Future environmental impacts of global hydrogen production
article
Low-carbon hydrogen (H2) will likely be essential in achieving climate-neutrality targets by 2050. This paper assesses the future life-cycle environmental impacts of global H2 production considering technical developments, regional feedstock supply, and electricity decarbonization. The analysis includes coal gasification, natural gas steam methane reforming, biomass gasification, and water electrolysis across 15 world regions until 2050. Three scenarios of the International Energy Agency are considered: (1) the Stated Policies Scenario (STEPS), (2) the Announced Pledges Scenario (APS) that entails aspirational goals in addition to stated policies, and (3) the Net Zero Emissions by 2050 Scenario (NZE). Results show the global average greenhouse gas (GHG) emissions per kg of H2 decrease from 14 kg CO2-eq. today to 9-14 kg CO2-eq. in 2030 and 2-12 kg CO2-eq. in 2050 (in NZE/STEPS). Fossil fuel-based technologies have a limited potential for emissions reduction without carbon capture and storage. At the same time, water electrolysis will become less carbon-intensive along with the low-carbon energy transition and can become nearly carbon-neutral by 2050. Although global H2 production volumes are expected to grow four to eight times by 2050, GHG emissions could already peak between 2025 and 2035. However, cumulative GHG emissions between 2020 and 2050 could reach 39 (APS) to 47 (NZE) Gt CO2-eq. The latter corresponds to almost 12% of the remaining carbon budget to meet the 1.5 °C target. This calls for a deeper and faster decarbonization of H2 production. This could be achieved by a more rapid increase in H2 produced via electrolysis and the additional expansion of renewable electricity. Investments in natural gas steam methane reforming with carbon capture and storage, as projected by the IEA, seem risky as this could become the major source of GHG emissions in the future, unless very high capture rates for CCS are assumed, and create a fossil fuel and carbon lock-in. Overall, to minimize climate and other environmental impacts of H2 production, a rapid and significant transition from fossil fuels to electrolysis and renewables accompanied by technological and material innovation is needed. (C) 2024 The Royal Society of Chemistry.
Topics
Budget controlCarbon captureDecarbonizationElectrolysisEmission controlFossil fuelsGas emissionsGreenhouse gasesHydrogen productionHydrogen storageInvestmentsLife cycleMethaneNatural gasSteam reformingBiomass GasificationDecarbonisationFeedstock supplyGreenhouse gas emissionsH 2 productionLife-cycle environmental impactLow carbonPolicy scenarioTechnical developmentWater electrolysisCarbon dioxide
TNO Identifier
994765
ISSN
17545692
Source
Energy and Environmental Science
Publisher
Royal Society of Chemistry
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