The role of hydrogen in low carbon energy futures–A review of existing perspectives

Renewable and Sustainable Energy Reviews

Volumn 82, Issue , 2018, Pages 3027-3045

  Hanley, Emma S ^a   Deane, J P ^a   Gallachoir B P O ^a  

^a UNIVERSITY COLLEGE CORK   (Ireland)

Author keywords

Hydrogen pathways; Integrated energy system models

Indexed keywords

ENERGY FUTURE; ENERGY SYSTEMS; ENERGY-SYSTEM MODELS; HYDROGEN PATHWAY; INTEGRATED ENERGY SYSTEM MODEL; INTEGRATED ENERGY SYSTEMS; LOW CARBON; LOW CARBON ENERGIES; LOW-CARBON TECHNOLOGIES; POLICY SCENARIO;

CARBON;

EID: 85032935424     PISSN: 13640321     EISSN: 18790690     Source Type: Journal    
DOI: 10.1016/j.rser.2017.10.034     Document Type: Review

References (76)

1. United Nations. Report of the Conference of the Parties on its twenty-first session, 〈http://unfccc.int/resource/docs/2015/cop21/eng/10.pdf〉 2015 [accessed 27 September 2016].
2. Sencar, M., Pozeb, V., Krope, T., Development of EU (European Union) energy market agenda and security of supply. Energy 77:1 (2014), 117–124.
3. Jonsson, D.K., Johansson, B., Månsson, A., Nilsson, L.J., Nilsson, M., Sonnsjö, H., Energy security matters in the EU Energy Roadmap. Energy Strategy Rev 6 (2015), 48–56.
4. deLlano-Paz, F., Fernandez, P.M., Soares, I., Addressing 2030 EU policy framework for energy and climate: cost, risk and energy security issues. Energy, 2016.
5. Internatinal Energy Agency, World Energy Outlook - Exec Summ, 2015 〈https://www.iea.org/Textbase/npsum/WEO2015SUM.pdf〉 [accessed 27 September 2016].
6. International Energy Agency, World Energy Outlook 2013, 2013 〈http://www.worldenergyoutlook.org/weo2013/〉 [accessed 27 September 2016].
7. Syri, S., Lehtila, A., Ekholm, T., Savolainen, I., Holttinen, H., Peltola, E., Global energy and emissions scenarios for effective climate change mitigation—deterministic and stochastic scenarios with the TIAM model. Int J Greenh Gas Control 2:2 (2008), 275–285.
8. Page, S., Krumdieck, S., System-level energy efficiency is the greatest barrier to development of the hydrogen economy. Energy Policy 37:9 (2009), 3325–3335.
9. Sgobbi, A., Nijs, W., De Miglio, R., Chiodi, A., Gargiulo, M., Thiel, C., How far away is hydrogen? Its role in the medium and long-term decarbonisation of the European energy system. Int J Hydrog Energy 41:1 (2016), 19–35.
10. Corbo, P., Migliardini, F., Veneri, O., Hydrogen as Future Energy Carrier. Hydrogen Fuel Cells for Road Vehicles, 2011, Springer Science & Business Media, 33–70 [ISBN 978-0-85729-135-6].
11. Lipman T. 2011. An overview of hydrogen production and storage systems with renewable hydrogen case studies, http://cesa.org/assets/2011-Files/Hydrogen-and-Fuel-Cells/CESA-Lipman-H2-prod-storage-050311.pdf [accessed 27.09.2016].
12. Sharma, S., Ghosal, S.K., Hydrogen the future transportation fuel: from production to applications. Renew Sustain Energy Rev 43 (2015), 1151–1158.
13. Midilli, A., Dincer, I., Key strategies of hydrogen energy systems for sustainability. Int J Hydrog Energy 32:5 (2007), 511–524.
14. World nuclear organisation. 2014. Transport and the hydrogen economy, http://www.world-nuclear.org/info/Non-Power-NuclearApplications/Transport/Transport-and-the-HydrogenEconomy/ [accessed 27 September 2016].
15. Hetland, J., Mulder, G., In search of a sustainable hydrogen economy: how a large scale transition to hydrogen may affect the primary energy demand and greenhouse gas emissions. Int J Hydrog Energy 32:6 (2007), 736–747.
16. Maag, G., Zanganeh, Steinfeld, A., Solar thermal cracking of methane in a particle-flow reactor for the co-production of hydrogen and carbon. Int J Hydrog Energy 34:18 (2009), 7676–7685.
17. Panagiotis, L., Review of recent trends in photoelectrocatalytic conversion of solar energy to electricity and hydrogen. Appl. Catal B: Environ 210 (2017), 235–254.
18. HyperSolar. 〈http://www.hypersolar.com/〉 [accessed 21 June 2017].
19. National Renewable Energy Laboratory. 〈http://www.nrel.gov/news/press/2017/41792〉 [accessed 21 June 2017].
20. Niaz, S., Manzoor, T., Pandith, A.H., Hydrogen storage: materials, methods and perspectives. Renew Sustain Energy Rev 50 (2015), 458–469.
21. Bakenne, A., Nutall, W., Kazantzis, N., Sankey-Diagram-based insights into the hydrogen economy of today. Int J Hydrog Energy, 2016.
22. Ball, M., Weeda, M., The hydrogen economy–Vision or reality?. J Hydrog Energy 40:25 (2015), 7903–7919.
23. Andrews, John, Shabani, B., Re-envisioning the role of hydrogen in a sustainable energy economy. Int J Hydrog Energy 37:2 (2012), 1184–1203.
24. Ahmed, A., Al-amin, A.Q., Ambrose, A.F., Saidur, R., Hydrogen fuel and transport system: a sustainable and environmental future. Int J Hydrog Energy 41:3 (2016), 1369–1380.
25. Hajimiragha, A.H., Claudio, C.A., Fowler, M.W., Moazeni, S., Elkamel, A., Wong, S., Sustainable convergence of electricity and transport sectors in the context of a hydrogen economy. Int J Hydrog Energy 36:11 (2011), 6357–6375.
26. Ball, M., Weeda, M., The hydrogen economy–Vision or reality?. Int J Hydrog Energy 40:25 (2015), 7903–7919.
27. Jebaraj, S., Iniyan, S., A review of energy models. Renew Sustain Energy Rev 10:4 (2006), 281–311.
28. Dodds PE, McDowall W, A review of hydrogen delivery technologies for energy system models, https://www.bartlett.ucl.ac.uk/energy/research/themes/energy-systems/hydrogen/WP7_Dodds_Delivery.pdf [accessed 27 September 2016].
29. Dodds PE, McDowall W, A review of hydrogen production technologies for energy system models, https://www.bartlett.ucl.ac.uk/energy/research/themes/energy-systems/hydrogen/WP6_Dodds_Production.pdf [accessed 27 September 2016].
30. Giannakidis, G., Labriet, M., O' Gallachoir, B., Tosato, G., Informing Energy and Climate Policies Using Energy and Systems Models. Lecture note in Energy, 2015, Springer.
31. Environmental and Energy Study Institute, Behind the 2 Degree Scenaerio Presented at COP21, 2015 〈http://www.eesi.org/articles/view/behind-the-2-degree-scenario-presented-at-cop21〉 [accessed 20 June 2017].
32. International Energy Agency, Energy Technol Perspect 2012 - Pathw a Clean Energy Syst, 2012 〈https://www.iea.org/publications/freepublications/publication/ETP2012_free.pdf〉 [accessed 27 September 2016].
33. Kamel, B., Dolf, G., Energy technology modelling of major carbon abatement options. Energy Procedia 1:1 (2009), 4297–4306.
34. Føyn, T.H.Y., Karlsson, K., Balyk, O., Grohnheit, P.E., A global renewable energy system: a modelling exercise in ETSAP/TIAM. Appl Energy 88:2 (2011), 526–534.
35. Loulou, R., Labriet, M., ETSAP-TIAM: the TIMES integrated assessment model Part I: model structure. Comput Manag Sci 5:1 (2008), 7–40.
36. Remme, U., Blesl, M., A global perspective to achieve a low-carbon society (LCS): scenario analysis with the ETSAPTIAM model. Clim Policy, 2008, S60–S75.
37. Loulou R, Remm U, Kanudia A, Lehtila A, Goldstein G. Documentation for the TIMES Model Part 1, http://iea-etsap.org/docs/TIMESDoc-Intro.pdf [accessed 27 Sepetember 2016].
38. Riah, K., Dentener, F., Gielen, D., Grubler, A., Jewell, J., Klimont, Z., Krey, V., McCollum, D., Pachauri, S., Rao, S., van Ruijven, B., van Vuuren, D.P., Wilson, C., [accessed 27 September 2016] Energy Pathw Sustain Dev, 2016 〈http://www.iiasa.ac.at/web/home/research/Flagship-Projects/Global-Energy-Assessment/GEA_Chapter17_pathways_lowres.pdf〉.
39. World Energy Council - Paul Scherrer Institute, World Energy Scenar Compos Energy Futures 2050, 2013 〈https://www.worldenergy.org/publications/2013/world-energy-scenarios-composing-energy-futures-to-2050/〉 [accessed 27 September 2016].
40. Lehtilä A, VTT Energy Systems. Analysing the global energy system by using the EFDA Global TIMES model (EFDA Project TW5-TRE-FESO/A) 〈https://www.euro-fusion.org/wpcms/wp-content/uploads/2014/12/TW5-TRE-FESO-A-VTT-Global-TIMES-Final.pdf〉 [accessed 21 June 2017].
41. AR5 scenario Database. 〈https://tntcat.iiasa.ac.at/AR5DB/dsd?Action=htmlpage&page=welcome〉 [accessed 27 September 2016].
42. Simoes, S., Nijs, W., Ruiz, P., Sgobbi, A., Radu, D., Bolat, P., Thiel, C., Peteves, S., JRC-EU Model, 2016 [accessed 27 September 2016] 〈http://publications.jrc.ec.europa.eu/repository/bitstream/JRC85804/jrc_times_%20eu_overview_online.pdf〉.
43. E3M Lab. The PRIMES Model, 〈http://www.e3mlab.ntua.gr/e3mlab/index.php?Option=com_content&view=category&id=35&Itemid=80&lang=en〉 [accessed 27 September 2016].
44. European Commission. Communication from the Comission to the European Parliament, the council, the European Economic and Social comittee and the comittee of the regions, http://ec.europa.eu/europe2020/pdf/europe2020stocktaking_en.pdf [accessed 27 September 2016].
45. European Commission, Energy Roadmap 2050, 〈https://ec.europa.eu/energy/sites/ener/files/documents/2012_energy_roadmap_2050_en_0.pdf〉 [accessed 27 September 2016].
46. Pye S, Anandarajah G, Fais B, McGlade C, Strachan N. 2015. Pathways to deep decarbonisation in the United Kingdom, http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_GBR.pdf [accessed 27 September 2016].
47. Daly, H.E., Fais, B., UK TIMES Model overview, 2014 〈http://www.ucl.ac.uk/energy-models/models/uktm-ucl/uktm-documentation-overview〉 [accessed 20 June 2017].
48. Devogelaer D, Duerinck J, Gusbin D, Marenne Y, Nijs W, Orsini M, Pairon M. Towards 100% renewable energy in Belgium by 2050, http://www.icedd.be/I7/mediatheque/energie/renouvelable/130419_Backcasting_FinalReport.pdf [accessed 27 September 2016].
49. Deane, P., Curtis, J., Chiodi, A., Gargiulo, M., Rogan, F., Dineen, D., Glynn, J., FitzGerald, J., Ó Gallachóir, B., Tech Support Dev Low Carbon Sect Roadmaps Irel, 2013 〈https://www.esri.ie/pubs/BKMNEXT292.pdf〉 [accessed 27 September 2016].
50. Kannan, R., Turton, H., Switzerland Energy Transition Scenarios – Development and Application of the Swiss TIMES Energy System Model (STEM), 2014 〈https://www.researchgate.net/profile/Ramachandran_Kannan/publication/272112791_Switzerland_Energy_Transition_Scenarios__Development_and_Application_of_the_Swiss_TIMES_Energy_System_Model_(STEM)/links/54db3e6b0cf2ba88a68f86ba.pdf〉 [accessed 27 September 2016].
51. Altieri, K., Trollip, H., Caetano, T., Hughes, A., Merven, B., Winkler, H., Pathways to deep decarbonization in South Africa. 2015, 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_ZAF.pdf〉 [accessed 27 September 2016].
52. Loulou, Richard, Ken Noble, Goldstein G., Documentation for the MARKAL Family of Models, 2004 〈http://unfccc.int/resource/cd_roms/na1/mitigation/Module_5/Module_5_1/b_tools/MARKAL/MARKAL_Manual.pdf〉 [accessed 27 September 2016].
53. VTT, Low Carbon Finland 2050, 〈http://www.vtt.fi/Documents/2012_V2.pdf〉 [accessed 27 September 2016].
54. Virdis MR et al. Pathways to deep decarboniation in Italy, 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_ITA.pdf〉 [accessed 27 September 2016].
55. Lund, H., Mathiesen, B.V., Energy system analysis of 100% renewable energy systems—The case of Denmark in years 2030 and 2050. Energy 34:5 (2007), 524–531.
56. Connolly, D., Lund, H., Mathiesen, B.V., Leahy, M., The first step towards a 100% renewable energy-system for Ireland. Appl Energy 88:2 (2011), 502–507.
57. Anandarajah, G., Strachan, N., Ekins, P., Kannan, R., Hughes, N., Pathways to a low carbon economy: energy systems modelling UKERC Energy 2050 Research Report, 2009 〈https://www.ucl.ac.uk/energy-models/models/uk-markal/ukerc-2050-uk-markal-research-report〉 [accessed 27 September 2016].
58. Usher W, Strachan N. 2010. UK MARKAL Modelling - Examining Decarbonisation Pathways in the 2020s on the Way to Meeting the 2050 Emissions Target, 〈https://www.ucl.ac.uk/energy-models/models/uk-markal/ccc-fourth-carbon-budget-final-report-uk-markal-updates〉 [accessed 27 September 2016].
59. DeLaquil, P., Wenying, C., Larson, E.D., Modeling China's energy future. Energy Sustain Dev 5:4 (2003), 40–56.
60. La Rovere EL, Gesteira C, Grottera C, Wills W, Pathways to deep decarbonization in Brazil, 〈http://deepdecarbonization.org/wp-content/uploads/2015/12/DDPP_BRA.pdf〉 [accessed 27 September 2016].
61. Criqui, P., Mathy, S., Hourcade, J.C., Pathw Deep decarbonization Fr, 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_FRA.pdf〉 [accessed 27 September 2016].
62. Gambhir, A., Napp, T.A., Emmott, C.J.M., Anandarajah, G., India's CO2 emissions pathways to 2050: energy system, economic and fossil fuel impacts with and without carbon permit trading. Energy 77 (2014), 791–801.
63. Denis, A., Jotzo, F., Ferraro, S., Jones, A., Kautto, N., Kelly, R., Skarbek, A., Thwaites, J., Adams, P., Graham, P., Hatfield-Dodds, S., Pathways to Deep Decarbonization in 2050 – How Australia Can Prosper in a Low Carbon World, 2014 〈http://deepdecarbonization.org/wp-content/uploads/2015/07/DDPP_Australia_Infographic_ClimateWorks.pdf〉 [accessed 27 September 2016].
64. Shukla, P.R., Dhar, S., Pathak, M., Mahadevia, D., Pathways to deep decarbonization in India, 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_IND.pdf〉 [accessed 27 September 2016].
65. Teng, F., Liu, Q., Cheny, Y., Tian, C., Zheng, X., Gu, A., Yang, Xi, Wang, X., Pathways to deep decarbonization in China, 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_CHN.pdf〉 [accessed 27 September 2016].
66. Bataille, C., Sawyer, D., Melton, N., Pathways to deep decarbonization in Canada. 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_CAN.pdf〉 [accessed 27 September 2016].
67. Williams, J.H., Haley, B., Kahrl, F., Moore, J., Jones, A.D., Torn, M.S., McJeon, H., Pathways to deep decarbonisation in the US, 2014 〈http://unsdsn.org/wp-content/uploads/2014/09/US-Deep-Decarbonization-Report.pdf〉 [accessed 27 September 2016].
68. Kainuma, M., Masui, T., Oshiro, K., Hibono, G., Pathways to deep decarbonization in Japan, 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_JPN.pdf〉 [accessed 27 September 2016].
69. Siagiana, U.W.R., Dewia, R.G., Boerb, R., Hendrawana, I., Yuwonoa, B.B., Gintingb, G.E., Pathways to deep decarbonization in Indonesia, 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/11/DDPP_IDN.pdf〉 [accessed 27 September 2016].
70. Buira D, Tovilla J. Pathways to deep decarbonization in Mexico, 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_MEX.pdf〉 [accessed 27 September 2016].
71. Dewi, R.G., Kobashi, T., Matsuoka, Y., Gomi, K., Ehara, T., Kainuma, M., Fujino, J., Low Carbon Society Scenario Toward 2050 Indonesia Energy Sector, 2010 〈http://2050.nies.go.jp/report/file/lcs_asia/IndonesiaLCS.pdf〉 [accessed 27 September 2016].
72. Gastec K. 2015. Scenarios for deployment of hydrogen in contributing to meeting carbon budgets and the 2050 target, 〈https://documents.theccc.org.uk/wp-content/uploads/2015/11/E4tech-for-CCC-Scenarios-for-deployment-of-hydrogen-in-contributing-to-meeting-carbon-budgets.pdf〉 [accessed 27 September 2016].
73. Appendix A: Model description IMACLIM-R. 〈https://www.pik-potsdam.de/members/luderer/recipe-1/wp-model-descriptions-appendix〉 [accessed 20 June 2017].
74. Hillebrandt, K., Samadi, S., Fischedick, M., Pathways to deep decarbonization in Germany, 2015 〈http://deepdecarbonization.org/wp-content/uploads/2015/09/DDPP_DEU.pdf〉 [accessed 27 September 2016].
75. Noble Soft Systems, ANSWER energy modelling software. 〈http://www.noblesoft.com.au/ansmardoc.html#addamdocs〉 [accessed 20 June 2017].
76. CIRED. 〈http://www2.centre-cired.fr/america-2222?Lang=en〉 [accessed 20 June 2017].