Power System Decarbonization: Impacts of Energy Storage Duration and Interannual Renewables Variability

Decarbonization of the electricity sector is one of the major measures in slowing down the pace of climate change. In this paper, we analyze the impacts of energy storage systems (ESS) and interannual uncertainty of variable renewable energy (VRE) on power system decarbonization in 2050. We perform capacity expansion optimization based on technology cost projections and CO2 emission restrictions using 11 years of VRE and load data in Italy's power system, with a particular focus on the role of ESS and its duration. We also explore capacity expansion optimization based on multiple-year vs. single-year data to quantify the impact of VRE interannual variability. Our results indicate high renewables penetration even in the absence of decarbonization policies. In the transition to zero carbon system, CCS plays a minor role due to its carbon capture efficiency. ESS investments contribute to lower system costs by replacing more expensive flexibility resources. However, longer ESS durations have lower marginal value per added kWh ESS. Interannual variability of VRE substantially changes the system's configuration and energy cost. Decision-making based on single-year data substantially increases the systems' operational costs in other years. In contrast, optimizing over multiple years provides a more robust and cost effective generation expansion strategy.

[1]  Robert Margolis,et al.  Utility-scale lithium-ion storage cost projections for use in capacity expansion models , 2016, 2016 North American Power Symposium (NAPS).

[2]  M. Ha-Duong,et al.  Climate change 2014 - Mitigation of climate change , 2015 .

[3]  Birgit Fais,et al.  Designing low-carbon power systems for Great Britain in 2050 that are robust to the spatiotemporal and inter-annual variability of weather , 2018 .

[4]  S. Pfenninger,et al.  Long-term patterns of European PV output using 30 years of validated hourly reanalysis and satellite data , 2016 .

[5]  Audun Botterud,et al.  The value of energy storage in decarbonizing the electricity sector , 2016 .

[6]  Paul Denholm,et al.  Timescales of energy storage needed for reducing renewable energy curtailment , 2019, Renewable Energy.

[7]  S. Pfenninger,et al.  Using bias-corrected reanalysis to simulate current and future wind power output , 2016 .

[8]  Rita Pongrácz,et al.  A brief review of health-related issues occurring in urban areas related to global warming of 1.5°C , 2018 .

[9]  Xiaodong Liang,et al.  Emerging Power Quality Challenges Due to Integration of Renewable Energy Sources , 2016, IEEE Transactions on Industry Applications.

[10]  J. Trancik,et al.  Value of storage technologies for wind and solar energy , 2016 .

[11]  Masato Takagi,et al.  The cost of CO2 capture and storage , 2016 .

[12]  B. Ó. Gallachóir,et al.  Informing Energy and Climate Policies Using Energy Systems Models , 2015 .

[13]  Brian Ó Gallachóir,et al.  Soft-linking of a power systems model to an energy systems model , 2012 .

[14]  Duration Addition to electricitY Storage (DAYS) Overview , 2018 .

[15]  Jinyu Wen,et al.  Power System Capacity Expansion Under Higher Penetration of Renewables Considering Flexibility Constraints and Low Carbon Policies , 2018, IEEE Transactions on Power Systems.

[16]  Michael Milligan,et al.  Operating Reserves and Variable Generation , 2011 .

[17]  Nouredine Hadjsaid,et al.  Storage as a flexibility option in power systems with high shares of variable renewable energy sources: a POLES-based analysis , 2017 .

[18]  Magnus Korpås,et al.  Impact of Offshore Wind Power on System Adequacy in a Regional Hydro-based Power System with Weak Interconnections , 2012 .

[19]  E. Pyrgioti,et al.  Wide scale penetration of renewable electricity in the Greek energy system in view of the European decarbonization targets for 2050 , 2015 .

[20]  Jesse D. Jenkins,et al.  The Role of Firm Low-Carbon Electricity Resources in Deep Decarbonization of Power Generation , 2018, Joule.

[21]  Lucia Gauchia,et al.  Deterministic models of Li-ion battery aging: It is a matter of scale , 2018, Journal of Energy Storage.

[22]  Fikile R. Brushett,et al.  Air-Breathing Aqueous Sulfur Flow Battery for Ultralow-Cost Long-Duration Electrical Storage , 2017 .

[23]  M. Fowler,et al.  Benchmarking and selection of Power-to-Gas utilizing electrolytic hydrogen as an energy storage alternative , 2016 .

[24]  Robert J. Brecha,et al.  Analyzing Major Challenges of Wind and Solar Variability in Power Systems , 2014 .

[25]  Barack Obama,et al.  The irreversible momentum of clean energy , 2017, Science.

[26]  Christian Breyer,et al.  Flexible electricity generation, grid exchange and storage for the transition to a 100% renewable energy system in Europe , 2019, Renewable Energy.

[27]  Magnus Korpås,et al.  Opportunities for hydrogen production in connection with wind power in weak grids , 2008 .

[28]  G. Luderer,et al.  Assessment of wind and solar power in global low-carbon energy scenarios: An introduction , 2017 .

[29]  Jack Brouwer,et al.  Impact of hydrogen energy storage on California electric power system: Towards 100% renewable electricity , 2019, International Journal of Hydrogen Energy.

[30]  Ying Shirley Meng,et al.  Combined economic and technological evaluation of battery energy storage for grid applications , 2018, Nature Energy.

[31]  A. Arneth,et al.  Framing and Context , 2019 .

[32]  Merlinde Kay,et al.  Battery energy storage system size determination in renewable energy systems: A review , 2018, Renewable and Sustainable Energy Reviews.

[33]  Audun Botterud,et al.  Improved Energy Arbitrage Optimization with Detailed Flow Battery Characterization , 2019, 2019 IEEE Power & Energy Society General Meeting (PESGM).

[34]  Omar J. Guerra,et al.  A review of the potential impacts of climate change on bulk power system planning and operations in the United States , 2018, Renewable and Sustainable Energy Reviews.

[35]  Thomas A. Buscheck,et al.  The value of bulk energy storage for reducing CO2 emissions and water requirements from regional electricity systems , 2019, Energy Conversion and Management.

[36]  Peng Hu,et al.  A novel isobaric adiabatic compressed air energy storage (IA-CAES) system on the base of volatile fluid , 2018 .

[37]  Daniel M. Kammen,et al.  Power system balancing for deep decarbonization of the electricity sector , 2016 .

[38]  Jesse D. Jenkins,et al.  Enhanced Decision Support for a Changing Electricity Landscape : The GenX Configurable Electricity Resource Capacity Expansion Model Revision 1 . 0 , 2017 .

[39]  Gang Xu,et al.  Development forecast of renewable energy power generation in China and its influence on the GHG control strategy of the country , 2011 .

[40]  Danae Diakoulaki,et al.  A decomposition analysis of the driving factors of CO2 (Carbon dioxide) emissions from the power sector in the European Union countries , 2016 .

[41]  J. P. Deane,et al.  Assessing power system security. A framework and a multi model approach , 2015 .

[42]  F. Graf,et al.  Renewable Power-to-Gas: A technological and economic review , 2016 .

[43]  W. Winiwarter,et al.  EU Reference Scenario 2016 - Energy, transport and GHG emissions Trends to 2050. , 2016 .

[44]  S. Pfenninger,et al.  Impacts of Inter-annual Wind and Solar Variations on the European Power System , 2018, Joule.