Blue Hydrogen and Ammonia
Article Sidebar
Main Article Content
Abstract
As the world seeks to transition to a low-carbon energy sources to meet the decarbonization goals for 2050, there is an essential need for technologies that can significantly reduce CO2 emissions without compromising the global energy and industrial production demands.
Among the low-carbon energy alternatives being explored, blue hydrogen and ammonia are considered as practical options. These elements offer promising potential as energy carriers and fuels to significantly reduce carbon emissions across different industries. However, like any emerging technology, blue hydrogen and ammonia come with their unique challenges and obstacles that must be addressed for wider implementation.
Before going further into the details of research, it is important to understand the connection between hydrogen and ammonia, and the reason why ammonia is critical in supporting hydrogen as an energy carrier.
This technical paper will explore the different types of hydrogen and ammonia, which are categorized based on their production source and methods. These variations also have significant impact on production costs.
Hydrogen and ammonia are recognized as an element that can generate substantial energy. However, a key question remains: Can they compete with conventional energy sources, such as hydrocarbons? And if they hold such promise, why haven't they fully replaced traditional energy sources yet?
Article Details
This work is licensed under a Creative Commons Attribution 4.0 International License.
References
[1] O'Brien, C. (2024, May 7). Greenhouse gases and climate change (Definition & examples). Palmetto. Retrieved October 27, 2024
[2] Al-Qahtani, Alaa, et al. "The Role of Carbon Intensity Certification in Enabling Blue Hydrogen for a Low-Carbon Future." King Abdullah Petroleum Studies and Research Center, 2021.
[3] Hatzell, Marta C. "The Colors of Ammonia." ACS Energy Letters, vol. 9, no. 8, June 2024, pp. 2920-2921.
[4] AIEN CCUS Taskforce. "Carbon Capture, Use and Storage (CCUS): Opportunities and Implications for the AIEN." Association of International Energy Negotiators, 2024.
[5] Intergovernmental Panel on Climate Change. "Special Report on Carbon Dioxide Capture and Storage." Cambridge University Press, 2005.
[6] Zapantis, Alex. "Blue Hydrogen." Global CCS Institute, 2021.
[7] Climate Technology Coalition and Bloomberg NEF. "Scaling Up Hydrogen: The Case for Low-Carbon Ammonia." Bloomberg NEF, 2022.
[8] Yadav, Omprakash Singh, et al. "Blue Ammonia: A Step Towards Green Energy." World Journal of Advanced Engineering Technology and Sciences, vol. 5, no. 1, 2022, pp. 210-216.
[9] Shabaneh, Rami, et al. "World's First Blue Ammonia Shipment Signals Prospective New Low-Carbon Energy Trade for Saudi Arabia." King Abdullah Petroleum Studies and Research Center (KAPSARC), 2 Nov. 2020, KS-2020-II28.
[10] "2023 Saudi Aramco Sustainability Report." Saudi Aramco, 2024.
[11] "Blue Ammonia Market Size, Share, Industry Analysis - 2030." MarketsandMarkets, Markets and Markets Research Private Ltd., Aug. 2023.
[12] "Emission Factors for Greenhouse Gas Inventories." United States Environmental Protection Agency, 5 June 2024.
[13] "Interactive: Ammonia Price Chart | S&P Global Commodity Insights." S&P Global Commodity Insights, 10 May 2023