Ammonia

Valera-Medina Agustin; Mashruk Syed; Pugh Daniel; Bowen Phil

doi:10.1017/9781009072366.011

8 - Ammonia

Published online by Cambridge University Press: 01 December 2022

Valera-Medina Agustin ,

Mashruk Syed ,

Pugh Daniel and

Bowen Phil

Edited by

Jacqueline O'Connor ,

Bobby Noble and

Tim Lieuwen

Show author details

Jacqueline O'Connor: Affiliation:
Pennsylvania State University
Bobby Noble: Affiliation:
Electric Power Research Institute
Tim Lieuwen: Affiliation:
Georgia Institute of Technology

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Summary

Ammonia is the second most transported chemical in the world today, with a global annual trade of around 180 Mtons. The history of the chemical’s generation and widespread utilization is based around demand from global food production, resulting in rapid expansion of the fertilizer industry through the twentieth century. Current widespread utilization of ammonia facilitated by global transportation has been enabled through the significant breakthrough of two German Nobel prizewinners (Fritz Haber and Carl Bosch) in the early twentieth century. Their catalytic Haber–Bosch process enabled the creation of ammonia from its constituent elements on industrial scale for the first time. The chemical can be utilized as a fuel via two main routes: first, by cracking ammonia to recover hydrogen prior to utilization in a combustion system or fuel cell, or secondly by direct ammonia use. Whereas the former requires an additional process penalty, the latter is less well publicized to the inherent difficulties associated with direct ammonia/air utilization, excessive NOx production when unproperly burned, and slow reaction kinetics, resulting in challenges associated with ignition and flame stability. Recent advances on enhanced ammonia combustion strategies have increased the potential of directly fired ammonia utilization or ammonia/fuel mixtures.

Keywords

Haber-Bosch gray ammonia blue ammonia green ammonia carbon-free fuel internal combustion engine gas turbines furnaces boilers fuel cells

Type: Chapter
Information: Renewable Fuels
Sources, Conversion, and Utilization
, pp. 245 - 274

DOI: https://doi.org/10.1017/9781009072366.011 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

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References

AFC Energy (2013). AFC wins funding for Alkammonia project, gains Diverse Energy. Fuel Cells Bulletin, 2013(1), 9. doi: 10.1016/S1464-2859(13)70022-1.Google Scholar

Afif, A., Radenahmad, N., Cheok, Q., Shams, S., Kim, J. H. and Azad, A. K. (2016). Ammonia-fed fuel cells: A comprehensive review. Renewable and Sustainable Energy Reviews, 60, 822–35. doi: 10.1016/j.rser.2016.01.120.CrossRef Google Scholar

Appl, M. (2011a). Ammonia, 1. Introduction, in Barbara Elvers (ed) Ullmann’s encyclopedia of industrial chemistry. Wiley-VCH Verlag GmbH & Co. KGaA, 107. doi: 10.1002/14356007.a02_143.pub3.Google Scholar

Appl, M. (2011b). Ammonia, 2. Production processes. in Barbara Elvers (ed) Ullmann’s encyclopedia of industrial chemistry. Wiley-VCH Verlag GmbH & Co. KGaA, 139.doi: 10.1002/14356007.o02_o11.Google Scholar

Argus Media Group (2019). Magellan midstream to decommission ammonia pipeline. Available at: www.argusmedia.com/en/news/1839099-magellan-midstream-to-decommission-ammonia-pipeline (Accessed: May 30, 2021).Google Scholar

Arif, K. and Brian, E. (2012). Fuel conditioning system for ammonia fired power plants, 2012 Annual NH3 Fuel Conference.Google Scholar

Asian Renewable Energy Hub (2020). About the Asian Renewable Energy Hub. Available at: https://asianrehub.com/about/ (Accessed: May 30, 2021).Google Scholar

Ballard (2016). Fuel cell power module for heavy duty motive applications. Burnaby: Ballard. Available at: www.ballard.com/docs/default-source/motive-modules-documents/fcvelocity_hd_family_of_products_low_res.pdf (Accessed: May 30, 2021).Google Scholar

Barkan, C. (2014). Introduction to North American rail transportation. Railway Engineering Education Symposium.Google Scholar

Bazhenova, T. A. and Shilov, A. E. (1995). Nitrogen fixation in solution. Coordination Chemistry Reviews. 60, 69–145. doi: 10.1016/0010-8545(95)01139-G.Google Scholar

Boothroyd, R. G. (2014). A proposed Australian transition to an anhydrous ammonia fuel transport economy to replace liquid petroleum fuels, in Al-Kayiem, H. H., Brebbia, C. A., and Zubir, S. S. (eds.), Energy and sustainability V. WIT Press, 443–56.Google Scholar

Božo, M. G., Mashruk, S., Zitouni, S. and Valera-Medina, A. (2021). Humidified ammonia/hydrogen RQL combustion in a trigeneration gas turbine cycle. Energy Conversion and Management, 227, 113625. doi: 10.1016/j.enconman.2020.113625.CrossRef Google Scholar

BP (2019). Statistical Review of World Energy. Available at: www.bp.com/en/global/corporate/energy-economics/statistical-review-of-world-energy.html (Accessed: May 5, 2021).Google Scholar

Brown, D. E., Edmonds, T., Joyner, R. W., McCarroll, J. J. and Tennison, S. R. (2014). The genesis and development of the commercial BP doubly promoted catalyst for ammonia synthesis. Catalysis Letters, 144(4), 545–52. doi: 10.1007/s10562-014-1226-4.Google Scholar

Brown, T. (2017). The new generation of fuel cells: Fast, furious, and flexible. Ammonia Energy. Available at: www.ammoniaenergy.org/the-new-generation-of-fuel-cells-fast-furious-and-flexible/ (Accessed: July 17, 2019).Google Scholar

Brown, T. (2020). Saudi Arabia to export renewable energy using green ammonia. Ammonia Energy Association. Available at: www.ammoniaenergy.org/articles/saudi-arabia-to-export-renewable-energy-using-green-ammonia/ (Accessed: May 30, 2021).Google Scholar

Bruce, S., Temminghoff, M., Hayward, J., Schmidt, E., Munnings, C., Palfreyman, D. and Hartley, P. (2018). National Hydrogen Roadmap – CSIRO. Available at: https://publications.csiro.au/rpr/pub?pid=csiro:EP184600 (Accessed: May 4, 2021).Google Scholar

Burén, S. and Rubio, L. M. (2018). State of the art in eukaryotic nitrogenase engineering. FEMS Microbiology Letters, 365(2), fnx274. doi: 10.1093/femsle/fnx274.Google Scholar

Cardin, M. (2011). Ammonia as a refrigerant: Pros and cons, goodway. Available at: www.goodway.com/hvac-blog/2009/08/ammonia-as-a-refrigerant-pros-and-cons/ (Accessed: May 30, 2021).Google Scholar

Cavaliere, A. and De Joannon, M. (2004). Mild combustion. Progress in Energy and Combustion Science, 30(4), 329–66. doi: 10.1016/j.pecs.2004.02.003.CrossRef Google Scholar

Cefic, E. (2011). Guidelines for measuring and managing CO2 emission from freight transport operations. Cefic Reports, 1, 1–18.Google Scholar

Cesaro, Z., Ives, M., Nayak-Luke, R., Mason, M. and Bañares-Alcántara, R. (2021). Ammonia to power: Forecasting the levelized cost of electricity from green ammonia in large-scale power plants. Applied Energy, 282(Part A), 116009. doi: 10.1016/j.apenergy.2020.116009.CrossRef Google Scholar

Chellappa, A. S., Fischer, C. M. and Thomson, W. J. (2002). Ammonia decomposition kinetics over Ni-Pt/Al2O3 for PEM fuel cell applications. Applied Catalysis A: General, 227(1–2), 231–40. doi: 10.1016/S0926-860X(01)00941-3.Google Scholar

Cherkasov, N., Ibhadon, A. O. and Fitzpatrick, P. (2015). A review of the existing and alternative methods for greener nitrogen fixation. Chemical Engineering and Processing: Process Intensification, 90, 24–33. doi: 10.1016/j.cep.2015.02.004.CrossRef Google Scholar

Committee on Climate Change (CCC) (2019). Net Zero – The UK’s contribution to stopping global warming – Climate Change Committee. Available at: www.theccc.org.uk/publication/net-zero-the-uks-contribution-to-stopping-global-warming/ (Accessed: May 5, 2021).Google Scholar

Cornelius, W., Huellmantel, L. W. and Mitchell, H. R. (1965). Ammonia as an engine fuel. SAE Technical Papers. doi: 10.4271/650052.CrossRef Google Scholar

Dincer, I. and Zamfirescu, C. (2012). Apparatus for using ammonia as a sustainable fuel, refrigerant and NOx reduction agent. Available at: https://patents.google.com/patent/US8272353B2/en.Google Scholar

Dincer, I. and Zamfirescu, C. (2016). A review of novel energy options for clean rail applications. Journal of Natural Gas Science and Engineering, 28, 461–78. doi: 10.1016/j.jngse.2015.12.007.CrossRef Google Scholar

DNV-GL (2018). Maritime forecast to 2050. Energy Transition Outlook 2018. Available at: https://eto.dnv.com/2019/Maritime/forecast (Accessed: May 30, 2021).Google Scholar

Dolan, M. (2018). Pilot-scale NH3-to-H2 system for FCEV refuelling. NH3 Event 2018. Rotterdam. www.ammoniaenergy.org/event/nh3-fuel-conference-2018/Google Scholar

Duijm, N. J., Markert, F. and Paulsen, J. L. (2005). Safety assessment of ammonia as a transport fuel. Denmark: Risø National Laboratory. Available at: www.osti.gov/etdeweb/servlets/purl/20607161.Google Scholar

Duynslaegher, C., Jeanmart, H. and Vandooren, J. (2009). Use of ammonia as a fuel for SI engine. Proceedings of the European Combustion Meeting. Available at: www.academia.edu/1093081/Use_of_ammonia_as_a_fuel_for_SI_engine.Google Scholar

Elishav, O., Mosevitzky Lis, B., Miller, E. M., Arent, D. J., Valera-Medina, A., Grinberg Dana, A., Shter, G. E. and Grader, G. S. (2020). Progress and prospective of nitrogen-based alternative fuels. Chemical Reviews, 120(12), 5352–436. doi: 10.1021/acs.chemrev.9b00538.CrossRef Google Scholar PubMed

ETN (2020). FLEXnCONFU. Available at: https://flexnconfu.eu (Accessed: May 30, 2021).Google Scholar

European Fertilizer Manufacturers Association (2007). Guidance for transporting ammonia by rail. 2nd ed. Brussels: European Fertilizer Manufacturers Association. Available at: https://cefic.org/app/uploads/2018/12/Transporting-Ammonia_ByRail-by-EFMA-2007-GUIDELINES-_ROAD-SUBSTANCE.pdf.Google Scholar

Forbes, C. (2020). Zero emission vessels for shipping: Optimising a green ammonia production, distribution and port bunkering network. MEng thesis. University of Oxford.Google Scholar

Frigo, S., Gentili, R. and De Angelis, F. (2014). Further Insight into the Possibility to Fuel a SI Engine with Ammonia plus Hydrogen. SAE/JSAE 2014 Small Engine Technology Conference & Exhibition. Pisa: SAE International. doi: 10.4271/2014-32-0082.CrossRef Google Scholar

Ganley, J. C. and Bowery, M. S. (2010). Engine-ready, carbon free ammonia fuel. 2010 Annual NH3 Fuel Conference. Available at: https://nh3fuel.files.wordpress.com/2012/05/afc_2010_ganleyjc_boweryms.pdf (Accessed: August 21, 2019).Google Scholar

Grannell, S., Stack, C. and Gillespie, D. (2010). A comparison of combustion promoters for ammonia and two ways to run engines on ammonia as the only fuel. 2010 Annual NH3 Fuel Conference, 14.Google Scholar

Grasham, O., Dupont, V., Camargo-Valero, M. A., García-Gutiérrez, P. and Cockerill, T. (2019). Combined ammonia recovery and solid oxide fuel cell use at wastewater treatment plants for energy and greenhouse gas emission improvements. Applied Energy, 240, 698–708. doi: 10.1016/j.apenergy.2019.02.029.Google Scholar

Gray, J.T., Meckel, N.T., Quillian, R.D., and Dimitroff, E. (1966). Ammonia fuel-engine compatibility and combustion. SAE Technical Paper 660156.Google Scholar

Gross, C. W. and Kong, S. C. (2013). Performance characteristics of a compression-ignition engine using direct-injection ammonia-DME mixtures. Fuel, 103, 1069–79. doi: 10.1016/j.fuel.2012.08.026.Google Scholar

Hejze, T., Besenhard, J. O., Kordesch, K., Cifrain, M. and Aronsson, R. R. (2008). Current status of combined systems using alkaline fuel cells and ammonia as a hydrogen carrier. Journal of Power Sources, 176(2), 490–93. doi: 10.1016/j.jpowsour.2007.08.117.Google Scholar

Hernandez, F. (2013). La cifra de muertos por la fuga de amoniaco en Oaxaca aumenta a nueve. CNN Mexico. Available at: https://expansion.mx/nacional/2013/08/20/una-fuga-de-amoniaco-de-un-ducto-de-pemex-causa-tres-muertos-en-oaxaca (Accessed: August 28, 2019).Google Scholar

Hewlett, S. G., Valera-Medina, A., Pugh, D. G. and Bowen, P. J. (2019). Gas turbine co-firing of steelworks ammonia with coke oven gas or methane: A fundamental and cycle analysis. Proceedings of the ASME Turbo Expo. Phoenix, Arizona, GT2019-91404. doi: 10.1115/GT2019-91404.CrossRef Google Scholar

Hignett, T. P. (1985). Transportation and storage of ammonia. Fertilizer Manual. Dordrecht: Springer Netherlands, 73–82. doi: 10.1007/978-94-017-1538-6_7.Google Scholar

Hiraoka, K., Fujimura, Y., Watanabe, Y., Kai, M., Sakata, K., Ishimoto, Y. and Mizuno, Y. (2018). Cost Evaluation Study on Low Carbon Ammonia and Coal Co-Fired Power Generation. NH3 Fuel Conference, 1–16. Available at: www.ammoniaenergy.org/wp-content/uploads/2019/12/0830-Cost-Evaluation-Study-on-Low-Carbon-NH3_JGC-IAE.pdf (Accessed: May 5, 2021).Google Scholar

International Energy Agency (2019). Future of hydrogen. Available at: www.iea.org/hydrogen2019/ (Accessed: January, 19 2021).Google Scholar

ISPT (2017). Power to ammonia. Report. Amersfoort: ISPT. Available at: www.ispt.eu/media/ISPT-P2A-Final-Report.pdf (Accessed: January 19, 2021).Google Scholar

Ito, Shintaro, Uchida, Masahiro, Onishi, Shogo, Fujimor, T., and Kobayashi, T.. (2018). Performance of ammonia-natural gas co-fired gas turbine for power generation. AIChE Annual Meeting. Available at: https://nh3fuelassociation.org/2018/12/07/performance-of-ammonia-natural-gas-co-fired-gas-turbine-for-power-generation/Google Scholar

Ito, T., Ishii, H., Zhang, J., Ishihara, S. and Suda, T. (2019). New technology of the ammonia co-firing with pulverized coal to reduce the NOx emission. AIChE Annual Meeting. Available at: www.ammoniaenergy.org/wp-content/uploads/2019/08/20191112.1517-AIChE2019_IHI_final.pdf (Accessed: May 5, 2021).Google Scholar

Khateeb, A. A., Guiberti, T. F., Zhu, X., Younes, M., Jamal, A. and Roberts, W. L. (2020). Stability limits and NO emissions of technically-premixed ammonia-hydrogen-nitrogen-air swirl flames. International Journal of Hydrogen Energy, 45(41), 22008–18. doi: 10.1016/j.ijhydene.2020.05.236.Google Scholar

Koike, M., Miyagawa, H., Suzuoki, T. and Ogasawara, K. (2012). Ammonia as a hydrogen energy carrier and its application to internal combustion engines. Institution of Mechanical Engineers – Sustainable Vehicle Technologies: Driving the Green Agenda, 1, 61–70. doi: 10.1533/9780857094575.2.61.CrossRef Google Scholar

Kondo, S., Takahashi, A., Tokuhashi, K. and Sekiya, A., (2002). RF number as a new index for assessing combustion hazard of flammable gases. Journal of Hazardous Materials, 93(3), 259–67. doi: 10.1016/S0304-3894(02)00117-6.Google Scholar

Korean Register (KR) (2019). Forecasting the alternative marine fuel: Ammonia. Available at: www.krs.co.kr/TECHNICAL_FILE/KR_Forecasting the Alternative Marine Fuel_Ammonia.pdf (Accessed: May 5, 2021).Google Scholar

Kroch, E. (1945). Ammonia – a fuel for motor buses. Journal of the Institute of Petroleum, 31, 343–50. Available at: http://claverton-energy.com/cms4/wp-content/files/NH3_bus_1945_JInstPetrol31_Pg213.pdf.Google Scholar

Kujiraoka, H., Izumi, T., Yoshizuru, Y., Suemasy, T., Ueda, M., Niki, T., Itou, T., Nishio, M., Murai, R. and Akamatsu, F. (2018). Evaluation of the cement clinker fired in the combustion furnace of heavy-oil and NH3. AIChE Annual Meeting. Available at: https://nh3fuelassociation.org/wp-content/uploads/2018/12/1700-549g181031_Kujiraoka_UBE_NoAPP.pdf.Google Scholar

Kurata, O., Iki, N., Matsunuma, T., Inoue, T., Tsujimura, T., Furutani, H., Kobayashi, H. and Hayakawa, A. (2017). Performances and emission characteristics of NH3 –air and NH3 CH4 –air combustion gas-turbine power generations. Proceedings of the Combustion Institute, 36(3), 3351–59. doi: 10.1016/j.proci.2016.07.088.Google Scholar

Kurata, O., Iki, N., Inoue, T., Matsunuma, T., Tsujimura, T., Furutani, H., Kawano, M., Arai, K., Okafor, E. C., Hayakawa, A. and Kobayashi, H. (2019). Development of a wide range-operable, rich-lean low-NOx combustor for NH3 fuel gas-turbine power generation. Proceedings of the Combustion Institute, 37(4), 4587–95. doi: 10.1016/j.proci.2018.09.012.Google Scholar

Kurvits, T. and Marta, T. (1998). Agricultural NH3 and NOx emissions in Canada. Environmental Pollution, 102(1), 187–94. doi: 10.1016/S0269-7491(98)80032-8.Google Scholar

Lan, R., Irvine, J. T. S. and Tao, S. (2012). Ammonia and related chemicals as potential indirect hydrogen storage materials. International Journal of Hydrogen Energy, 37(2), 1482–94. doi: 10.1016/j.ijhydene.2011.10.004.CrossRef Google Scholar

Lanser, A. (2019). Controlled industrial-scale combustion of Ammonia for high-temperature applications. NH3 European Conference. Available at: https://nh3event.com/presentations/.Google Scholar

Lee, D. (2018). Simulation study of the new combustion strategy of pre-combustion-assisted compression ignition for internal combustion engine fueled by pure ammonia. Department of Mechanical Engineering, Seoul National University. Available at: https://hdl.handle.net/10371/140573.Google Scholar

Leeladhar, R., Grannell, S., Bohac, S., and Assanis, D. (2012). Comparison of ammonia/gasoline and ammonia/ethanol fuel mixtures for use in IC engines. NH3. Available at: https://nh3fuelassociation.org/wp-content/uploads/2012/05/leeladhar_nh3.pdf.Google Scholar

Leighty, B. (2008). Energy storage with anhydrous ammonia: Comparison with other energy storage. Annual NH3 fuel conference: Ammonia: The key to US Energy Independence.Google Scholar

Leighty, W. C. (2013). Alaska’s renewables-source ammonia fuel energy storage pilot plant: Toward community energy independence. Power and Energy Society General Meeting (PES), 2013 IEEE. IEEE, 1–5.CrossRef Google Scholar

Leighty, W. C. and Holbrook, J. H. (2012). Alternatives to electricity for transmission, firming storage, and supply integration for diverse, stranded, renewable energy resources: Gaseous hydrogen and anhydrous ammonia fuels via underground pipelines. Energy Procedia, 29, 332–46. doi: 10.1016/j.egypro.2012.09.040.Google Scholar

Lloyd’s Register and UMAS (2020). Techno-economic assessment of zero-carbon fuels. Lloyds Register (March). Available at: www.lr.org/en-gb/insights/global-marine-trends-2030/techno-economic-assessment-of-zero-carbon-fuels/ (Accessed: May 4, 2021).Google Scholar

Ma, Q., Ma, J., Zhou, S., Yan, R., Gao, J. and Meng, G. (2007). A high-performance ammonia-fueled SOFC based on a YSZ thin-film electrolyte. Journal of Power Sources, 164(1), 86–89. doi: 10.1016/j.jpowsour.2006.09.093.Google Scholar

MacFarlane, D. R. et al. (2020). A roadmap to the ammonia economy. Joule, 4(6), 1186–205. doi: 10.1016/j.joule.2020.04.004.Google Scholar

MAN Energy Solutions (2019). Engineering the future two-stroke green-ammonia engine. Copenhagen, Denmark: MAN Energy Solutions. Available at: https://fathom.world/wp-content/uploads/2020/05/engineeringthefuturetwostrokegreenammoniaengine1589339239488.pdf.Google Scholar

Mitsubishi Power Ltd. (2021). Mitsubishi power commences development of world’s first ammonia-fired 40MW class gas turbine system. Available at: https://power.mhi.com/news/20210301.html (Accessed: May 30, 2021).Google Scholar

Mørch, C. S., Bjerre, A., Gøttrup, M. P., Sorenson, S. C. and Schramm, J. (2011). Ammonia/hydrogen mixtures in an SI-engine: Engine performance and analysis of a proposed fuel system. Fuel, 90(2), 854–64. doi: 10.1016/j.fuel.2010.09.042.Google Scholar

Morgan, E. R. (2013). Techno-economic feasibility study of ammonia plants powered by offshore wind recommended citation – PhD Thesis. University of Massachusetts Amherst.Google Scholar

Morgan, E. R., Manwell, J. F. and McGowan, J. G. (2017). Sustainable ammonia production from U.S. offshore wind farms: A techno-economic review. ACS Sustainable Chemistry and Engineering, 5(11), 9554–67. doi: 10.1021/acssuschemeng.7b02070.CrossRef Google Scholar

National Transportation Safety Board (2004). Pipeline Accident Brief. Accident no. DCA05-MP001. Washington DC, U.S.A.Google Scholar

Newhall, H. and Starkman, E. (1966). Theoretical performance of ammonia as a gas turbine fuel. SAE Technical Paper 660768.Google Scholar

Ngayan, N., Kristoff, A. and Simonova, A. (2015). Togliattiazot danger: Ammonia pipeline disaster in southern Russia, Ecology Russia. Available at: http://ecologyrussia.com/togliattiazot-danger-ammonia-pipeline-disaster-in-southern-russia/ (Accessed: May 30, 2021).Google Scholar

Ni, M., Leung, D. Y. C. and Leung, M. K. H. (2008). Electrochemical modeling of ammonia-fed solid oxide fuel cells based on proton conducting electrolyte. Journal of Power Sources, 183(2), 687–92. doi: 10.1016/j.jpowsour.2008.05.018.Google Scholar

Niels de Vries (2019). Safe and effective application of ammonia as a marine fuel. TU DELFT. Available at: https://repository.tudelft.nl/.Google Scholar

Niki, Y., Nitta, Y., Sekiguchi, H. and Hirata, K. (2019). Diesel fuel multiple injection effects on emission characteristics of diesel engine mixed ammonia gas into intake air. Journal of Engineering for Gas Turbines and Power, 141(6), 061020. doi: 10.1115/1.4042507.Google Scholar

Nyborg, R. and Lunde, L. (1996). Measures for reducing SCC in anhydrous ammonia storage tanks. Process Safety Progress, 15(1), 32–41. doi: 10.1002/prs.680150110.CrossRef Google Scholar

Office of Industrial Relations Wokplace Health and Safety Queensland (2018). Emergency planning for ammonia-based refrigeration systems guide. Queensland, Australia. Available at: www.worksafe.qld.gov.au/__data/assets/pdf_file/0020/20954/ammonia-based-refrigeration-systems.pdf.Google Scholar

Okafor, E. C., Somarathne, K. K. A., Hayakawa, A., Kudo, T., Kurata, O., Iki, N. and Kobayashi, H. (2019). Towards the development of an efficient low-NOx ammonia combustor for a micro gas turbine. Proceedings of the Combustion Institute, 37(4), 4597–606. doi: 10.1016/j.proci.2018.07.083.CrossRef Google Scholar

Oram, B. (2014). Ammonia in groundwater, runoff, surface water, lakes and streams. Water Research Wastershed Centre. Available at: https://water-research.net/index.php/ammonia-in-groundwater-runoff-and-streams (Accessed: May 30, 2021).Google Scholar

Papavinasam, S. (2014). Oil and gas industry network. in Papavinasam, S. (ed), Corrosion control in the oil and gas industry. Oxford, UK: Gulf Professional Publishing, 41–131. doi: 10.1016/b978-0-12-397022-0.00002-9.Google Scholar

Pfromm, P. H. (2017). Towards sustainable agriculture: Fossil-free ammonia. Journal of Renewable and Sustainable Energy, 9(3), p. 034702. doi: 10.1063/1.4985090.Google Scholar

Philibert, C. (2018). Renewable energy for industry: Offshore wind in Northern Europe. Rotterdam, the Netherlands: International Energy Agency. Available at: https://iea.blob.core.windows.net/assets/bfc5d90a-07e5-4f14-8ee2-f91763fbd99f/OffshoreDecarbEUIndustry.pdf.Google Scholar

Pochet, M., Truedsson, I., Foucher, F., Jeanmart, H. and Contino, F. (2017). Ammonia-hydrogen blends in homogeneous-charge compression-ignition engine. 2017-24-0087: SAE International.Google Scholar

Porter, D. H. (1998). The life and times of Sir Goldsworthy Gurney: Gentleman scientist and inventor, 1793–1875. Lehigh University Press.Google Scholar

Pugh, D., Bowen, P., Valera-Medina, A., Giles, A., Runyon, J. and Marsh, R. (2019). Influence of steam addition and elevated ambient conditions on NOx reduction in a staged premixed swirling NH3/H2 flame. Proceedings of the Combustion Institute, 37(4), 5401–09. doi: 10.1016/j.proci.2018.07.091.Google Scholar

Pugh, D., Runyon, J., Bowen, P., Giles, A., Valera-Medina, A., Marsh, R., Goktepe, B. and Hewlett, S. (2020). An investigation of ammonia primary flame combustor concepts for emissions reduction with OH*, NH2* and NH* chemiluminescence at elevated conditions. Proceedings of the Combustion Institute, 38(4), 6451–59. doi: 10.1016/j.proci.2020.06.310.Google Scholar

Pugh, D., Valera-Medina, A., Bowen, P., Giles, A., Goktepe, B., Runyon, J., Morris, S., Hewlett, S. and Marsh, R. (2020). Emissions performance of staged premixed and diffusion combustor concepts for an NH3/AIR flame with and without reactant humidification. Proceedings of the ASME Turbo Expo. doi: 10.1115/GT2020-14953.Google Scholar

Reiter, A. J. and Kong, S. C. (2011). Combustion and emissions characteristics of compression-ignition engine using dual ammonia-diesel fuel. Fuel, 90(1), 87–97. doi: 10.1016/j.fuel.2010.07.055.Google Scholar

Rossetti, I. (2020). Reactor design, modelling and process intensification for ammonia synthesis. in Inamuddin, A. and Rajender, B. (eds.) Green Energy and Technology. Switzerland: Springer Nature, 17–48. doi: 10.1007/978-3-030-35106-9_2.Google Scholar

Seaman, R. W. and Huson, G. (2013). The choice of NH3 to fuel the X-15 Rocket plane. NH3 Association. Available at: https://nh3fuel.files.wordpress.com/2013/01/2011-seaman-huson.pdf (Accessed: May 30, 2021).Google Scholar

Skeffington, R. A. and Wilson, E. J. (1988). Excess nitrogen deposition: Issues for consideration. Environmental Pollution, 54(3–4), 159–84. doi: 10.1016/0269-7491(88)90110-8.Google Scholar

Smill, V. and Streatfeild, R. A. (2002). Enriching the Earth: Fritz Haber, Carl Bosch, and the transformation of world food production. Electronic Green Journal, 7(3), 338. doi: 10.2307/3985938.Google Scholar

Sorrentino, G., Sabia, P., Bozza, P., Ragucci, R. and de Joannon, M. (2019). Low-NOx conversion of pure ammonia in a cyclonic burner under locally diluted and preheated conditions. Applied Energy, 254, 113676. doi: 10.1016/j.apenergy.2019.113676.CrossRef Google Scholar

Tanigawa, H. (2018). Test results of the ammonia mixed combustion at Mizushima Power Station Unit No.2 and related patent applications, NH3 Association. Available at: https://nh3fuelassociation.org/wp-content/uploads/2018/12/1530-Chugoku-Electric-Power-Co.pdf (Accessed: June 24, 2019).Google Scholar

The Royal Society (2020). Ammonia: Zero-carbon fertiliser, fuel and energy store. Available at: royalsociety.org/green-ammonia (Accessed: January 19, 2021).Google Scholar

TogliattiAzot (2016). Production. Available at: www.toaz.ru/eng/about/production.phtml (Accessed: May 30, 2021).Google Scholar

Tripodi, A., Conte, F. and Rossetti, I. (2021). Process intensification for ammonia synthesis in multibed reactors with Fe-wustire and Ru/C catalysts. Industrial & Engineering Chemistry Research, 60(2), 908–15. doi: 10.1021/acs.iecr.0c05350.Google Scholar

UN Industrial Development Organization (1998) Fertilizer Manual. 3rd ed. Kluwer Academic Publishers, Chapter 7, p. 195. Available at: www.springer.com/gp/book/9780792350323 Google Scholar

Valera-Medina, A., Morris, S., Runyon, J., Pugh, D. G., Marsh, R., Beasley, P. and Hughes, T. (2015). Ammonia, methane and hydrogen for gas turbines. Energy Procedia, 75, 118–23. doi: 10.1016/j.egypro.2015.07.205.CrossRef Google Scholar

Valera-Medina, A., Xiao, H., Owen-Jones, M., David, W. I. and Bowen, P. J. (2018). Ammonia for power. Progress in Energy and Combustion Science, 69, 63–102. doi: 10.1016/j.pecs.2018.07.001.Google Scholar

Valera-Medina, A. Gutesa, M., Xiao, H., Pugh, D., Giles, A., Goktepe, B., Marsh, R. and Bowen, P. (2019). Premixed ammonia/hydrogen swirl combustion under rich fuel conditions for gas turbines operation. International Journal of Hydrogen Energy, 44(16), 8615–26. doi: 10.1016/j.ijhydene.2019.02.041.Google Scholar

Valera-Medina, A. (2020). Stored ammonia for power (SAFE). Available at: www.safeammonia.com (Accessed: May 30, 2021).Google Scholar

Valera-Medina, A., Amer-Hatem, F., Azad, A. K., Dedoussi, I. C., De Joannon, M., Fernandes, R. X., Glarborg, P., Hashemi, H., He, X., Mashruk, S., McGowan, J., Mounaim-Rouselle, C., Ortiz-Prado, A., Ortiz-Valera, A., Rossetti, I., Shu, B., Yehia, M., Xiao, H., and Costa, M. (2021). Review on ammonia as a potential fuel: From synthesis to economics. Energy & Fuels, 35(9), 6964–7029. doi: 10.1021/acs.energyfuels.0c03685.Google Scholar

Valera-Medina, A. and Banares-Alcantara, R. (2021). Techno-economic challenges of green ammonia as an energy vector. 1st ed. Academic Press. doi: 10.1016/c2019-0-01417-3.Google Scholar

Valera-Medina, A. and Roldan, A. (2020). Ammonia from steelworks. Green energy and technology. Springer Nature. 69–80. doi: 10.1007/978-3-030-35106-9_4.Google Scholar

WÄRTSILÄ, Encyclopedia of Marine Technology (2016). Gas carrier types. Available at: www.wartsila.com/encyclopedia/term/gas-carrier-types (Accessed: May 4, 2021).Google Scholar

Watts, C. and Awan, S. (2019). Canadian fundamentals of fire fighter skills and hazardous materials response. 4th ed. Jones & Bartlett Learning.Google Scholar

Wijayanta, A. T., Oda, T., Purnomo, C. W., Kashiwagi, T. and Aziz, M. (2019). Liquid hydrogen, methylcyclohexane, and ammonia as potential hydrogen storage: Comparison review. International Journal of Hydrogen Energy, 44(29), 15026–44. doi: 10.1016/j.ijhydene.2019.04.112.CrossRef Google Scholar

Woo, Y., Jang, J. Y., Lee, Y. J. and Kim, J. N. (2014). Recent progress on the ammonia-gasoline and the ammonia-diesel dual fueled ICE in Korea. 11th NH3 Fuel Conference.Google Scholar

Wood, R. D. (1903). Mond gas, Philadelphia Co. Available at: https://archive.org/stream/mondgas00woodrich#page/n5/mode/2up (Accessed: May 30, 2021).Google Scholar

Wood, T. J., Makepeace, J. W., Hunter, H. M., Jones, M. O. and David, W. I. (2015). Isotopic studies of the ammonia decomposition reaction mediated by sodium amide. Physical Chemistry Chemical Physics, 17(35), 22999–3006. doi: 10.1039/c5cp03560k.Google Scholar

World Health Organization (2003). Ammonia in drinking-water. Geneva, Switzerland: World Health Organization. Available at: www.who.int/water_sanitation_health/dwq/ammonia.pdf.Google Scholar

YARA (2018). YARA fertilizer industry handbook. Norway: YARA. Available at: www.yara.com/siteassets/investors/057-reports-and-presentations/other/2018/fertilizer-industry-handbook-2018-with-notes.pdf/.Google Scholar

Zadick, A., Dubau, L., Artyushkova, K., Serov, A., Atanassov, P. and Chatenet, M. (2017). Nickel-based electrocatalysts for ammonia borane oxidation: Enabling materials for carbon-free-fuel direct liquid alkaline fuel cell technology. Nano energy, 37, 248–59. doi: 10.1016/j.nanoen.2017.05.035.Google Scholar

Zhang, L., You, C. O., Weishen, Y. A. and Liwu, L. I. (2007). A direct ammonia tubular solid oxide fuel cell. Chinese Journal of Catalysis, 28(9), 749–51. doi: 10.1016/S1872-2067(07)60062-X.Google Scholar

Zhu, X., Khateeb, A. A., Guiberti, T. F. and Roberts, W. L. (2020). NO and OH* emission characteristics of very-lean to stoichiometric ammonia-hydrogen-air swirl flames. Proceedings of the Combustion Institute, 38(4), 5155–62. doi: 10.1016/j.proci.2020.06.275.Google Scholar

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8 - Ammonia

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