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Technologies for Decarbonising the Electricity Sector

Published online by Cambridge University Press:  08 October 2021

Kenneth G. H. Baldwin
Affiliation:
Australian National University, Canberra
Mark Howden
Affiliation:
Australian National University, Canberra
Michael H. Smith
Affiliation:
Australian National University, Canberra
Karen Hussey
Affiliation:
University of Queensland
Peter J. Dawson
Affiliation:
P. J. Dawson & Associates
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Print publication year: 2021

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References

ACT (Australian Capital Territory) Government (2016). Canberra 100% Renewable: Leading Innovation with 100% Renewable Energy by 2020. Canberra: Australian Capital Territory Government. Available at: www.environment.act.gov.au/__data/assets/pdf_file/0007/987991/100-Renewal-Energy-Tri-fold-ACCESS.pdf.Google Scholar
Ahuja, E. (2015). Energy change: Insights from the 1st and 2nd Industrial Revolutions and recent developments to help achieve the next low carbon industrial revolution. Masters Thesis, The Australian National University. Available at: www.academia.edu/27596477/Ahuja_E_2015_Energy_Change_-Insights_from_the_1st_and_2nd_Industrial_Revolutions_and_Recent_Developments_to_help_achieve_the_next_Low_Carbon_Industrial_Revolution._ANU_ECI_Masters_Thesis_advanced_._Supervisor_Dr_Michael_H_Smith.Google Scholar
AEMO (Australian Energy Market Operator) (2018). Integrated System Plan: For the National Electricity Market. Australian Energy Market Operator. Available at: https://aemo.com.au/-/media/files/electricity/nem/planning_and_forecasting/isp/2018/integrated-system-plan-2018_final.pdf.Google Scholar
AWEA (American Wind Energy Association) (n.d.). State facts sheets. American Wind Energy Association. Available at: www.awea.org/resources/fact-sheets/state-facts-sheets.Google Scholar
BP (2019). BP Statistical Review of World Energy 2019. London: BP. Available at: www.bp.com/en/global/corporate/energy-economics/statistical-review-of-world-energy.html.Google Scholar
Chabot, B. (2016). Backing up wind and nuclear power. Erneuerbare Energien. Available at: www.erneuerbareenergien.de/backing-up-wind-and-nuclear-power/150/437/86412/.Google Scholar
Clean Energy Council (2019). Clean Energy Australia Report 2019. Clean Energy Council. Available at: https://assets.cleanenergycouncil.org.au/documents/resources/reports/clean-energy-australia/clean-energy-australia-report-2019.pdf.Google Scholar
Cochran, J., Bird, L., Heeter, J. and Arent, D. J. (2012). Integrating Variable Renewable Energy in Electric Power Markets: Best Practices from International Experience. Springfield, VA: US Department of Energy and US Department of Commerce. Available at: www.nrel.gov/docs/fy12osti/53732.pdf.Google Scholar
Eberhard, A. and Naude, R. (2017). The South African Renewable Energy IPP Procurement Programme: Review, Lessons Learned & Proposals to Reduce Transaction Costs. Cape Town: Graduate School of Business, University of Cape Town. Available at: www.gsb.uct.ac.za/files/EberhardNaude_REIPPPPReview_2017_1_1.pdf.Google Scholar
Hills, R. (1996). Power from Wind: A History of Windmill Technology. Cambridge: Cambridge University Press. Available at: www.cambridge.org/au/academic/subjects/general-science/history-science/power-wind-history-windmill-technology.Google Scholar
Hristova, D. (2016). Peru shortlists 13 winners in renewables auction. Renewables Now. 17 February. Available at: https://renewablesnow.com/news/peru-shortlists-13-winners-in-renewables-auction-513576/.Google Scholar
IEA (International Energy Agency) (2013). Technology Roadmap: Wind Energy. Paris: International Energy Agency. Available at: www.energie-nachrichten.info/file/News/2013/2013-10/Wind_2013_Roadmap.pdf.Google Scholar
IEA (2018). World Energy Outlook 2018. Paris: International Energy Agency. Available at: www.iea.org/reports/world-energy-outlook-2018/electricity.Google Scholar
IPP Renewables (n.d.). BW4 preferred bidder announcement. IPP Projects. 16 April. Available at: https://ipp-projects.co.za/PressCentre.Google Scholar
IRENA (International Renewable Energy Agency) (2019). Future of Wind: Deployment, Investment, Technology, Grid Integration and Socio-economic Aspects (A Global Energy Transformation Paper). Abu Dhabi: International Renewable Energy Agency. Available at: www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Oct/IRENA_Future_of_wind_2019.pdf.Google Scholar
Mora, A. (2017). Mexico’s third long-term electricity auction: The results and the comparison. Mexico Business Publishing. 29 November. Available at: www.renewableenergymexico.com/mexicos-third-long-term-electricity-auction-the-results-and-the-comparison/ (link discontinued).Google Scholar
NREL (National Renewable Energy Laboratory) (2012). Renewable Electricity Futures Study. Edited by Hand, M. M., Baldwin, S., DeMeo, E. et al. 4 vols. NREL/TP-6A20–52409. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/analysis/re-futures.html.Google Scholar
NREL (2017). Cost of Wind Energy Review. Technical Report NREL/TP-6A20–72167. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy18osti/72167.pdf.Google Scholar
OpenNEM (n.d.). OpenNEM Project. Created by McConnell, D., Holmes à Court, S. and Tan, S. Available at: https://opennem.org.au/energy/nem.Google Scholar
REN21 (2018). Renewables 2018: Global Status Report. Paris: REN21. Available at: www.ren21.net/wp-content/uploads/2019/05/GSR2018_Full-Report_English.pdf.Google Scholar
RenewableUK (n.d.). Wind energy statistics. renewableUK. Available at: www.renewableuk.com/page/UKWEDhome/Wind-Energy-Statistics.htm.Google Scholar
RepuTex Energy (2018). The Impact of the NEG on Emissions and Electricity Prices by 2030: Modelling for Greenpeace Australia Pacific. Melbourne: RepuTex Australia. Available at: www.reputex.com/wp-content/uploads/2018/07/REPUTEX_Modelling-of-the-National-Energy-Guarantee_0718_26-45.pdf.Google Scholar
RSA (Republic of South Africa) Department of Energy (2018). 2018 Draft Integrated Resource Plan. Available at: www.energy.gov.za/IRP/irp-update-draft-report-2018.html.Google Scholar
UK DBEIS (Department for Business, Energy and Industrial Strategy) (2013). National statistics: Energy trends: UK renewables. Gov.uk. 9 January. Available at: www.gov.uk/government/statistics/energy-trends-section-6-renewables.Google Scholar
US Department of Energy (2017). 2017 Wind Technologies Market Report. US Department of Energy. Available at: www.energy.gov/eere/wind/downloads/2017-wind-technologies-market-report.Google Scholar
Wright, J. G., Bischof-Niemz, S. T., Calitz, J. R., Mushwana, C. and van Heerden, R. (2017). Future wind deployment scenarios for South Africa. Paper presented at WindAc Conference, Cape Town, South Africa, 14–16 November. Available at: http://hdl.handle.net/10204/10070.Google Scholar
Wright, J., Ireland, G., Hartley, F., Merven, B., Burton, J., Ahjum, F. Mccall, B., Caetano, T. and Arndt, C. (2017). The Developing Energy Landscape in South Africa: Technical Report. Cape Town: University of Cape Town Energy Research Centre, CSIR (Council for Scientific and Industrial Research) and IFPRI (International Food Policy Research Institute).Google Scholar
Yaneva, M. (2016). Morocco’s wind power price goes as low as USD 30/MWh. Renewables Now. 19 January. Available at: https://renewablesnow.com/news/moroccos-wind-power-price-goes-as-low-as-usd-30-mwh-509642/.Google Scholar

References

Bhandarib, K. P., Colliera, J. M., Ellingson, R. J. and Apula, D. S. (2015). Energy payback time (EPBT) and energy return on energy invested (EROI) of solar photovoltaic systems: A systematic review and meta-analysis. Renewable and Sustainable Energy Reviews, 47, 133141.Google Scholar
Blakers, A. (2019). Development of the PERC solar cell. IEEE Journal of Photovoltaics, 9, 629635. Available at: https://ieeexplore.ieee.org/document/8653319.Google Scholar
Blakers, A., Luther, J. and Nadolny, A. (2012). Asia Pacific super grid: Solar electricity generation, storage and distribution. GREEN: The International Journal of Sustainable Energy Conversion and Storage, 2, 189202.Google Scholar
Blakers, A., Lu, B. and Stocks, M. (2017). 100% renewable electricity in Australia. Energy, 133, 471482. Available at: www.sciencedirect.com/science/article/pii/S0360544217309568.Google Scholar
Blakers, A., Stocks, M., Lu, B., Cheng, C. and Stocks, R. (2019). Pathway to 100% renewable electricity. IEEE Journal of Photovoltaics, 9, 18281833. Available at: https://ieeexplore.ieee.org/document/8836526.Google Scholar
Blakers, A., Stocks, M., Lu, B. and Cheng, C. (2021). A review of pumped hydro energy storage. Progress in Energy, 3. Available at: http://iopscience.iop.org/article/10.1088/2516-1083/abeb5b.Google Scholar
Fraunhofer (2015). Photovoltaics Report. Freiburg: Fraunhofer Institute for Solar Energy Systems, ISE. Available at: www.ise.fraunhofer.de/content/dam/ise/de/documents/publications/studies/Photovoltaics-Report.pdf.Google Scholar
IPCC (Intergovernmental Panel on Climate Change) (2014). Climate Change 2014: Synthesis Report. Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Edited by Pachauri, R. K. and Meyer, L. A.. Geneva: IPCC. Available at: www.ipcc.ch/report/ar5/syr/.Google Scholar
IRENA (International Renewable Energy Agency) (2018). Renewable Energy Statistics 2018. Abu Dhabi: International Renewable Energy Agency. Available at: www.irena.org/publications/2018/Jul/Renewable-Energy-Statistics-2018.Google Scholar
Reinders, A., Freundlich, A., van Sark, W. and Verlinden, P. (2015). Photovoltaic Solar Energy: From Fundamentals to Applications. London: Wiley & Sons.Google Scholar
Siemens (2012). Factsheet Energy Sector. Abu Dhabi: Siemens.Google Scholar

References

Agrafiotis, C., von Storch, H., Roeb, M. and Sattler, C. (2014). Solar thermal reforming of methane feedstocks for hydrogen and syngas production: A review. Renewable and Sustainable Energy Reviews, 29I, 656682.Google Scholar
A.T. Kearney (2010). Solar Thermal Electricity 2025. Dusseldorf: A.T. Kearney GmbH and ESTELA (European Solar Thermal Electricity Association). Available at: www.promes.cnrs.fr/uploads/pdfs/documentation/2010-Solar%20thermal%20electricity%202025%20ESTELA.pdf.Google Scholar
Bader, R. and Lipiński, W. (2017). Solar thermal processing. In Blanco, M. and Santigosa, L. R., eds., Advances in Concentrating Solar Thermal Research and Technology. Cambridge: Woodhead Publishing.Google Scholar
Ballestrín, J. and Marzo, A. (2012). Solar radiation attenuation in solar tower plants. Solar Energy, 86(1), 388392.Google Scholar
Bracken, N., Macknick, J., Tovar-Hastings, A., Komor, P., Gerritsen, M. and Mehta, S. (2015). Concentrating Solar Power and Water Issues in the US Southwest. Technical report NREL/TP-6A50–61376. Golden, CO: Joint Institute for Strategic Energy Analysis. Available at: www.nrel.gov/docs/fy15osti/61376.pdf.Google Scholar
Branker, K., Pathak, M. and Pearce, J. (2011). A review of solar photovoltaic levelized cost of electricity. Renewable and Sustainable Energy Reviews, 15(9), 44704482.Google Scholar
Burkhardt, J. J., Heath, G. A. and Turchi, C. S. (2011). Life cycle assessment of a parabolic trough concentrating solar power plant and the impacts of key design alternatives. Environmental Science & Technology, 45, 24572464.CrossRefGoogle ScholarPubMed
Burkhardt, J. J., Heath, G. and Cohen, E. (2012). Life cycle greenhouse gas emissions of trough and tower concentrating solar power electricity generation: Systematic review and harmonization. Journal of Industrial Ecology, 16(1), S93S109.Google Scholar
Cao, C., Hu, J., Li, S., Wilcox, W. and Wang, Y. (2009). Intensified Fischer–Tropsch synthesis process with microchannel catalytic reactors. Catalysis Today, 140, 149156.Google Scholar
Christensen, L. R. and Greene, W. H. (1976). Economies of scale in US electric power generation. Journal of Political Economy, 84, 655676.CrossRefGoogle Scholar
Cochran, J., Mai, T. and Bazilian, M. (2014). Meta-analysis of high penetration renewable energy scenarios. Renewable and Sustainable Energy Reviews, 29I, 246253.CrossRefGoogle Scholar
Cohen, G. E., Kearney, D. W. and Kolb, G. J. (1999). Final Report on the Operation and Maintenance Improvement Program for Concentrating Solar Power Plants. Technical report SAND99–1290. Albuquerque, NM: Sandia National Laboratories. Available at: www.osti.gov/servlets/purl/8378.Google Scholar
CSP (Concentrating Solar Power) Alliance (2014). The Economic and Reliability Benefits of CSP with Thermal Energy Storage: Literature Review and Research Needs. Technical report. CSP Alliance. Available at: www.inship.eu/docs/TES%204%20the_economic_and_reliability_benefits_of_csp_with_thermal_storage_2014_09_09_final.pdf.Google Scholar
Deloitte (2011). Macroeconomic Impact of the Solar Thermal Electricity Industry in Spain. Consultants’ report. Seville: Protermosolar. Available at: www.solarthermalworld.org/sites/default/files/Macroeconomic_impact_of_the_Solar_Thermal_Electricity_Industry_in_Spain_Protermo_Solar_Deloitte_21x21.pdf.Google Scholar
Denholm, P. and Mehos, M. (2011). Enabling Greater Penetration of Solar Power via the Use of CSP with Thermal Energy Storage. Technical report NREL/TP-6A20–52978. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy12osti/52978.pdf.Google Scholar
Denholm, P., Wan, Y.-H., Hummon, M. and Mehos, M. (2013). An Analysis of Concentrating Solar Power with Thermal Energy Storage in a California 33% Renewable Scenario. Technical report NREL/TP-6A20–58186. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy13osti/58186.pdf.CrossRefGoogle Scholar
Denholm, P., Wan, Y.-H., Hummon, M. and Mehos, M. (2014). The value of CSP with thermal energy storage in the western United States. Energy Procedia, 49, 16221631.CrossRefGoogle Scholar
Dutton, J. M. and Thomas, A. (1984). Treating progress functions as a managerial opportunity. Academy of Management Review, 9, 235247.Google Scholar
Eglinton, T., Hinkley, J., Beath, A. and Dell’Amico, M. (2013). Potential applications of concentrated solar thermal technologies in the Australian minerals processing and extractive metallurgical industry. Journal of the Minerals, Metals and Materials Society, 65, 17101720.CrossRefGoogle Scholar
Elliston, B., MacGill, I. and Diesendorf, M. (2013). Least cost 100% renewable electricity scenarios in the Australian National Electricity Market. Energy Policy, 59I, 270282.Google Scholar
Elliston, B., MacGill, I. and Diesendorf, M. (2014). Comparing least cost scenarios for 100% renewable electricity with low emission fossil fuel scenarios in the Australian National Electricity Market. Renewable Energy, 66, 196204. Available at: https://arena.gov.au/assets/2017/06/Elliston_2014_5.pdf.CrossRefGoogle Scholar
ETH Zurich (2019). Carbon-neutral fuel made from sunlight and air. ETH Zürich. 13 June. Available at: https://ethz.ch/en/news-and-events/eth-news/news/2019/06/pr-solar-mini-refinery.html. Google Scholar
Green, A., Diep, C., Dunn, R. and Dent, J. (2015). High capacity factor CSP–PV hybrid systems. Energy Procedia, 69, 20492059. Available at: https://core.ac.uk/download/pdf/81170195.pdf.CrossRefGoogle Scholar
Hernández-Moro, J. and Martínez-Duart, J. (2013). Analytical model for solar PV and CSP electricity costs: Present LCOE values and their future evolution. Renewable and Sustainable Energy Reviews, 20I, 119132.Google Scholar
Hertwich, E. G. and Zhang, X. (2009). Concentrating-solar biomass gasification process for a 3rd generation biofuel. Environmental Science & Technology, 43, 42074212.Google Scholar
Hinkley, J., Curtin, B., Hayward, J. et al. (2011). Concentrating Solar Power: Drivers and Opportunities for Cost-Competitive Electricity. Commissioned report for the Commonwealth Government of Australia. Canberra: CSIRO. Available at: https://publications.csiro.au/rpr/download?pid=csiro:EP111647&dsid=DS3.Google Scholar
Hinkley, J. T., Hayward, J. A., Curtin, B. et al. (2013). An analysis of the costs and opportunities for concentrating solar power in Australia. Renewable Energy, 57, 653661.Google Scholar
Hinkley, J. T., McNaughton, R. K., Pye, J. D., Lipiński, W. and Lovegrove, K. M. (2015). Current and future status of solar fuel technologies in Australia. Journal of the Japan Institute of Energy, 94, 182.Google Scholar
Hinkley, J. T., McNaughton, R. K., Pye, J., Saw, W. and Stechel, E. B. (2015). The challenges and opportunities for integration of solar syngas production with liquid fuel synthesis. Paper presented at 21st SolarPACES Conference, Cape Town, South Africa, 13–16 October.Google Scholar
Ho, C. K. (2016). Review of avian mortality studies at concentrating solar power plants. AIP Conference Proceedings, 1734, 070017.CrossRefGoogle Scholar
Ho, C. K., Sims, C. A. and Christian, J. M. (2014). Evaluation of Glare at the Ivanpah Solar Electric Generating System. Technical report SAND2014–15847. Albuquerque, NM: Sandia National Laboratories. Available at: https://prod-ng.sandia.gov/techlib-noauth/access-control.cgi/2014/1415847.pdf.CrossRefGoogle Scholar
Ho, C. K., Wendelin, T., Horstman, L. and Yellowhair, J. (2016). A method to assess flux hazards at CSP plants to reduce avian mortality. Paper presented at 22nd SolarPACES Conference, Abu Dhabi, UAE, 11–14 October. Available at: www.researchgate.net/publication/317984020_A_method_to_assess_flux_hazards_at_CSP_plants_to_reduce_avian_mortality.Google Scholar
IRENA (International Renewable Energy Agency) (2012). Concentrating Solar Power. IRENA Working Paper. Renewable energy technologies: Cost analysis series Vol. 1: Power Sector. Issue 2/5. Abu Dhabi: International Renewable Energy Agency. Available at: https://irena.org/publications/2012/Jun/Renewable-Energy-Cost-Analysis – Concentrating-Solar-Power.Google Scholar
IRENA (2016). Power to Change: Solar and Wind Cost Reduction Potential to 2025. Abu Dhabi: International Renewable Energy Agency. Available at: www.irena.org/-/media/Files/IRENA/Agency/Publication/2016/IRENA_Power_to_Change_2016.pdf.Google Scholar
IRENA (2019). Renewable Power Generation Costs in 2018. Abu Dhabi: International Renewable Energy Agency. Available at: www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/May/IRENA_Renewable-Power-Generations-Costs-in-2018.pdf.Google Scholar
Jacobowitz, D. and Google (2013). Google’s Green PPAs: What, How, and Why. Technical report. Google. Available at: https://static.googleusercontent.com/media/www.google.com/en//green/pdfs/renewable-energy.pdf.Google Scholar
Jacobson, M. Z., Delucchi, M. A., Bauer, Z. A. et al. (2017). 100% clean and renewable wind, water, and sunlight all-sector energy roadmaps for 139 countries of the world. Joule, 1, 108121. Available at: https://web.stanford.edu/group/efmh/219amsar219n/Articles/I/CountriesWWS.pdf. Google Scholar
Jorgensen, J., Denholm, P., Mehos, M. and Turchi, C. (2013). Estimating the Performance and Economic Value of Multiple Concentrating Solar Power Technologies in a Production Cost Model. Technical report NREL/TP-6A20–58645. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy14osti/58645.pdf.Google Scholar
Jorgenson, J., Denholm, P. and Mehos, M. (2014). Quantifying the value of concentrating solar power in a production cost model. In Proceedings of ASME 2014 8th International Conference on Energy Sustainability collocated with the ASME 2014 12th International Conference on Fuel Cell Science, Engineering and Technology, Vol. 1. ASME (American Society of Mechanical Engineers). Available at: https://asmedigitalcollection.asme.org/ES/ES2014/volume/45868.Google Scholar
Kempener, R., Burch, J., Brunner, C., Navntoft, C. and Mugnier, D. (2015). Solar Heat for Industrial Processes. Technology Brief E21. IEA (International Energy Agency)-ETSAP (Energy Technology Systems Analysis Programme) and IRENA (International Renewable Energy Agency). Available at: www.irena.org/publications/2015/Jan/Solar-Heat-for-Industrial-Processes.Google Scholar
Kolb, G. J., Ho, C. K., Mancini, T. R. and Gary, J. A. (2011). Power Tower Technology Roadmap and Cost Reduction Plan. Sandia report SAND2011–2419. Albuquerque, NM: Sandia National Laboratories. Available at: https://prod-ng.sandia.gov/techlib-noauth/access-control.cgi/2011/112419.pdf.Google Scholar
Konstantin, P. and Kretschmann, J. (2010). Assessment of Technology Options for Development of Concentrating Solar Power in South Africa for The World Bank. Stuttgart: Fichtner. Available at: www.climateinvestmentfunds.org/sites/default/files/Presentation%20-%20WB%20(Eskom)%20Project%20-%202010_12_07%20.pdf. Google Scholar
Kulichenko, N. and Wirth, J. (2011). Regulatory and Financial Incentives for Scaling Up Concentrating Solar Power in Developing Countries . Energy and mining sector board Discussion Paper 24. Washington, DC: World Bank Group.CrossRefGoogle Scholar
Lienhard, J., Antar, M. A., Bilton, A., Blanco, J. and Zaragoza, G. (2012). Solar desalination. Annual Review of Heat Transfer, 15, 277347.Google Scholar
Lilliestam, J. and Pitz-Paal, R. (2018). Concentrating solar power for less than USD 0.07 per kWh: Finally the breakthrough? Renewable Energy Focus, 26, 1721.Google Scholar
Lilliestam, J., Labordena, M., Patt, A. and Pfenninger, S. (2017). Empirically observed learning rates for concentrating solar power and their responses to regime change. Nature Energy, 2, 17094.Google Scholar
Lovegrove, K. (2013). The potential for solar fuels in Australia. Paper presented at the Solar Thermal Chemical and Industrial Processes Workshop, University of Adelaide, Australia, 7–8 February.Google Scholar
Lovegrove, K. and Pye, J. (2012). Fundamental principles of concentrating solar power (CSP) systems. In Lovegrove, K. and Stein, W., eds., Fundamental Principles of Concentrating Solar Power (CSP) Systems. Cambridge: Woodhead Publishing.Google Scholar
Lovegrove, K., Watt, M., Passey, R., Pollock, G., Wyder, J. and Dowse, J. (2012). Realising the Potential of Concentrating Solar Power in Australia. Commissioned report for the Australian Solar Institute. Canberra: IT Power (Australia) Pty Ltd and the Australian Solar Institute.Google Scholar
Lovegrove, K., Edwards, S., Jacobson, N. et al. (2015). Renewable Energy Options for Australian Industrial Gas Users: Background Technical Report. Background technical report ITP/A0142 rev. 2.0. Canberra: IT Power (Australia) Pty Ltd and ARENA (Australian Renewable Energy Agency). Available at: https://itpau.com.au/wp-content/uploads/2018/08/ITP_REOptionsForIndustrialGas_TechReport.compressed.pdf.Google Scholar
Macknick, J., Newmark, R., Heath, G. and Hallett, K. (2011). A Review of Operational Water Consumption and Withdrawal Factors for Electricity Generating Technologies. Technical report NREL/TP-6A20–50900. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy11osti/50900.pdf.Google Scholar
Mendelsohn, M., Kreycik, C., Bird, L., Schwabe, P. and Cory, K. (2012). The Impact of Financial Structure on the Cost of Solar Energy. Technical report NREL/TP-6A20–53086. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy12osti/53086.pdf.Google Scholar
Moore, S. (2018). Sustainable Energy Transformations, Power and Politics: Morocco and the Mediterranean. London: Routledge.CrossRefGoogle Scholar
NREL (National Renewable Energy Laboratory) (n.d.). Concentrating solar power projects [data resource]. SolarPACES. Available at: www.nrel.gov/csp/solarpaces/.Google Scholar
Ortega, M., del Río, P. and Montero, E. A. (2013). Assessing the benefits and costs of renewable electricity: The Spanish case. Renewable and Sustainable Energy Reviews, 27, 294304.Google Scholar
Patt, A., Pfenninger, S. and Lilliestam, J. (2013). Vulnerability of solar energy infrastructure and output to climate change. Climatic Change, 121, 93102.Google Scholar
Pitz-Paal, R., Dersch, J., Milow, B. et al. (2005). ECOSTAR: European Concentrated Solar Thermal Road-Mapping. Roadmap document SES6-CT-2003-502578. DLR (German Aerospace Centre). Available at: www.promes.cnrs.fr/uploads/pdfs/ecostar/ECOSTAR.Roadmap.pdf.Google Scholar
Platzer, W. (2015). Combined solar thermal and photovoltaic power plants: An approach to 24h solar electricity? Paper presented at 21st SolarPACES Conference, Cape Town, South Africa, 13–16 October.Google Scholar
Price, H. (2017). Dispatchable solar power: Adapting CSP to modern grid needs. Paper presented at 23rd SolarPACES Conference, Santiago, Chile, 26–29 September. Available at: www.solarpaces.org/wp-content/uploads/Hank-Price-Presentation.pdf.Google Scholar
Richert, T., Riffelmann, K.-J. and Nava, P. (2012). LCOE versus LCOE versus PPA bid price: How different financing parameters influence their values. Paper presented at 18th SolarPACES Conference, Marrakech, Morocco, 11–14 September.Google Scholar
Romero, M. and González-Aguilar, J. (2014). Solar thermal CSP technology. WIREs Energy and Environment, 3, 4259.Google Scholar
Romero, M. and Steinfeld, A. (2012). Concentrating solar thermal power and thermochemical fuels. Energy & Environmental Science, 5, 92349245.Google Scholar
Sargent and Lundy LLC Consulting Group (2003). Assessment of Parabolic Trough and Power Tower Solar Technology Cost and Performance Forecasts. Subcontractor report NREL/SR-550-34440. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy04osti/34440.pdf.Google Scholar
Shahan, Z. (2013). CSP for 5.57 cents/kWh. CleanTechnica. 14 June. Available at: cleantechnica.com/2013/06/14/csp-for-5-57-centskwh/.Google Scholar
Slaughter, R. (2014). Port Augusta Solar Thermal Generation Feasibility Study: Final Balance of Study. Milestone 4 Report 105-RPT-006. Sydney: Alinta Energy. Available at: https://alintaenergy.com.au/Alinta/media/Documents/Alinta-Energy-Port-Augusta-Solar-Thermal-Generation-Feasibility-Study-Milestone-4-Summary-Report.pdf.Google Scholar
Staight, K. (2016). Sundrop Farms pioneering solar-powered greenhouse to grow food without fresh water. ABC News. 2 October. Available at: www.abc.net.au/news/2016-10-01/sundrop-farms-opens-solar-greenhouse-using-no-fresh-water/7892866. Google Scholar
Steinfeld, A. (2005). Solar thermochemical production of hydrogen: A review. Solar Energy 78, 603615.Google Scholar
Stine, W. B. and Geyer, M. (2001). Power from the Sun. Available at: www.powerfromthesun.net/index.html.Google Scholar
Turchi, C. (2010). Parabolic Trough Reference Plant for Cost Modeling with the Solar Advisor Model (SAM). Technical report NREL/TP-550e47605. Golden, CO: (NREL) National Renewable Energy Laboratory.Google Scholar
Turchi, C., Mehos, M., Ho, C. K. and Kolb, G. J. (2010). Current and future costs for parabolic trough and power tower systems in the US market. Paper presented at 16th SolarPACES Conference, Perpignan, France, 21–24 September.Google Scholar
Viebahn, P., Kronshage, S., Trieb, F. and Lechon, Y. (2008). Final Report on Technical Data, Costs, and Life Cycle Inventories of Solar Thermal Power Plants. DLR (German Aerospace Centre) and CIEMAT (Spanish Centre for Energy, Environment and Technology). Available at: www.solarthermalworld.org/sites/gstec/files/concentratingsolarthermalpowerplants.pdf. Google Scholar
Viebahn, P., Esken, A., Höller, S., Luhmann, H., Pietzner, K. and Vallentin, D. (2010). RECCS Plus: Comparison of Renewable Energy Technologies (RE) with Carbon Dioxide Capture and Storage (CCS). Update and Expansion of the RECCS study. Final report of Wuppertal Institute. Berlin: German BMU (Federal Ministry for the Environment, Nature Conservation and Nuclear Safety). Available at: https://epub.wupperinst.org/frontdoor/deliver/index/docId/5001/file/5001_RECCSplus_en.pdf.Google Scholar
Viebahn, P., Lechon, Y. and Trieb, F. (2011). The potential role of concentrated solar power (CSP) in Africa and Europe: A dynamic assessment of technology development, cost development and life cycle inventories until 2050. Energy Policy, 39, 44204430.Google Scholar
Vivar, M., Herrero, R., Antón, I. et al. (2010). Effect of soiling in CPV systems. Solar Energy, 84, 13271335.Google Scholar
Voutchkov, N. (2016). Desalination: Past, present and future. International Water Association. 17 August. Available at: www.iwa-network.org/desalination-past-present-future.Google Scholar
Wang, Z., Roberts, R. R., Naterer, G. F. and Gabriel, K. S. (2012). Comparison of thermochemical, electrolytic, photoelectrolytic and photochemical solar-to-hydrogen production technologies. International Journal of Hydrogen Energy, 37, 1628716301.Google Scholar
Weiss, W. and Spörk-Dür, M. (2019). Solar Heat Worldwide. Technical report 2019 edition. Gleisdorf, Austria: SHC (Solar Heating and Cooling) Programme, International Energy Agency. Available at: www.iea-shc.org/Data/Sites/1/publications/Solar-Heat-Worldwide-2019.pdf.Google Scholar
Wentzel, M. and Pouris, A. (2007). The development impact of solar cookers: A review of solar cooking impact research in South Africa. Energy Policy, 35, 19091919.Google Scholar
World Bank (2014). Demonstrating the viability of solar thermal power in Morocco. The World Bank. 15 April. Available at: www.worldbank.org/en/results/2014/04/15/demonstrating-the-viability-of-solar-thermal-power-in-morocco.Google Scholar
Zamfirescu, C. and Dincer, I. (2008). Using ammonia as a sustainable fuel. Journal of Power Sources, 185, 459465.Google Scholar
Zedtwitz, P. and Steinfeld, A. (2003). The solar thermal gasification of coal: Energy conversion efficiency and CO2 mitigation potential. Energy, 28, 441456.Google Scholar

References

Bodansky, D. (2005). Nuclear Energy: Principles, Practices, and Prospects, 2nd ed. New York: Springer-Verlag.Google Scholar
Chen, F. F. (2011). An Indispensable Truth: How Fusion Power Can Save the Planet. New York: Springer-Verlag.Google Scholar
Cook, I., Miller, R. L. and Ward, D. J. (2002). Prospects for economic fusion electricity. Fusion Engineering and Design, 63–64, 2533.Google Scholar
Gen IV (Generation IV International Forum) (2002). A Technology Roadmap for Generation IV Nuclear Energy Systems. Issued by the US DOE Nuclear Energy Research Advisory Committee and the Generation IV International Forum. GIF-002-00. Available at: www.gen-4.org/gif/upload/docs/application/pdf/2013-09/gif_rd_outlook_for_generation_iv_nuclear_energy_systems.pdf.Google Scholar
Government of South Australia (2016). Nuclear Fuel Cycle Royal Commission Report. Adelaide: Government of South Australia. Available at: http://nuclearrc.sa.gov.au/media-centre/nuclear-fuel-cycle-royal-commission-report-delivered/.Google Scholar
Hitachi (n.d.). PRISM. Nuclear Power Plants GE Hitachi. Available at: https://nuclear.gepower.com/build-a-plant/products/nuclear-power-plants-overview/prism1.Google Scholar
IAEA (International Atomic Energy Agency) (n.d.a) International project on innovative nuclear reactors and fuel cycles (INPRO). IAEA.org. Available at: www.iaea.org/services/key-programmes/international-project-on-innovative-nuclear-reactors-and-fuel-cycles-inpro.Google Scholar
IAEA (n.d.b). Small modular reactors. IAEA.org. Available at: www.iaea.org/topics/small-modular-reactors.Google Scholar
IAEA (1991). Safety Culture: A Report by the International Nuclear Safety Advisory Group. INSAG Series No. 4. International Atomic Energy Agency. Available at: www.iaea.org/publications/3753/safety-culture.Google Scholar
IAEA (2005). Thorium Fuel Cycle: Potential Benefits and Challenges. IAEA Tecdoc 1450. International Atomic Energy Agency. Available at: www.iaea.org/publications/7192/thorium-fuel-cycle-potential-benefits-and-challenges.Google Scholar
IAEA (2006). Fundamental Safety Principles. IAEA Safety Standards Series No. SF-1. International Atomic Energy Agency. Available at: www.iaea.org/publications/7592/fundamental-safety-principles.Google Scholar
IAEA (2007). Milestones in the Development of a National Infrastructure for Nuclear Power. IAEA Nuclear Energy Series NG-G-3.1. International Atomic Energy Agency. Available at: www.iaea.org/publications/7812/milestones-in-the-development-of-a-national-infrastructure-for-nuclear-power.Google Scholar
IAEA (2011). Geological Disposal Facilities for Radioactive Waste: Specific Safety Guide. IAEA Safety Standards Series No. SSG-14. International Atomic Energy Agency. Available at: www.iaea.org/publications/8535/geological-disposal-facilities-for-radioactive-waste.Google Scholar
IAEA (2016). Nuclear Power Reactors in the World: 2016 Edition. Reference Data Series No. 2. International Atomic Energy Agency. Available at: www.iaea.org/publications/11079/nuclear-power-reactors-in-the-world.Google Scholar
IEA (International Energy Agency) (2016). CO2 Emissions from Fuel Combustion: Highlights. Paris: International Energy Agency. Available at: https://emis.vito.be/sites/emis.vito.be/files/articles/3331/2016/CO2EmissionsfromFuelCombustion_Highlights_2016.pdf.Google Scholar
Till, C. E. and Chang, Y. I. (2011). Plentiful Energy: The Story of the Integral Fast Reactor. Charles E. Till and Yoon Il Chang.Google Scholar
US NRC (Nuclear Regulatory Commission) (n.d.). Pressurized water reactors. U.S. NRC. Available at: www.nrc.gov/reactors/pwrs.html.Google Scholar
Wesson, J. (2004). Tokamaks, 3rd ed. Oxford: Clarendon Press.Google Scholar
WNA (World Nuclear Association) (n.d.). Information library. World Nuclear Association. Available at: www.world-nuclear.org/information-library.aspx.Google Scholar
WNA (2017). Nuclear fuel cycle overview. World Nuclear Association. Available at: www.world-nuclear.org/info/Nuclear-Fuel-Cycle/Introduction/Nuclear-Fuel-Cycle-Overview/.Google Scholar
WNA (2018). Processing of used nuclear fuel. World Nuclear Association. Available at: www.world-nuclear.org/information-library/nuclear-fuel-cycle/fuel-recycling/processing-of-used-nuclear-fuel.aspx.Google Scholar
WNA (2020). Decommissioning nuclear facilities. World Nuclear Association. Available at: www.world-nuclear.org/information-library/nuclear-fuel-cycle/nuclear-wastes/decommissioning-nuclear-facilities.aspx.Google Scholar

References

Agostinho, C. S., Agostinho, A. A., Pelicice, F., Almeida, D. A. d. and Marques, E. E. (2007). Selectivity of fish ladders: A bottleneck in neotropical fish movement. Neotropical Ichthyology, 5, 205213.Google Scholar
Arthur, R. I. and Friend, R. M. (2011). Inland capture fisheries in the Mekong and their place and potential within food-led regional development. Global Environmental Change, 21, 219226.CrossRefGoogle Scholar
Baran, E. and Myschowoda, C. (2009). Dams and fisheries in the Mekong basin. Aquatic Ecosystem Health & Management, 12, 227234.Google Scholar
Bates, B. C., Kundzewicz, Z. W., Wu, S. and. Palutikof, J. P., eds. (2008). Climate Change and Water: Technical Paper of the Intergovernmental Panel on Climate Change. Geneva: IPCC (Intergovernmental Panel on Climate Change) Secretariat.Google Scholar
Béné, C., Barange, M., Subasinghe, R. et al. (2015). Feeding 9 billion by 2050: Putting fish back on the menu. Food Security, 7, 261274.Google Scholar
Bermann, C. (2007). Impasses e controvérsias da hidreletricidade. Estudos Avançados, 21, 139153.Google Scholar
Brink, P. T., ed. (2011). The Economics of Ecosystems and Biodiversity in National and International Policy Making. Oxford: Earthscan.Google Scholar
CBD (Convention on Biological Diversity) (2010). Decision X/28. Inland waters biodiversity. UNEP/CBD/COP/DEC/X/28. Montreal, Canada: Convention on Biological Diversity. Available at: www.cbd.int/decisions/cop/10/28/25.a.Google Scholar
CDM (Clean Development Mechanism) Executive Board (2009 ). Approved Consolidated Baseline and Monitoring Methodology ACM0002: Consolidated Baseline Methodology for Grid-Connected Electricity Generation from Renewable Sources. ACM0002/Version 10. Sectoral Scope: 01. EB 47. United Nations Framework Convention on Climate Change. Bonn: United Nations Framework Convention on Climate Change.Google Scholar
Costanza, R., d’Arge, R., de Groot, R. et al. (1997). The value of the world’s ecosystem services and natural capital. Nature, 387, 253260.Google Scholar
Cowx, I. G. and Welcomme, R. L. (1998). Rehabilitation of Rivers for Fish. Oxford: FAO and Fishing News Books.Google Scholar
Daufresne, M. and Boet, P. (2007). Climate change impacts on structure and diversity of fish communities in rivers. Global Change Biology, 13, 24672478.Google Scholar
Díaz, S., Demissew, S., Carabias, J. et al. (2015). The IPBES Conceptual Framework: Connecting nature and people. Current Opinion in Environmental Sustainability, 14, 116.Google Scholar
Fearnside, P. M. (2004). Greenhouse gas emissions from hydroelectric dams: Controversies provide a springboard for rethinking a supposedly ‘clean’ energy source. An editorial comment. Climatic Change, 66, 18.Google Scholar
Foran, T. (2010). Making Hydropower More Sustainable? A Sustainability Measurement Approach Led by the Hydropower Sustainability Assessment Forum. Chiang Mai: Mekong Program on Water, Environment and Resilience.Google Scholar
Garcia de Leaniz, C. (2008). Weir removal in salmonid streams: Implications, challenges and practicalities. Hydrobiologia, 609, 8396.Google Scholar
Government of Brazil (2008). Executive Summary: National Plan on Climate Change, English version. Brasília: Interministerial Committee on Climate Change, Government of Brazil. Available at: www.mma.gov.br/estruturas/imprensa/_arquivos/96_11122008040728.pdf.Google Scholar
Government of China (2007). China’s National Climate Change Program, English version. Beijing: National Reform and Development Commission, Government of China. Available at: https://en.ndrc.gov.cn/newsrelease_8232/200706/P020191101481828642711.pdf.Google Scholar
Hallegatte, S. (2009). Strategies to adapt to an uncertain climate change. Global Environmental Change, 19, 240247.Google Scholar
Hamududu, B. and Killingtveit, A. (2012). Assessing climate change impacts on global hydropower. Energies, 5, 305322.Google Scholar
Harvey, L. D. D. (2006). The exchanges between Fearnside and Rosa concerning the greenhouse gas emissions from hydro-electric power dams. Climatic Change, 75, 8790.Google Scholar
Howard, C. D. D. (2000). Operations, monitoring and decommissioning of dams. Contributing paper prepared as input to the World Commission on Dams Thematic Review IV.5: Operation, Monitoring and Decommissioning of Dams. Cape Town, South Africa: World Commission on Dams.Google Scholar
ICEM (International Centre for Environmental management) (2010). MRC Strategic Environmental Assessment of Hydropower on the Mekong Mainstream. Final report. Hanoi: International Centre for Environmental Management. Available at: www.mrcmekong.org/assets/Publications/Consultations/SEA-Hydropower/SEA-FR-summary-13oct.pdf.Google Scholar
IEA (International Energy Agency) (2012). Technology Roadmap: Hydropower. Technology report. Paris: International Energy Agency. Available at: www.iea.org/reports/technology-roadmap-hydropower.Google Scholar
IHA (International Hydropower Association) (2010a). Hydropower Sustainability Assessment Protocol. London: International Hydropower Association.Google Scholar
IHA (2010b). Hydropower and the Clean Development Mechanism. Policy statement. London: International Hydropower Association.Google Scholar
IPCC (Intergovernmental Panel on Climate Change) (2007). Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Edited by Parry, M. L., Canziani, O. F., Palutikof, J. P., van der Linden, P. J. and Hanson, C. E.. Cambridge: Cambridge University Press.Google Scholar
Krchnak, K., Richter, B. and Thomas, G. (2009). Integrating Environmental Flows into Hydropower Dam Planning, Design, and Operations. Washington, DC: World Bank Group.Google Scholar
Larnier, M. and Marmulla, G. (2004). Fish passes: Types, principles and geographical distribution – an overview. In Welcomme, R. and Petr, T., eds., Proceedings of the Second International Symposium on the Management of Large Rivers for Fisheries, Vol. II. Bangkok: Food and Agriculture Organization of the United Nations. Available at: www.fao.org/3/ad526e/ad526e0g.htm#bm16.Google Scholar
Lukasiewicz, A., Finlayson, C. M. and Pittock, J. (2013). Identifying Low Risk Climate Change Adaptation in Catchment Management While Avoiding Unintended Consequences. Synthesis and integrative research final report. Gold Coast, Australia: National Climate Change Adaptation Research Facility. Available at: https://nccarf.edu.au/identifying-low-risk-climate-change-adaptation-catchment-management-while-avoiding/.Google Scholar
MEA (Millennium Ecosystem Assessment) (2005). Ecosystems and Human Well-being: Wetlands and Water. Synthesis. Washington, DC: World Resources Institute. Available at: www.millenniumassessment.org/documents/document.358.aspx.pdf.Google Scholar
Milly, P. C. D., Betancourt, J., Falkenmark, M. et al. (2008). Stationarity is dead: Whither water management? Science, 319, 573574.Google Scholar
Null, S. E., Ligare, S. T. and Viers, J. H. (2013). A method to consider whether dams mitigate climate change effects on stream temperatures. Journal of the American Water Resources Association, 49, 14561472.Google Scholar
Olden, J. D. and Naiman, R. J. (2009). Incorporating thermal regimes into environmental flows assessments: Modifying dam operations to restore freshwater ecosystem integrity. Freshwater Biology, 55, 86107.Google Scholar
Opperman, J. J., Apse, C., Banks, J., Day, L. R. and Royte, J. (2011). The Penobscot River (Maine, USA): A basin-scale approach to balancing power generation and ecosystem restoration. Ecology and Society, 16, 7. Available at: www.ecologyandsociety.org/vol16/iss3/art7/.Google Scholar
Opperman, J. J., Galloway, G. E., Fargione, J., Mount, J. F., Richter, B. D. and Secchi, S. (2009). Sustainable floodplains through large-scale reconnection to rivers. Science, 326, 14871488.Google Scholar
Opperman, J. J., Hartmann, J. and Harrison, D. (2015). Hydropower within the climate, energy and water nexus. In Pittock, J., Hussey, K. and Dovers, S.., eds., Climate, Energy and Water: Managing Trade-offs, Seizing Opportunities. Cambridge: Cambridge University Press.Google Scholar
Orr, S., Pittock, J., Chapagain, A. and Dumaresq, D. (2012). Dams on the Mekong River: Lost fish protein and the implications for land and water resources. Global Environmental Change, 22, 925932.Google Scholar
Pacca, S. (2007). Impacts from decommissioning of hydroelectric dams: A life cycle perspective. Climatic Change, 84, 281294.Google Scholar
Palmer, M. A., Liermann, R., Nilsson, C. et al. (2008). Climate change and the world’s river basins: Anticipating management options. Frontiers in Ecology and the Environment, 6, 8189.Google Scholar
Pittock, J. (2010). Better management of hydropower in an era of climate change. Water Alternatives, 3, 444452.Google Scholar
Pittock, J. (2019). Pumped-storage hydropower: Trading off environmental values? Australian Environment Review, 33, 195200.Google Scholar
Pittock, J. and Finlayson, C. M. (2011). Australia’s Murray-Darling Basin: Freshwater ecosystem conservation options in an era of climate change. Marine and Freshwater Research, 62, 232243.Google Scholar
Pittock, J. and Hartmann, J. (2011). Taking a second look: Climate change, periodic re-licensing and better management of old dams. Marine and Freshwater Research, 62, 312320.Google Scholar
PMCCC (Prime Minister’s Council on Climate Change) (2008). National Action Plan on Climate Change. New Delhi: Government of India.Google Scholar
Poff, N. L., Olden, J. D., Merritt, D. M. and Pepin, D. M. (2007). Homogenization of regional river dynamics by dams and global biodiversity implications. Proceedings of the National Academy of Sciences, 104, 57325737.CrossRefGoogle ScholarPubMed
Postel, S. and Richter, B. (2003). Rivers for Life: Managing Water for People and Nature. Washington, DC: Island Press.Google Scholar
Ramsar (Ramsar Convention) (2008). The Ramsar Strategic Plan 2009–2015. Gland: Ramsar Convention Secretariat. Available at: www.ramsar.org/document/the-ramsar-strategic-plan-2009-2015.Google Scholar
Richter, B. D., Postel, S., Revenga, C. et al. (2010). Lost in development’s shadow: The downstream human consequences of dams. Water Alternatives, 3, 1442.Google Scholar
Rosa, L. P., dos Santos, M. A., Matvienko, B., dos Santos, E. O. and Sikar, E. (2006). Scientific errors in the Fearnside comments on greenhouse gas emissions (GHG) from hydroelectric dams and response to his political claiming. Climatic Change, 75, 91102.Google Scholar
Russo, T. N. (2000). US Federal Energy Regulatory Commission. Contributing paper prepared as input to the World Commission on Dams Thematic Review IV.5: Operation, Monitoring and Decommissioning of Dams. Cape Town, South Africa: World Commission on Dams.Google Scholar
US DoE (Department of Energy) (2015). Marine and Hydrokinetic Energy Projects: Fiscal Years 2008–2014. US Department of Energy Wind and Water Power Technologies Office Funding in the United States. Washington, DC: US Department of Energy. Available at: www.energy.gov/sites/prod/files/2015/04/f22/MHK-Project-Report-4-14-15.pdf.Google Scholar
Viers, J. H. (2011). Hydropower relicensing and climate change. Journal of the American Water Resources Association, 47, 655661.Google Scholar
WCD (World Commission on Dams) (2000). Dams and Development: A New Framework for Decision-Making. The report of the World Commission on Dams. London: Earthscan. Available at: www.internationalrivers.org/resources/dams-and-development-a-new-framework-for-decision-making-3939.Google Scholar
Weisser, D. (2007). A guide to life-cycle greenhouse gas (GHG) emissions from electric supply technologies. Energy, 32, 15431559.Google Scholar
World Bank (2004). Water Resources Sector Strategy: Strategic Directions for World Bank Engagement. Washington, DC: World Bank. Available at: http://documents.worldbank.org/curated/en/941051468765560268/Water-resources-sector-strategy-strategic-directions-for-World-Bank-engagement.Google Scholar
WWF (World Wildlife Fund) (2004). Repowering Hydroelectric Utility Plants as an Environmentally Sustainable Alternative to Increasing Energy Supply in Brazil. Brasília: WWF Brazil. Available at: http://assets.panda.org/downloads/brazilupgradinghydropowerreport.pdf.Google Scholar
WWF (2006). Free-Flowing Rivers: Economic Luxury or Ecological Necessity? Gland: WWF International. Available at: https://wwf.panda.org/?63020/Free-flowing-rivers-Economic-luxury-or-ecological-necessity.Google Scholar
WWF (2007). Climate Solutions: WWF’s Vision for 2050. Gland: WWF International. Available at: https://wwf.panda.org/?122201/Climate-Solutions-WWFs-Vision-for-2050.Google Scholar
Ziv, G., Baran, E., Nam, S., Rodríguez-Iturbe, I. and Levin, S. A. (2012). Trading-off fish biodiversity, food security, and hydropower in the Mekong River basin. Proceedings of the National Academy of Sciences, 109, 56095614.Google Scholar

References

1414 Degrees (n.d.). How. 1414 Degrees. Available at: https://1414degrees.com.au/how/.Google Scholar
Amber Kinetics (n.d.). Flywheel energy storage. Available at: www.amberkinetics.com.Google Scholar
Ambrosio-Albalá, P., Upham, P. and Bale, C. S. (2019). Purely ornamental? Public perceptions of distributed energy storage in the United Kingdom. Energy Research and Social Science, 48, 139150.CrossRefGoogle Scholar
Amiryar, M. E. and Pullen, K. R. (2017). A review of flywheel energy storage system technologies and their applications. Applied Sciences, 7, 286.Google Scholar
Amnesty International (2017). Industry giants fail to tackle child labour allegations in cobalt battery supply chains. Amnesty International. 15 November. Available at: www.amnesty.org/en/latest/news/2017/11/industry-giants-fail-to-tackle-child-labour-allegations-in-cobalt-battery-supply-chains/.Google Scholar
ARENA (Australian Renewable Energy Agency) (2019). South Australian zinc mine to be converted into Australia’s first compressed air facility for renewable energy storage. ARENA. 8 February. Available at: https://arena.gov.au/news/south-australian-zinc-mine-to-be-converted-into-australias-first-compressed-air-facility-for-renewable-energy-storage/.Google Scholar
Australian Energy Market Operator (2018a). Initial Operation of the Hornsdale Power Reserve Battery Energy Storage System. Australian Energy Market Operator. Available at: www.aemo.com.au/-/media/Files/Media_Centre/2018/Initial-operation-of-the-Hornsdale-Power-Reserve.pdf.Google Scholar
Australian Energy Market Operator (2018b). NEM Virtual Power Plant (VPP) Demonstrations Program. Consultations paper. Australian Energy Market Operator. Available at: www.aemo.com.au/-/media/Files/Electricity/NEM/DER/2018/NEM-VPP-Demonstrations-program.pdf.Google Scholar
Banks, J., Bruce, A. and MacGill, I. (2017). Fast frequency response markets for high renewable energy penetrations in the future Australian NEM. Paper presented at the Asia-Pacific Solar Research Conference 2017, Melbourne, 5–7 December. Available at: www.ceem.unsw.edu.au/sites/default/files/documents/024_J-Banks_DI_Peer-reviewed.pdf.Google Scholar
Barbour, E., Wilson, I. G., Radcliffe, J., Ding, Y. and Li, Y. (2016). A review of pumped hydro energy storage development in significant international electricity markets. Renewable and Sustainable Energy Reviews, 61, 421432.Google Scholar
Beacon Power (n.d.). Stephentown, New York. Beacon Power. Available at: https://beaconpower.com/stephentown-new-york/.Google Scholar
Blaga, R., Sabadus, A., Stefu, N., Dughir, C., Paulesu, M. and Badescu, V. (2018). A current perspective on the accuracy of incoming solar energy forecasting. Progress in Energy and Combustion Science, 70, 119144.Google Scholar
Blakers, A., Stocks, M., Lu, B., Cheng, C. and Nadolny, A. (n.d.). Global Pumped Hydro Atlas. The Australian National University. Available at: http://re100.eng.anu.edu.au/global/index.php.Google Scholar
Bloomberg NEF (New Energy Finance) (2017). New Energy Outlook 2017. London: Bloomberg New Energy Finance.Google Scholar
Breeze, P. (2018). Power System Energy Storage Technologies. London: Academic Press.Google Scholar
Brown, A. (2017). Tesla’s Gigafactory to build Model 3 motors in addition to batteries. The Drive. 18 January. Available at: www.thedrive.com/news/7008/teslas-gigafactory-to-build-model-3-motors-in-addition-to-batteries.Google Scholar
Budt, M., Wolf, D., Span, R. and Yan, J. (2016). A review on compressed air energy storage: Basic principles, past milestones and recent developments. Applied Energy, 170, 250268.Google Scholar
Bulkeley, H., Powells, G. and Bell, S. (2016). Smart grids and the constitution of solar electricity conduct. Environment and Planning A: Economy and Space, 48, 723.Google Scholar
California Public Utilities Commission (n.d.). Rule 21 interconnection. California Public Utilities Commission. Available at: www.cpuc.ca.gov/Rule21/.Google Scholar
California Public Utilities Commission (2018). Resolution E-4949. Available at: http://docs.cpuc.ca.gov/PublishedDocs/Published/G000/M229/K550/229550723.PDF.Google Scholar
Cavanagh, K., Ward, J., Behrens, S., Bhatt, A., Ratnam, E., Oliver, E. and Hayward, J. (2015). Electrical Energy Storage: Technology Overview and Applications. Canberra: Commonwealth Scientific and Industrial Research Organisation. Available at: www.aemc.gov.au/sites/default/files/content/7ff2f36d-f56d-4ee4-a27b-b53e01ee322c/CSIRO-Energy-Storage-Technology-Overview.pdf.Google Scholar
Chen, H., Cong, T. N., Yang, W., Tan, C., Li, Y. and Ding, Y. (2009). Progress in electrical energy storage system: A critical review. Progress in Natural Science, 19, 291312.Google Scholar
Chu, J. (2019). Sun in a box. MIT Technology Review. 27 February. Available at: www.technologyreview.com/s/612798/sun-in-a-box/.Google Scholar
Colthorpe, A. (2018). Germany reaches 100k home battery storage installations. Energy Storage News. 28 August. Available at: www.energy-storage.news/news/germany-reaches-100k-home-battery-storage-installations. Google Scholar
Crotogino, F., Mohmeyer, K.-U. and Scharf, R. (2001). Huntorf CAES: More than 20 years of successful operation. Available at: www.fze.uni-saarland.de/AKE_Archiv/AKE2003H/AKE2003H_Vortraege/AKE2003H03c_Crotogino_ea_HuntorfCAES_CompressedAirEnergyStorage.pdf.Google Scholar
Devine-Wright, P., Batel, S., Aas, O., Sovacool, B., Carnegie Labelle, M. and Ruud, A. (2017). A conceptual framework for understanding the social acceptance of energy infrastructure: Insights from energy storage. Energy Policy, 107, 2731.Google Scholar
Ding, K. and Zhi, J. (2016). Wind power peak–valley regulation and frequency control technology. In Wang, N., Kang, C. and Ren, D., eds., Large-Scale Wind Power Grid Integration. Academic Press, pp. 211232.Google Scholar
Dow, J. (2018). VW’s Electrify America opens California’s first 350kW ultra-fast charger, before cars can actually use it. electrek. 6 December. Available at: https://electrek.co/2018/12/06/electrify-america-first-350kw-charger-california/.Google Scholar
Dustmann, C. (2004). Advances in ZEBRA batteries. Journal of Power Sources, 127, 8592.Google Scholar
Energy Networks Association (n.d.). Future worlds: Consultation. Energy Networks Association. Available at: www.energynetworks.org/electricity/futures/open-networks-project/future-worlds/future-worlds-consultation.html.Google Scholar
Energy Networks Australia (2018). A joint Energy Networks Australia and Australian Energy Market Operator (AEMO) project. Energy Networks Australia. Available at: www.energynetworks.com.au/joint-energy-networks-australia-and-australian-energy-market-operator-aemo-project.Google Scholar
Energy Storage Association (n.d.a). Mechanical energy storage: CAES. Energy Storage Association. Available at: http://energystorage.org/compressed-air-energy-storage-caes.Google Scholar
Energy Storage Association (n.d.b). Mechanical energy storage: Flywheels. Energy Storage Association. Available at: http://energystorage.org/energy-storage/technologies/flywheels.Google Scholar
European Commission (2016). Massive InteGRATion of power Electronic devices. Cordis. Available at: https://cordis.europa.eu/project/rcn/199590/factsheet/en.Google Scholar
EV SafeCharge (2019). DC fast charging explained. EV SafeCharge. Available at: https://evsafecharge.com/dc-fast-charging-explained/.Google Scholar
Fang, J., Li, H., Tang, Y. and Blaabjerg, F. (2018). Distributed power system virtual inertia implemented by grid-connected power converters. IEEE Transactions on Power Electronics, 33, 84888499.Google Scholar
Fitzpatrick, E. (2013). Solar storage plant Gemasolar sets 36-day record for 24/7 output. Renew Economy. 8 October. Available at: https://reneweconomy.com.au/solar-storage-plant-gemasolar-sets-36-day-record-247-output-12586/.Google Scholar
Garvey, S. (2018). Let’s store solar and wind energy: By using compressed air. The Conversation. 24 October. Available at: https://theconversation.com/lets-store-solar-and-wind-energy-by-using-compressed-air-103183.Google Scholar
Ginninderry Energy Research Team (2017). Householder Attitudes to Residential Renewable Energy Futures. Canberra: Riverview Projects. Available at: https://ginninderry.com/wp-content/uploads/2016/09/Ginninderry-2017-Householder-Attitudes-to-Residential-Renewable-Energy-Futures.pdf.Google Scholar
Graham, P. W., Hayward, J., Foster, J., Story, O. and Havas, L. (2018). GenCost 2018: Updated Projections of Electricity Generation Technology Costs. Canberra: Commonwealth Scientific and Industrial Research Organisation. Available at: www.csiro.au/~/media/News-releases/2018/renewables-cheapest-new-power/GenCost2018.pdf.Google Scholar
Guangdong Hydropower Planning and Design Institute (2013). Shenzhen Pumped Storage Power Station. GPDI. 19 December. Available at: www.gpdiwe.com/en/webview/?artid=40815.Google Scholar
Gür, T. (2018). Review of electrical energy storage technologies, materials and systems: Challenges and prospects for large-scale grid storage. Energy & Environmental Science, 10, 26962767.Google Scholar
Hebner, R., Beno, J. and Walls, A. (2002). Flywheel batteries come around again. IEEE Spectrum, 39, 4651.Google Scholar
Hering, G. (2019). Amid global battery boom, 2019 marks new era for energy storage. S&P Global Market Intelligence. 11 January. Available at: www.spglobal.com/marketintelligence/en/news-insights/trending/9GIYsd7qF8tNpiopwH7KSg2.Google Scholar
Hicks, J. and Ison, N. (2018). An exploration of the boundaries of ‘community’ in community renewable energy projects: Navigating between motivations and context. Energy Policy, 113, 523534.Google Scholar
Hui, A. and Walker, G. (2018). Concepts and methodologies for a new relational geography of energy demand: Social practices, doing-places and settings. Energy Research & Social Science, 36, 2129.Google Scholar
Hwang, J., Myung, S. and Sun, Y. (2017). Sodium-ion batteries: Present and future. Chemical Society Reviews, 12, 35293614.Google Scholar
Hydro Tasmania (2018). Battery of the Nation: Analysis of the Future National Energy Market. Hobart: Hydro Tasmania. Available at: www.hydro.com.au/docs/default-source/clean-energy/battery-of-the-nation/future-state-nem-analysis-full-report.pdf.Google Scholar
IEA (International Energy Agency) (2014). Technology Roadmap: Energy Storage. Technical report. Paris: International Energy Agency. Available at: www.iea.org/reports/technology-roadmap-energy-storage.Google Scholar
IEA (2019a). Electric vehicles. Tracking Transport. Paris: International Energy Agency. Available at: www.iea.org/topics/tracking-clean-energy-progress (these data accessed 2019).Google Scholar
IEA (2019b). Energy storage. Tracking Energy Integration. Paris: International Energy Agency. Available at: www.iea.org/topics/tracking-clean-energy-progress(thesedataaccessed2019). Google Scholar
IEA (2019c). Sustainable Development Scenario. Paris: International Energy Agency. Available at: www.iea.org/reports/world-energy-model/sustainable-development-scenario.Google Scholar
IEA (2019d). Will pumped storage hydropower expand more quickly than stationary battery storage? Analysis from Renewables 2018. IEA.org. 4 March. Available at: www.iea.org/articles/will-pumped-storage-hydropower-expand-more-quickly-than-stationary-battery-storage.Google Scholar
IRENA (International Renewable Energy Agency) (2017). Electricity Storage and Renewables: Costs and Markets to 2030. Abu Dhabi: International Renewable Energy Agency. Available at: www.irena.org/-/media/Files/IRENA/Agency/Publication/2017/Oct/IRENA_Electricity_Storage_Costs_2017.pdf.Google Scholar
IRENA (2019). Renewable energy now accounts for a third of global power capacity. IRENA.org. 2 April. Available at: www.irena.org/newsroom/pressreleases/2019/Apr/Renewable-Energy-Now-Accounts-for-a-Third-of-Global-Power-Capacity.Google Scholar
Jones, C. R., Gaede, J., Ganowski, S. and Rowlands, I. H. (2018). Understanding lay-public perceptions of energy storage technologies: Results of a questionnaire conducted in the UK. Energy Procedia, 151, 135143.Google Scholar
Kane, M. (2018). Nissan LEAF is Germany’s first V2G-approved electric car. Inside EVs. 23 October. Available at: https://insideevs.com/news/340585/350ought-leaf-is-germanys-first-v2g-approved-electric-car/.Google Scholar
Kane, M. (2019). Here is the Nissan LEAF e+ 62 kWh battery: Video. Inside EVs. 9 January. Available at: https://insideevs.com/news/342009/here-is-the-nissan-leaf-e-62-kwh-battery-video/.Google Scholar
Ke, X., Prahl, J., Alexander, J., Wainright, J., Zawodzinski, T. and Savinell, R. (2018). Rechargeable redox flow batteries: Flow fields, stacks and design considerations. Chemical Society Reviews, 23, 87218743.Google Scholar
Keller, T. (2016). Could this be the most extreme power plant in the world? GE Reports: Hydropower. 7 June. Available at: www.ge.com/reports/how-the-swiss-turned-an-alpine-peak-into-a-battery-the-size-of-a-nuclear-plant/.Google Scholar
Kemp, R. (1994). Technology and the transition to environmental sustainability: The problem of technological regime shifts. Futures, 26, 10231046.Google Scholar
Kruger, K. (2018). Li-ion battery versus pumped storage for bulk energy storage: A comparison of raw material, investment costs and CO2 footprints. Paper presented at HydroVision Conference, Charlotte, USA, 27 June. Available at: www.voith.com/corp-de/VH_Paper_Battery-versus-Pumped-Storage-_2018_HydroVision_en.pdf.Google Scholar
KTrimble, (2009). Aerial photo of Taum Sauk reservoir under construction [image]. Wikimedia Commons. 22 November. Available at: https://commons.wikimedia.org/wiki/File:TaumSaukReservoir_underconstruction.jpg.Google Scholar
Lambert, F. (2018). Tesla Semi production version will have closer to 600 miles of range, says Elon Musk. electrek. 2 May. Available at: https://electrek.co/2018/05/02/tesla-semi-production-version-range-increase-elon-musk/.Google Scholar
Lambert, F. (2019a). Tesla releases new Model S battery pack, makes massive price drop, kills base Model X pack. electrek. 1 March. Available at: https://electrek.co/2019/03/01/tesla-model-s-model-x-prices-options/.Google Scholar
Lambert, F. (2019b). Volvo delivers its first electric trucks. electrek. 21 February. Available at: https://electrek.co/2019/02/21/volvo-delivers-first-electric-trucks/.Google Scholar
Laughlin, R. (2017). Pumped thermal grid storage with heat exchange. Renewable and Sustainable Energy, 9. Available at: https://doi.org/10.1063/1.4994054.Google Scholar
Lazard, (2018). Levelized Cost of Energy Analysis: Version 4.0. Available at: https://www.lazard.com/perspective/levelized-cost-of-energy-and-levelized-cost-of-storage-2018/.Google Scholar
Li, L., Zhang, X., Li, M., Chen, R., Wu, F., Amine, K. and Liu, J. (2018). The recycling of spent lithium-ion batteries: A review of current processes and technologies. Electrochemical Energy Reviews, 1, 461482.Google Scholar
Liu, H., Chen, C., Lv, X., Wu, X. and Liuy, M. (2019). Deterministic wind energy forecasting: A review of intelligent predictors and auxiliary methods. Energy Conversion and Management, 195, 328345.Google Scholar
Lovell, H. (2017). Are policy failures mobile? An investigation of the Advanced Metering Infrastructure Program in the State of Victoria, Australia. Environment and Planning A: Economy and Space, 49, 314331.Google Scholar
Lutzenhiser, L. (2014). Through the energy efficiency looking glass. Energy Research & Social Science, 1, 141151.Google Scholar
Lv, W., Wang, Z., Cao, H., Sun, O., Zhang, Y. and Sun, Z. (2018). A critical review and analysis on the recycling of spent lithium-ion batteries. ACS Sustainable Chemistry & Engineering, 6, 15041521.Google Scholar
Maloney, P. (2018). Electric vehicle and stationary storage batteries begin to diverge as performance priorities evolve. Utility Dive. 1 August. Available at: www.utilitydive.com/news/batteries-for-electric-vehicles-and-stationary-storage-are-showing-signs-of/528848/.Google Scholar
May, G., Davidson, A. and Monahov, B. (2018). Lead batteries for utility energy storage: A review. Journal of Energy Storage, 15, 145157.Google Scholar
Mulder, F. (2014). Implications of diurnal and seasonal variations in renewable energy generation for large scale energy storage. Journal of Renewable and Sustainable Energy, 6. Available at: https://doi.org/10.1063/1.4874845.Google Scholar
Neoen (2017). Hornsdale Power Reserve. Available at: https://hornsdalepowerreserve.com.au/.Google Scholar
NREL (National Renewable Energy Laboratory) (n.d.). Concentrating solar power projects by project name. Concentrating Solar Power Projects. Available at: https://solarpaces.nrel.gov/projects.Google Scholar
Parkinson, G. (2019). Tesla Big Battery delivered a $22 million profit in 2018. Renew Economy. 14 May. Available at: https://reneweconomy.com.au/tesla-big-battery-delivered-a-22-million-profit-in-2018-2018/.Google Scholar
Patel, S. (2013). Spain inaugurates 2-GW pumped storage facility. Power. 30 November. Available at: www.powermag.com/spain-inaugurates-2-gw-pumped-storage-facility/.Google Scholar
Pena-Alzola, R., Sebastián, R., Quesada, J. and Colmenar, A. (2011). Review of flywheel based energy storage systems. In 2011 International Conference on Power Engineering, Energy and Electrical Drives, PowerEng2011. Piscataway, NJ: IEEE, pp. 16.Google Scholar
Ratnam, E., Weller, S. and Kellett, C. (2016). Central versus localized optimization-based approaches to power management in distribution networks with residential battery storage. International Journal of Electrical Power & Energy Systems, 80, 396406.Google Scholar
Robson, P. and Bonomi, D. (2018). Growing the Battery Storage Market 2018: Exploring Four Key Issues. White paper. Dufresne Research. Available at: https://energystorageforum.com/files/ESWF_Whitepaper_-_Growing_the_battery_storage_market.pdf.Google Scholar
Rogers, J., Watkins, C. and Hoffman, D. (n.d.). Overview and History of the Taum Sauk Pumped Storage Project. Rolla, MO: Missouri University of Science and Technology. Available at: https://web.mst.edu/~rogersda/dams/2_43_Rogers.pdf.Google Scholar
Rogner, M. and Troja, N. (2018). The World’s Water Battery: Pumped Hydropower Storage and the Clean Energy Transition. IHA Working Paper. London: International Hydropower Association. Available at: www.hydropower.org/publications/the-world-e2-80-99s-water-battery-pumped-hydropower-storage-and-the-clean-energy-transition. Google Scholar
Romanach, L., Contreras, Z. and Ashworth, P. (2013). Australian Householders’ Interest in the Distributed Energy Market [survey]. Report No. EP133598. Canberra: Commonwealth Scientific and Industrial Research Organisation (CSIRO). Available at: http://apvi.org.au/wp-content/uploads/2013/11/CSIRO-Survey-Report.pdf.Google Scholar
Scott, P., Gordon, D., Franklin, E., Jones, L. and Thiebaux, S. (2019). Network-aware coordination of residential distributed energy resources. IEEE Transactions on Smart Grid, 10, 65286537.Google Scholar
Seltzer, M. A. (2017). Why salt is this power plant’s most valuable asset. Smithsonian Magazine. 4 August. Available at: www.smithsonianmag.com/innovation/salt-power-plant-most-valuable-180964307/.Google Scholar
Singh, M., Lopes, L. and Ninad, N. (2015). Grid forming battery energy storage system (BESS) for a highly unbalanced hybrid mini-grid. Electric Power Systems Research, 127, 126133.Google Scholar
Snowy Hydro (2019). Snowy 2.0 Project Update. Snowy Hydro Limited. Available at: www.snowyhydro.com.au/our-scheme/snowy20/.Google Scholar
Sobri, S., Koohi-Kamali, S. and Abdul Rahim, N. (2018). Solar photovoltaic generation forecasting methods: A review. Energy Conversion and Management, 156, 459497.Google Scholar
Sovacool, B. K. (2014). What are we doing here? Analyzing fifteen years of energy scholarship and proposing a social science research agenda. Energy Research & Social Science, 1, 129.Google Scholar
Spears, J. (2014). Ontario electricity gets taken for a spin. The Star. 7 November.Google Scholar
StreetScooter (n.d.). StreetScooter. Available at: www.streetscooter.com/de. Google Scholar
Sunspec Alliance (2016). IEEE 2030.5 Common California IOU Rule 21 Implementation Guide for Smart Inverters. Common Smart Inverter Profile Working Group. Available at: www.pge.com/includes/docs/pdfs/shared/customerservice/nonpgeutility/electrictransmission/handbook/rule21-implementation-guide.pdf.Google Scholar
US DOE (Department of Energy) (n.d.). DOE OE Global Energy Storage Database. Available at: www.sandia.gov/ess/global-energy-storage-database/.Google Scholar
Watson, P., Lovell, H., Ransan-Cooper, H., Hann, V. and Harwood, A. (2019). CONSORT Bruny Island battery trial. Project final report. Available at: http://brunybatterytrial.org/wp-content/uploads/2019/05/consort_social_science.pdf.Google Scholar
Weaver, J. F. (2017). World’s largest battery: 200MW/800MWh vanadium flow battery: Site work ongoing. electrek. 21 December. Available at: https://electrek.co/2017/12/21/worlds-largest-battery-200mw-800mwh-vanadium-flow-battery-rongke-power/.Google Scholar
Weber, A., Mench, M. M., Meyers, J., Ross, P., Gostick, J. and Liu, Q. (2011). Redox flow batteries: A review. Applied Electrochemistry, 41, 11371164.Google Scholar
West, N., Watson, P. and Potter, C. (2018). Pumped Hydro Cost Modelling. ENTURA-10686B. Cambridge, Tasmania: Entura. Available at: www.aemo.com.au/-/media/Files/Electricity/NEM/Planning_and_Forecasting/Inputs-Assumptions-Methodologies/2019/Report-Pumped-Hydro-Cost-Modelling.pdf.Google Scholar
Zinaman, O., Bowen, T. and Aznur, A. (2020). An Overview of Behind-the-Meter Solar-Plus-Storage Regulatory Design. Report/Contract No. IAG-17-2050. USA: National Renewable Energy Lab. Available at: www.nrel.gov/docs/fy20osti/75283.pdf.Google Scholar

References

Ang, B. W., Choong, W. L. and Ng, T. S. (2015). Energy security: Definitions, dimensions and indexes. Renewable and Sustainable Energy Reviews, 42, 10771093.Google Scholar
Balcombe, P., Brierly, J., Lewis, C. et al. (2019). How to decarbonise international shipping: Options for fuels, technologies and policies. Energy Conversion and Management, 182(January), 7288.Google Scholar
Bataille, C., Guivarch, C., Hallegatte, S. et al. (2018). Carbon prices across countries. Nature Climate Change, 8, 648650.Google Scholar
Bento, N. (2008). Building and interconnecting hydrogen networks: Insights from the electricity and gas experience in Europe. Energy Policy, 36, 30193028.Google Scholar
Bockris, J. O. and Appleby, A. J. (1972). The hydrogen economy: An ultimate economy? The Environment This Month, 1, 2935.Google Scholar
Bruce, S., Temminghoff, M., Hayward, J. et al. (2018). National Hydrogen Roadmap: Pathways to an Economically Sustainable Hydrogen Industry in Australia. Canberra: Commonwealth Scientific and Industrial Research Organisation (CSIRO). Available at: www.csiro.au/en/Do-business/Futures/Reports/Hydrogen-Roadmap.Google Scholar
Buttler, A. and Spliethoff, H. (2018). Current status of water electrolysis for energy storage, grid balancing and sector coupling via power-to-gas and power-to-liquids: A review. Renewable and Sustainable Energy Reviews, 82, 24402454.Google Scholar
Caldera, U., Bogdanov, D., Afanasyeva, S. et al. (2017). Role of seawater desalination in the management of an integrated water and 100% renewable energy based power sector in Saudi Arabia. Water, 10. DOI: 10.3390/w10010003.Google Scholar
Carbon Pricing Leadership Coalition (2017). Report of the High-Level Commission on Carbon Prices. Washington, DC: World Bank. Available at: www.carbonpricingleadership.org/report-of-the-highlevel-commission-on-carbon-prices.Google Scholar
CertifHy (2015). Overview of the market segmentation for hydrogen across potential customer groups, based on key application areas. CertifyHy. Available at: www.certifhy.eu/images/D1_2_Overview_of_the_market_segmentation_Final_22_June_low-res.pdf.Google Scholar
Cetinkaya, E., Dincer, I. and Naterer, G. F. (2012). Life cycle assessment of various hydrogen production methods. International Journal of Hydrogen Energy, 37, 20712080.Google Scholar
Chapman, A., Itaoka, K., Hirose, K. et al. (2019). A review of four case studies assessing the potential for hydrogen penetration of the future energy system. International Journal of Hydrogen Energy, 44, 63716382.Google Scholar
Chen, T.-Y., Huang, D.-R. and Huang, A. Y.-J. (2016). An empirical study on the public perception and acceptance of hydrogen energy in Taiwan. International Journal of Green Energy, 13, 15791584.Google Scholar
Clean Energy Ministerial (2019). Hydrogen initiative: An initiative of the clean energy ministerial. Clean Energy Ministerial. Available at: www.cleanenergyministerial.org/initiative-clean-energy-ministerial/hydrogen-initiative.Google Scholar
COAG Energy Council Hydrogen Working Group (2019). Australia’s National Hydrogen Strategy. Canberra: COAG Energy Council. Available at: www.industry.gov.au/data-and-publications/australias-national-hydrogen-strategy.Google Scholar
Committee on Climate Change (2018). Hydrogen in a Low-Carbon Economy. London: Committee on Climate Change. Available at: www.theccc.org.uk/publication/hydrogen-in-a-low-carbon-economy.Google Scholar
Dalebrook, A. F., Gan, W., Grasemann, M., Moret, S. and Laurenczy, G. (2013). Hydrogen storage: Beyond conventional methods. Chemical Communications, 49, 87358751.Google Scholar
DNV-GL (2018). Hydrogen: Decarbonising heat. DNVGL.com. Available at: www.dnvgl.com/oilgas/natural-gas/hydrogen-decarbonizing-the-heat.html. Google Scholar
European Commission (2003). Hydrogen Energy and Fuel Cells: A Vision of Our Future. EUR Community Research 20719. Luxembourg: Office for Official Publications of the European Communities. Available at: www.fch.europa.eu/sites/default/files/documents/hlg_vision_report_en.pdf.Google Scholar
Feng, Y., Liu, Y. and Zhang, Y. (2015). Enhancement of sludge decomposition and hydrogen production from waste activated sludge in a microbial electrolysis cell with cheap electrodes. Environmental Science: Water Research and Technology, 1, 761768.Google Scholar
Floristean, A., Brahy, N. and Kraus, N. (2018). HyLAW: List of Legal Barriers. Available at: www.hylaw.eu/sites/default/files/2019-01/D4.2 - List of legal barriers.pdf.Google Scholar
Foh, S., Novil, M., Rockar, E. and Randolph, P. (1979). Underground Hydrogen Storage: Final Report [Salt Caverns, Excavated Caverns, Aquifers and Depleted Fields]. Chicago, IL: US Department of Energy and Environment. Available at: www.osti.gov/biblio/6536941.Google Scholar
Geißler, T., Abánades, A., Heinzel, A. et al. (2016). Hydrogen production via methane pyrolysis in a liquid metal bubble column reactor with a packed bed. Chemical Engineering Journal, 299, 192200.Google Scholar
Gillingham, K. and Sweeney, J. (2011). Market failure and the structure of externalities. In Moselle, B., Padilla, J. and Schmalensee, R., eds., Harnessing Renewable Energy in Electric Power Systems: Theory, Practice, Policy. Routledge, pp. 6992.Google Scholar
Global CCS Institute (2018). The Global Status of CCS 2018. Global CCS Institute. Available at: www.globalccsinstitute.com/resources/global-status-report/previous-reports/.Google Scholar
Hauch, A., Ebbesen, S. D., Jensen, S. H. and Mogensen, M. (2008). Highly efficient high temperature electrolysis. Journal of Materials Chemistry, 20, 23312340.Google Scholar
He, T., Pachfule, P., Wu, H., Xu, Q. and Chen, P. (2016). Hydrogen carriers. Nature Reviews Materials, 1, 117.Google Scholar
Hickson, A., Phillips, A. and Morales, G. (2007). Public perception related to a hydrogen hybrid internal combustion engine transit bus demonstration and hydrogen fuel. Energy Policy, 35, 22492255.Google Scholar
Huang, E. (2019). A hydrogen fueling station fire in Norway has left fuel-cell cars nowhere to charge. Quartz. 12 June. Available at: https://qz.com/1641276/a-hydrogen-fueling-station-explodes-in-norways-baerum/.Google Scholar
Hydrogen Council (2017). Hydrogen Scaling Up: A Sustainable Pathway for the Global Energy Transition. Hydrogen Council. Available at: https://hydrogencouncil.com/wp-content/uploads/2017/11/Hydrogen-scaling-up-Hydrogen-Council.pdf.Google Scholar
IEA (International Energy Agency) (2019a). Energy security. IEA.org. Available at: www.iea.org/topics/energysecurity.Google Scholar
IEA (2019b). IEA contribution to G20 energy in 2019. IEA.org. 28 June. Available at: www.iea.org/articles/iea-contribution-to-g20-energy-in-2019/.Google Scholar
IEA (2019c). IEA Hydrogen Technology Collaboration Program: Renewable Hydrogen Production. Paris: International Energy Agency.Google Scholar
IEA (2019d). The Future of Hydrogen. Paris: International Energy Agency. Available at: www.iea.org/reports/the-future-of-hydrogen.Google Scholar
International Standards Organization (2019). ISO/TC 197: Hydrogen technologies. ISO.org. Available at: www.iso.org/committee/54560.html.Google Scholar
IPCC (2018). Global Warming of 1.5 °C: An IPCC Special Report on the Impacts of Global Warming of 1.5 °C Above Pre-Industrial Levels and Related Global Greenhouse Gas Emission Pathways, in the Context of Strengthening the Global Response to the Threat of Climate Change, Sustainable Development, and Efforts to Eradicate Poverty. Edited by Masson-Delmotte, V., Zhai, P., Pörtner, H.-O. et al. Cambridge: Cambridge University Press. Available at: www.ipcc.ch/sr15/.Google Scholar
IPHE (International Partnership for Hydrogen and Fuel Cells in the Economy) (2019). International Partnership for Hydrogen and Fuel Cells in the Economy. Available at: www.iphe.net.Google Scholar
IRENA (International Renewable Energy Agency) (2018). Hydrogen from Renewable Power: Technology Outlook for the Energy Transition. Abu Dhabi: International Renewable Energy Agency. Available at: www.irena.org/publications/2018/Sep/Hydrogen-from-renewable-power.Google Scholar
IRENA (2019). Hydrogen: A Renewable Energy Perspective. Abu Dhabi: International Renewable Energy Agency. Available at: www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Sep/IRENA_Hydrogen_2019.pdf.Google Scholar
Itaoka, K., Saito, A. and Sasaki, K. (2017). Public perception on hydrogen infrastructure in Japan: Influence of rollout of commercial fuel cell vehicles. International Journal of Hydrogen Energy, 42, 72907296.Google Scholar
Jenkins, J. D. (2019). Why carbon pricing falls short and what can we do about it. Kleinman Center for Energy Policy. 24 April. Available at: https://kleinmanenergy.upenn.edu/policy-digests/why-carbon-pricing-falls-short.Google Scholar
Kosturjak, A., Dey, T., Young, M. D. and Whetton, S. (2019). Advancing Hydrogen: Learning from 19 Plans to Advance Hydrogen from Across the Globe. Future Fuels CRC. Available at: www.energynetworks.com.au/resources/reports/advancing-hydrogen-learning-from-19-plans-to-advance-hydrogen-from-across-the-globe-ffcrc/.Google Scholar
Lambert, V. and Ashworth, P. (2018). The Australian Public’s Perception of Hydrogen for Energy. Australian Renewable Energy Agency. Available at: https://arena.gov.au/assets/2018/12/the-australian-publics-perception-of-hydrogen-for-energy.pdf.Google Scholar
Melaina, M., Antonia, O. and Penev, M. (2013). Blending hydrogen into natural gas pipeline networks: A review of key issues. Contract, 303(March), 275300.Google Scholar
Meldrum, J., Nettles-Anderson, S., Heath, G. and Macknick, J. (2013). Life cycle water use for electricity generation: A review and harmonization of literature estimates. Environmental Research Letters, 8, 015031.Google Scholar
METI (Japanese Ministry of Economy, Trade and Industry) (2017). Basic Hydrogen Strategy. Ministerial Council on Renewable Energy, Hydrogen and Related Issues. Available at: www.meti.go.jp/english/press/2017/pdf/1226_003b.pdf.Google Scholar
Milbrandt, A. and Mann, M. (2009). Hydrogen Resource Assessment: Hydrogen Potential from Coal, Natural Gas, Nuclear, and Hydro Power. Technical report NREL/TP-560-42773. Golden, CO: National Renewable Energy Laboratory. Available at: www.nrel.gov/docs/fy09osti/42773.pdf.Google Scholar
Mission Innovation (2019a). IC8: Renewable and clean hydrogen. Mission Innovation. Available at: http://mission-innovation.net/our-work/innovation-challenges/renewable-and-clean-hydrogen/.Google Scholar
Mission Innovation (2019b). Overview. Mission Innovation. Available at: http://mission-innovation.net/about-mi/overview/.Google Scholar
Muradov, N. (2017). Low to near-zero CO2 production of hydrogen from fossil fuels: Status and perspectives. International Journal of Hydrogen Energy, 42, 1405814088.Google Scholar
National Academies of Sciences Engineering and Medicine (2016). Sustainable alternative jet fuels. In Commercial Aircraft Propulsion and Energy Systems Research: Reducing Global Carbon Emissions. Washington, DC: The National Academies Press.Google Scholar
Olea, R. A. (2015). CO2 retention values in enhanced oil recovery. Journal of Petroleum Science and Engineering, 129, 2328.Google Scholar
Preuster, P., Papp, C. and Wasserscheid, P. (2017). Liquid organic hydrogen carriers (LOHCs): Toward a hydrogen-free hydrogen economy. Accounts of Chemical Research, 50, 7485.Google Scholar
Rodrik, D. (2004). Industrial Policy for the Twenty-First Century. CEPR Discussion Papers No. 4767. London: Centre for Economic Policy Research.Google Scholar
Schmidt, A. and Donsbach, W. (2016). Acceptance factors of hydrogen and their use by relevant stakeholders and the media. International Journal of Hydrogen Energy, 41, 45094520.Google Scholar
Schmidt, O., Gambhir, A., Staffell, I., Hawkes, A., Nelson, J. and Few, S. (2017). Future cost and performance of water electrolysis: An expert elicitation study. International Journal of Hydrogen Energy, 42, 3047030492.Google Scholar
Shaner, M. R., Atwater, H. A., Lewis, N. S. and McFarland, E. W. (2016). A comparative technoeconomic analysis of renewable hydrogen production using solar energy. Energy & Environmental Science, 9, 23542371.Google Scholar
Sheffield, J. W. and Sheffield, Ç., eds. (2007). Assessment of Hydrogen Energy for Sustainable Development. NATO Science for Peace and Security Series C: Environmental Security. Dordrecht: Springer Netherlands.Google Scholar
Vogl, V., Åhman, M. and Nilsson, L. J. (2018). Assessment of hydrogen direct reduction for fossil-free steelmaking. Journal of Cleaner Production, 203, 736745.Google Scholar
Weger, L., Abánades, A. and Butler, T. (2017). Methane cracking as a bridge technology to the hydrogen economy. International Journal of Hydrogen Energy, 42, 720731.Google Scholar
Zimmer, R. and Welke, J. (2012). Let’s go green with hydrogen! The general public’s perspective. International Journal of Hydrogen Energy, 37, 1750217508.Google Scholar

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