Expectations for the Role of Hydrogen and Its Derivatives in Different Sectors through Analysis of the Four Energy Scenarios: IEA-STEPS, IEA-NZE, IRENA-PES, and IRENA-1.5°C

Abstract: Recently, worldwide, the attention being paid to hydrogen and its derivatives as alternative carbon-free (or low-carbon) options for the electricity sector, the transport sector, and the industry sector has increased. Several projects in the field of low-emission hydrogen production (particularly electrolysis-based green hydrogen) have either been constructed or analyzed for their feasibility. Despite the great ambitions announced by some nations with respect to becoming hubs for hydrogen production and export… Show more

“…In order to achieve global carbon neutrality (net-zero emissions of carbon dioxide) by 2050, and thus limit the rise in the global mean surface temperature (compared to the pre-industrial level) to 1.5 °C by 2100, total electricity generation in 2050 should grow to about three times its level in 2020, with the electrification percentage in the total final energy consumption (TFEC) reaching about 50 % in 2050 (compared to 22 % in 2020), and the share of renewable energy sources should dominate total electricity generation in 2050, with a share of about 90 % in 2050 (compared to 28 % in 2020) [ [8] , [9] , [10] , [11] , [12] , [13] ]. While the increasing demand for electricity can be fulfilled by conventional fossil-fuel power plants, nuclear power plants, and mature renewable energy power plants (such as solar photovoltaic panels and wind turbines) [ [14] , [15] , [16] , [17] , [18] , [19] , [20] , [21] , [22] , [23] , [24] ], the current study is concerned with a special electricity generation method, which is magnetohydrodynamic (MHD) channels (or plasma generators).…”

“…+ 34.755413381759915 ln (u) 3 + 48.31120748606025 ln (u) 4 + 34.44165112788354 ln (u) 5 + 13.332151177313404 ln (u) 6 + 2.662961571532757 ln (u) 7 + 0.2148246953236797 ln (u)8 …”

Estimated electric conductivities of thermal plasma for air-fuel combustion and oxy-fuel combustion with potassium or cesium seeding

“…In order to achieve global carbon neutrality (net-zero emissions of carbon dioxide) by 2050, and thus limit the rise in the global mean surface temperature (compared to the pre-industrial level) to 1.5 °C by 2100, total electricity generation in 2050 should grow to about three times its level in 2020, with the electrification percentage in the total final energy consumption (TFEC) reaching about 50 % in 2050 (compared to 22 % in 2020), and the share of renewable energy sources should dominate total electricity generation in 2050, with a share of about 90 % in 2050 (compared to 28 % in 2020) [ [8] , [9] , [10] , [11] , [12] , [13] ]. While the increasing demand for electricity can be fulfilled by conventional fossil-fuel power plants, nuclear power plants, and mature renewable energy power plants (such as solar photovoltaic panels and wind turbines) [ [14] , [15] , [16] , [17] , [18] , [19] , [20] , [21] , [22] , [23] , [24] ], the current study is concerned with a special electricity generation method, which is magnetohydrodynamic (MHD) channels (or plasma generators).…”

“…+ 34.755413381759915 ln (u) 3 + 48.31120748606025 ln (u) 4 + 34.44165112788354 ln (u) 5 + 13.332151177313404 ln (u) 6 + 2.662961571532757 ln (u) 7 + 0.2148246953236797 ln (u)8 …”

Estimated electric conductivities of thermal plasma for air-fuel combustion and oxy-fuel combustion with potassium or cesium seeding

Recent advancement in energy storage technologies and their applications

Life cycle cost assessment of geothermal energy assisted hydrogen liquefaction for sustainable and renewable energy applications: Case study and adaptation for Afyon geothermal power plant