The world is undergoing a transition to a low-carbon economy to reduce greenhouse gas (GHG) emissions and dependence on fossil fuels. This is highlighted by the International Energy Agency’s (IEA) global hydrogen review 2023 that showed global hydrogen demand reached 95 tonne in 2022, its highest in recent history. One key aspect of this transition is the electrification of end uses, coupled with a shift toward low-carbon electricity sources such as nuclear, wind, solar, and hydropower. However, some sectors, such as aviation, heavy-duty transport, and the chemical industry, are challenging to electrify and have demands for energy-dense fuels. Clean hydrogen (including all clean hydrogen generation) and clean synthetic chemicals and fuels such as ammonia, methanol, and Fischer–Tropsch (FT) fuels produced from nuclear and renewable electricity are promising carbon-neutral drop-in alternatives that can meet the needs for fuel reliability and processing chemistry for those end-use sectors.

Renewable power-based electrolysis to produce clean hydrogen is usually considered to have zero emissions because of the zero-emission burden at the place of electricity production. However, this assumption may not be true when embodied emissions associated with renewable power plant materials, manufacturing, and installation. Embodied emissions of renewable power plants refer to the emissions associated with the entire life cycle of material extraction, processing, manufacturing, installation, and end-of-life treatment of power facilities. Although nearly emission-free electricity generation of solar photovoltaic (PV) systems over their 25–30 year lifespan, their manufacturing and installation necessitate energy and material inputs and result in emissions being produced. (1,2)

Several studies have examined the global warming potential of clean hydrogen production. Spath and Mann (3) found that hydrogen produced from wind electricity would have emissions of 0.97 kg CO2 e/kg H2 including embodied emissions. A subsequent review by Bhandari et al. (4) confirmed that hydrogen produced by wind electricity has the lowest emissions among hydrogen produced from different renewable and nuclear electrolysis. Cetinkaya et al. detailed the embodied emissions for five different H2 production methods, including three from renewable energies (solar PV, wind, and thermochemical water splitting using nuclear). (5) They found that GHG emissions from solar and wind electrolysis were 0.97 and 2.4 kg of CO2 e/kgH2, respectively. (5) This is backed up by Palmer et al. (6) as they reported that hydrogen from solar PV would have emissions of 2.3 kg CO2 e/kgH2. Motazedi et al. calculated emissions of hydrogen produced by high-temperature electrolysis to be 0.3 kg CO2 e/kg H2. (7)...

Figure 1. Emissions of nuclear and renewable electricity. Process emissions include emissions from fuel combustion for power generation and upstream emissions of fuel production and transportation. Plant-embodied emissions are emissions from power plant construction and upstream emissions of material extraction and manufacturing.

Figure 2. Cradle-to-gate GHG emissions of hydrogen production.

Figure 3. Cradle-to-gate GHG emissions of synthetic ammonia using hydrogen from PEM and SOEC electrolysis.

Figure 4. Emission estimates of clean hydrogen and e-FT fuel in the 2030 future scenario, assuming reduced electricity related emissions and improved electrolysis efficiency.

...According to our estimates, on-shore wind power has an average embodied emission of 9.8 g of CO2/kWh, while electricity generated from off-shore fixed-bottom wind turbines has an average embodied emission of 12.5 g of CO2/kWh. Although offshore wind turbines have a higher average capacity factor, the manufacturing and installation of offshore wind turbines usually require more materials/energy inputs, resulting in higher embodied emissions compared to onshore wind power. Currently, onshore wind power capacity accounts for the vast majority (over 99%) of total wind power capacity in the U.S...

...The embodied GHG emissions of hydroelectricity are estimated to be 7.2 g/kWh, slightly lower than that of wind power. This estimate does not account for the potential biogenic GHG emissions associated with hydroelectric reservoirs. These reservoirs can give rise to emissions of biogenic carbon dioxide and methane. (29) Such GHG emissions occur due to the decomposition of flooded vegetation and soil organic matter during the construction and operation of dams. The rate of carbon dioxide and methane flux per unit area of a reservoir varies significantly based on factors such as organic carbon content, reservoir age, and water temperature. (30)...

...Nuclear power plants with different reactor technologies have different embodied emissions, varying from the lowest of 0.16 g/kWh for the AHTR plant to the highest of 0.4 g/kW for the ABWR plant. The embodied emissions of the current U.S. fleet average nuclear power plants (consisting of ∼65% power capacity from PWR and ∼35% from BWR) are 0.3 g/kWh. The high capacity factor of an average of ∼90% for the U.S. operating fleet contributes to the lower embodied emission intensity of nuclear electricity. Moreover, different from the solar and wind power plant, there is no age-related decline in capacity factor seen in the nuclear reactor performance, with average capacity factors and rated power increasing with age for reactors between 40 and 50 years old. (28) Thus, nuclear power plants have much higher lifespans than their renewable counterparts, many nuclear power plants in the U.S. have received license extensions from the initial 40 to 60 years, (28) and it is possible they will last from 80 to 100 years. The longer lifespan also leads to a lower embodied emission intensity of nuclear power plants...