[1] "Global Energy & CO2 Status Report 2019," 2019. [Online]. Available: https://www.iea.org/reports/global-energy-co2-status-report-2019. [Accessed 2023 10 28].
[2] C. Wiesen, "Special Report on Global Warming of 1.5°C," The Intergovernmental Panel on Climate Change. IPCC, The United Nations, 2017.
[3] Lund H., Mathiesen B.V., "Energy system analysis of 100% renewable energy systems—The case of Denmark in years 2030 and 2050," Energy, vol. 34, no. 5, pp. 524-531, 2009.
[4] Yilmaz F., Ozturk M., Selbas R., "Development and performance examination of an integrated plant with desalination process for multigeneration purposes," Energy Conversion and Management, vol. 240, p. 114275, 2021.
[5] Tabrizi Z.H., Mohammadourfard M., Akkurt G.G., Heris S.Z., "Energy, exergy, exergoeconomic, and exergoenvironmental (4E) analysis of a new bio-waste driven multigeneration system for power, heating, hydrogen, and freshwater production: Modeling and a case study in Izmir," Energy Conversion and Management, vol. 288, p. 117130, 2023.
[6] Ghasemiasl R., Abhari M.K., Javadi M.M., Gomashi H., "4E investigating of a combined power plant and converting it to a multigeneration system to reduce environmental pollutant production and sustainable development," Energy Conversion and Management, vol. 245, p. 114468, 2021.
[7] D’Amore F., Nava F., Colbertaldo P., Visconti C.G., Romano M.C., "Turning CO2 from fuel combustion into e-Fuel? Consider alternative pathways," Energy Conversion and Management, vol. 289, p. 117170, 2023.
[8] Valera-Medina A., Morris S., Runyon J., Pugh D.G., Marsh R., Beasley P., Hughes T., "Ammonia, Methane and Hydrogen for Gas Turbines," Energy Procedia, vol. 75, pp. 118-123, 2015.
[9] Ávila C.D., Cardona S., Abdullah M., Younes M., Jamal A., Guiberti T.F., Roberts W.L., "Experimental assessment of the performance of a commercial micro gas turbine fueled by ammonia-methane blends," Applications in Energy and Combustion Science, vol. 13, p. 100104, 2023.
[10] Xiao, H., Wang, Z., Valera-Medina, A. et al., "Study on Characteristics of Co-firing Ammonia/Methane Fuels under Oxygen Enriched Combustion Conditions," J. Therm. Sci., vol. 27, p. 270–276, 2018.
[11] Valera-Medina A., Marsh R., Runyon J., Pugh D., Beasley P., Hughes T. , BowenT., "Ammonia–methane combustion in tangential swirl burners for gas turbine power generation," Applied Energy, vol. 185, pp. 1362-1371, 2017.
[12] Keller M., Koshi M., Otomo J., Iwasaki H., Mitsumori T., Yamada K., "Thermodynamic evaluation of an ammonia-fueled combined-cycle gas turbine process operated under fuel-rich conditions," Energy, vol. 194, p. 116894, 2020.
[13] Pirmohamadi A., Ziapour B.M. , "Proposal of a novel ammonia brayton cycle integrated with a methane/hydrogen brayton cycle; Thermodynamic and environmental impacts assessments," Energy Equipment and Systems, vol. 11, no. 1, pp. 95-122, 2023.
[14] Okafor E.C., Yamashita H., Hayakawa A., et al., "Flame stability and emissions characteristics of liquid ammonia spray co-fired with methane in a single stage swirl combustor," Fuel, vol. 287, p. 119433, 2021.
[15] Guteša Božo M. , Vigueras-Zuniga M.O., Buffi M., Seljak T., Valera-Medina A., "Fuel rich ammonia-hydrogen injection for humidified gas turbines," Applied Energy, vol. 251, p. 113334, 2019.
[16] Guteša Božo M. , Mashruk S., Zitouni S., Valera-Medina A., "Humidified ammonia/hydrogen RQL combustion in a trigeneration gas turbine cycle," Energy Conversion and Management, vol. 227, p. 113625, 2021.
[17] Da Rocha R.C., Costa M., Bai X.S.,, "Chemical kinetic modelling of ammonia/hydrogen/air ignition, premixed flame propagation and NO emission," Fuel, vol. 246, pp. 24-33, 2019.
[18] Honzawa T., Kai R., Okada A., Valera-Medina A., Bowen P.J., KuroseR., "Predictions of NO and CO emissions in ammonia/methane/air combustion by LES using a non-adiabatic flamelet generated manifold," Energy, vol. 186, p. 115771, 2019,.
[19] Valera-Medina A., Gutesa M., Xiao H., Pugh D., Giles A., Goktepe B., Marsh R., Bowen P., "Premixed ammonia/hydrogen swirl combustion under rich fuel conditions for gas turbines operation," International Journal of Hydrogen Energy, vol. 44, no. 16, pp. 8615-8626, 2019.
[20] Xiao H.,Valera-Medina A., "Chemical Kinetic Mechanism Study on Premixed Combustion of Ammonia/Hydrogen Fuels for Gas Turbine Use," ASME. J. Eng. Gas Turbines Power, vol. 139, no. 8, p. 081504, 2017.
[21] Su B., Huang Y., Wang Y., Huang Z., Yuan S., Huang Q., Xu Z., Lin F., "Novel ammonia-driven chemically recuperated gas turbine cycle based on dual fuel mode," Applied Energy, vol. 343, p. 121184, 2023.
[22] Wang Y., Liu J., Wang L., Fu Z., Weng P., "Non-premixed combustion and NOX emission characteristics in a micro gas turbine swirl combustor fueled by methane and ammonia at various heat loads," Heliyon, vol. 9, no. 3, p. e14521, 2023.
[23] Yilmaz F., Ozturk M., Selbas R., "Thermodynamic performance analysis and environmental impact assessment of an integrated system for hydrogen and ammonia generation," International Journal of Hydrogen Energy, vol. 46, no. 57, 2021.
[24] Yilmaz F., Ozturk M., Selbas R., "Development and performance examination of an integrated plant with desalination process for multigeneration purposes," Energy Conversion and Management, vol. 240, p. 114275, 2021.
[25] He W., Namar M.M., Li Z., Maleki A., Tlili I., Safdari Shadloo M., "Thermodynamic analysis of a solar-driven high-temperature," Appl Therm Eng, vol. 172, 2020.
[26] AlZahrani A.A., Dincer I., "Exergoeconomic analysis of hydrogen production using a standalone high-temperature electrolyzer," Int J Hydrogen Energy, vol. 46 , no. 27, pp. 13899-13907, 2021.
[27] Anvari S., Mahian O., Taghavifar H., Wongwises S., Desideri U., "4E analysis of a modified multigeneration system designed for power, heating/cooling, and water desalination," Applied Energy, vol. 270, p. 115107, 2020.
[28] Eldeib A., Luqman M., Bicer Y., Al-Ansari T.A.,, "Thermodynamic design and analysis of a multigeneration system to support sustainable dairy farming," Energy Conversion and Management, vol. 18, p. 100363, 2023.
[29] Liu Q., Arabkoohsar A., Liu Y., He Z., "Techno-economic analysis of a liquid air energy storage system combined with calcium carbide production and waste heat recovery," Journal of Energy Storage, vol. 60, p. 106689, 2023.
[30] Pulla B.P., Nutakki T.U.K., Albani A., Agrawal M.K., Begum M.Y., Han W., "Comprehensive technical study of a novel polygeneration arrangement using natural gas power plant and geothermal energy for producing electricity, heat, fresh water, and methanol," Process Safety and Environmental Protection, vol. 180, pp. 98-121, 2023.
[31] Ding G.C.,JI P., GENG M.Y.,, "Technical assessment of Multi-generation energy system driven by integrated renewable energy Sources: Energetic, exergetic and optimization approaches," Fuel, vol. 331, p. 125689, 2023.
[32] Bicer Y., Dincer I., "Development of a new solar and geothermal based combined system for hydrogen production," Sol Energy ;127:, vol. 127, pp. 269-284, 2016.
[33] Acar C., Dincer I., "Investigation of a new integrated system for multiple outputs with hydrogen and methanol," International Journal of Hydrogen Energy, vol. 46, no. 6, pp. 4699-4715, 2021.
[34] Siddiqui O., Ishaq H., Dincer I., "A novel solar and geothermal based trigeneration system for electricity generation,hydrogen production and cooling," Energy Convers Manag, vol. 198, p. 111812, 2019.
[35] Akrami E, Chitsaz A, Nami H, Mahmoudi SMS., "Energetic and exergoeconomic assessment of a multi-generation energy system based on indirect use of geothermal energy," Energy, vol. 124, pp. 625-639, 2017.
[36] Bet Sarkis R., Zare V., "Proposal and analysis of two novel integrated configurations for hybrid solar-biomass power generation systems: thermodynamic and economic evaluation," Energy Convers Manag, vol. 160, pp. 411-425, 2018.
[37] Ghaebi H., Namin A.S., Rostamzadeh H., "Exergoeconomic optimization of a novel cascade Kalina/Kalina cycle using geothermal heat source and LNG cold energy recovery," Journal of Cleaner Production, vol. 189, pp. 279-296, 2018.
[38] Tao J., Dong W., Qiu B., Xu C., Liu Y., Chu H., "Effect of Ammonia on Laminar Combustion Characteristics of Methane−Air Flames at Elevated Pressures," ASC OMEGA, vol. 7, p. 15326−15337, 2022.
[39] Pirmohamadi A., Ghaebi H., Ziapour B.M. , Ebadollahi M., "Exergoeconomic Analysis of a Novel Hybrid System by Integrating the Kalina and Heat Pump Cycles with a Nitrogen Closed Brayton System," Energy Reports, vol. 7, pp. 546-564, 2021.
[40] Kobayashi H., Hayakawa A., Kunkuma K.D., Somarathne A., Okafor E.C., "Science and technology of ammonia combustion," Proceedings of the Combustion Institute, vol. 37, p. 109–133, 2019.
