity. However, the ability to remain competitive to investors will depend on the volatility of ammonia prices, whereby a significant decrease would require high carbon prices to compensate. Moreover, since no such project has been constructed previously, there is high technology risk associated with capital investment. With limited incentives for industrial intensive energy users to reduce their greenhouse gas emissions, a sensible policy mechanism could target the support of commercial demonstration plants to help ensure this risk barrier is resolved. © 2013 Elsevier Ltd. All rights reserved.

DOI10.1016/j.jclepro.2013.09.011
Tyndall Consortium Institution

Manchester

Research Programme

Energy