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Blue hydrogen can be low-carbon, a techno-economic-environmental analysis

Mehrshad Kolahchian Tabrizi, Caecilia R. Vitasari, Davide Bonalumi, Stefano Campanari

2025Energy Conversion and Management6 citationsDOIOpen Access PDF

Abstract

• Partial condensation and desublimation CO 2 separation techniques are studied. • Autothermal reforming with low-temperature CO 2 separation shows promising results. • The Levelized Cost of blue hydrogen ranges from 2.4 to 4 €/kg H 2 . • The average carbon footprint is 2.5 kg CO 2 eq/kg H 2 for photovoltaic-powered cases. • Blue H 2 from a low-emission natural gas supply chain is competitive with green H 2 . Hydrogen produced through natural gas reforming with carbon capture and storage (blue H 2 ) is expected to supply up to 30 % of global low-carbon hydrogen by 2030. However, wide variability in reported findings creates uncertainty about its future role. To address this, the present techno-economic-environmental study from a life-cycle perspective evaluates whether blue hydrogen can meet carbon footprint thresholds (3 and 3.4 kg CO 2 eq./kg H 2 ) required to qualify as low-carbon hydrogen. Several configurations of either chemical absorption or low-temperature CO 2 separation techniques integrated with auto-thermal reforming are modeled. Results show that low-temperature separation can achieve comparable or even superior energetic performance to conventional capture methods, with cold gas and overall efficiencies reaching up to 80 % and 78 %, respectively. The economic analysis estimates the levelized cost of blue hydrogen at 3.5–4 €/kg under 2024 EU average non-household consumer natural gas and electricity prices, and 2.4–2.8 €/kg under Italy’s 2024 wholesale prices. From an environmental standpoint, life-cycle assessment indicates an average carbon footprint of 2.5 kg CO 2 eq./kg H 2 , assuming photovoltaic electricity for auxiliary power and excluding more carbon-intensive natural gas supply chains. The findings highlight that partial electrification of the CO 2 separation unit, use of renewable electricity, and maximizing capture rates are key factors essential for producing compliant blue H 2 . Furthermore, adopting ultra-low-emission natural gas supply chains could reduce blue H 2 ′s carbon footprint to the level of green H 2 , suggesting that the introduction of certificate-of-origin schemes for natural gas can guarantee blue H 2 with minimal emissions.

Topics & Concepts

Natural gasHydrogenHydrogen productionCost of electricity by sourceCarbon footprintMethaneCarbon capture and storage (timeline)Environmental scienceCarbon fibersElectricitySteam reformingHydrogen storageGreenhouse gasMaterials scienceChemistryHydrogen economyCondensationAbsorption (acoustics)Process engineeringCarbon dioxideAnalytical Chemistry (journal)Environmental engineeringCoalWaste managementElectricity generationSubstitute natural gasPhotovoltaic systemWater-gas shift reactionHybrid Renewable Energy SystemsCarbon Dioxide Capture TechnologiesSpacecraft and Cryogenic Technologies
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