Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs

Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs

Hydrogen can be produced from the decomposition of methane (also called pyrolysis). Many studies assume that this process emits few greenhouse gas (GHG) because the reaction from methane to hydrogen yields only solid carbon and no CO2. This paper assesses the life-cycle GHG emissions and the leveliz...

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Main Authors: Sebastian Timmerberg, Martin Kaltschmitt, Matthias Finkbeiner
Format: Article
Language:English
Published: Elsevier 2020-09-01
Series:Energy Conversion and Management: X
Subjects:
Hydrogen production
Methane decomposition
Pyrolysis
Blue hydrogen
Online Access:http://www.sciencedirect.com/science/article/pii/S2590174520300155
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spelling doaj-d90e295382e641f09f3947ecfcf7de582020-11-25T03:54:34ZengElsevierEnergy Conversion and Management: X2590-17452020-09-017100043Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costsSebastian Timmerberg0Martin Kaltschmitt1Matthias Finkbeiner2Hamburg University of Technology, Germany; Technische Universität Berlin, Germany; Corresponding author at: Eissendorfer Str.40, 21073 Hamburg, Germany.Hamburg University of Technology, GermanyTechnische Universität Berlin, GermanyHydrogen can be produced from the decomposition of methane (also called pyrolysis). Many studies assume that this process emits few greenhouse gas (GHG) because the reaction from methane to hydrogen yields only solid carbon and no CO2. This paper assesses the life-cycle GHG emissions and the levelized costs for hydrogen provision from methane decomposition in three configurations (plasma, molten metal, and thermal gas). The results of these configurations are then compared to electrolysis and steam methane reforming (SMR) with and without CO2 capture and storage (CCS). Under the global natural gas supply chain conditions, hydrogen from methane decomposition still causes significant GHG emissions between 43 and 97 g CO2-eq./MJ. The bandwidth is predominately determined by the energy source providing the process heat, i.e. the lowest emissions are caused by the plasma system using renewable electricity. This configuration shows lower GHG emissions compared to the “classical” SMR (99 g CO2-eq./MJ) but similar emissions to the SMR with CCS (46 g CO2-eq./MJ). However, only electrolysis powered with renewable electricity leads to very low GHG emissions (3 g CO2-eq./MJ). Overall, the natural gas supply is a decisive factor in determining GHG emissions. A natural gas supply with below-global average GHG emissions can lead to lower GHG emissions of all methane decomposition configurations compared to SMR. Methane decomposition systems (1.6 to 2.2 €/kg H2) produce hydrogen at costs substantially higher compared to SMR (1.0 to 1.2 €/kg) but lower than electrolyser (2.5 to 3.0 €/kg). SMR with CCS has the lowest CO2 abatement costs (24 €/t CO2-eq., other > 141 €/t CO2-eq.). Finally, fuels derived from different hydrogen supply options are assessed. Substantially lower GHG emissions, compared to the fossil reference (natural gas and diesel/gasoline), are only possible if hydrogen from electrolysis powered by renewable energy is used (>90% less). The other hydrogen pathways cause only slightly lower or even higher GHG emissions.http://www.sciencedirect.com/science/article/pii/S2590174520300155Hydrogen productionMethane decompositionPyrolysisBlue hydrogen
collection DOAJ
language English
format Article
sources DOAJ
author Sebastian Timmerberg
Martin Kaltschmitt
Matthias Finkbeiner
spellingShingle Sebastian Timmerberg
Martin Kaltschmitt
Matthias Finkbeiner
Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs
Energy Conversion and Management: X
Hydrogen production
Methane decomposition
Pyrolysis
Blue hydrogen
author_facet Sebastian Timmerberg
Martin Kaltschmitt
Matthias Finkbeiner
author_sort Sebastian Timmerberg
title Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs
title_short Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs
title_full Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs
title_fullStr Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs
title_full_unstemmed Hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – GHG emissions and costs
title_sort hydrogen and hydrogen-derived fuels through methane decomposition of natural gas – ghg emissions and costs
publisher Elsevier
series Energy Conversion and Management: X
issn 2590-1745
publishDate 2020-09-01
description Hydrogen can be produced from the decomposition of methane (also called pyrolysis). Many studies assume that this process emits few greenhouse gas (GHG) because the reaction from methane to hydrogen yields only solid carbon and no CO2. This paper assesses the life-cycle GHG emissions and the levelized costs for hydrogen provision from methane decomposition in three configurations (plasma, molten metal, and thermal gas). The results of these configurations are then compared to electrolysis and steam methane reforming (SMR) with and without CO2 capture and storage (CCS). Under the global natural gas supply chain conditions, hydrogen from methane decomposition still causes significant GHG emissions between 43 and 97 g CO2-eq./MJ. The bandwidth is predominately determined by the energy source providing the process heat, i.e. the lowest emissions are caused by the plasma system using renewable electricity. This configuration shows lower GHG emissions compared to the “classical” SMR (99 g CO2-eq./MJ) but similar emissions to the SMR with CCS (46 g CO2-eq./MJ). However, only electrolysis powered with renewable electricity leads to very low GHG emissions (3 g CO2-eq./MJ). Overall, the natural gas supply is a decisive factor in determining GHG emissions. A natural gas supply with below-global average GHG emissions can lead to lower GHG emissions of all methane decomposition configurations compared to SMR. Methane decomposition systems (1.6 to 2.2 €/kg H2) produce hydrogen at costs substantially higher compared to SMR (1.0 to 1.2 €/kg) but lower than electrolyser (2.5 to 3.0 €/kg). SMR with CCS has the lowest CO2 abatement costs (24 €/t CO2-eq., other > 141 €/t CO2-eq.). Finally, fuels derived from different hydrogen supply options are assessed. Substantially lower GHG emissions, compared to the fossil reference (natural gas and diesel/gasoline), are only possible if hydrogen from electrolysis powered by renewable energy is used (>90% less). The other hydrogen pathways cause only slightly lower or even higher GHG emissions.
topic Hydrogen production
Methane decomposition
Pyrolysis
Blue hydrogen
url http://www.sciencedirect.com/science/article/pii/S2590174520300155
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AT martinkaltschmitt hydrogenandhydrogenderivedfuelsthroughmethanedecompositionofnaturalgasghgemissionsandcosts
AT matthiasfinkbeiner hydrogenandhydrogenderivedfuelsthroughmethanedecompositionofnaturalgasghgemissionsandcosts
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