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Utility-scale photovoltaics and storage: Decarbonizing and reducing greenhouse gases abatement costs

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  • Virguez, Edgar
  • Wang, Xianxun
  • Patiño-Echeverri, Dalia

Abstract

This study explores the performance of the Duke Energy Carolinas/Progress (DEC/DEP) electric power system under one hundred forty-one configurations combining different capacities of utility-scale photovoltaics (PV) and battery energy storage (lithium-ion batteries or BES). The different configurations include PV installations capable of providing 5–25% of the systems energy and batteries with varying duration (energy-to-power ratio) of 2, 4, and 6 h. A production cost model comprised of a day-ahead unit commitment and a real-time economic dispatch simulates the optimal operation of all the generation resources necessary to supply hourly demand and reserve requirements during the year 2016. The model represents in detail the generation fleet of the system, including 221 nuclear, natural gas, coal and hydro power generators with a combined installed capacity of 37.8 GW. Results indicate that: 1) adding BES to a power system that includes PV further reduces carbon dioxide emissions while also lowering the cost of carbon abatement. 2) The optimal power rating of a BES system that supports PV seems to be lower than 25% of the capacity of the PV. 3) BES of short duration (2-h) are more cost-effective (i.e., result in a lower cost of abatement) when the level of PV penetration is low (lower than ~12.5%), while BES of longer duration (6-h) are more cost-effective when there are larger shares of PV. 4) The installation of optimal configurations of PV + BES to reduce carbon emissions in the DEC/DEP system by ~14–57% would increase the levelized cost of electricity (LCOE) ~8–65%. 5) If projections of declining costs for the next decade materialize, the installation of up to 15 GW of PV + 1.88 GW / 3.76 GWh of BES would reduce the LCOE while achieving up to 33% reduction in carbon emissions.

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  • Virguez, Edgar & Wang, Xianxun & Patiño-Echeverri, Dalia, 2021. "Utility-scale photovoltaics and storage: Decarbonizing and reducing greenhouse gases abatement costs," Applied Energy, Elsevier, vol. 282(PA).
    • Handle: RePEc:eee:appene:v:282:y:2021:i:pa:s0306261920315385
    DOI: 10.1016/j.apenergy.2020.116120
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    as
    1. Kavlak, Goksin & McNerney, James & Trancik, Jessika E., 2018. "Evaluating the causes of cost reduction in photovoltaic modules," Energy Policy, Elsevier, vol. 123(C), pages 700-710.
    2. Marcucci, Adriana & Panos, Evangelos & Kypreos, Socrates & Fragkos, Panagiotis, 2019. "Probabilistic assessment of realizing the 1.5 °C climate target," Applied Energy, Elsevier, vol. 239(C), pages 239-251.
    3. Jenkins, J.D. & Zhou, Z. & Ponciroli, R. & Vilim, R.B. & Ganda, F. & de Sisternes, F. & Botterud, A., 2018. "The benefits of nuclear flexibility in power system operations with renewable energy," Applied Energy, Elsevier, vol. 222(C), pages 872-884.
    4. Jacobson, Mark Z. & Delucchi, Mark A. & Ingraffea, Anthony R. & Howarth, Robert W. & Bazouin, Guillaume & Bridgeland, Brett & Burkart, Karl & Chang, Martin & Chowdhury, Navid & Cook, Roy & Escher, Giu, 2014. "A roadmap for repowering California for all purposes with wind, water, and sunlight," Energy, Elsevier, vol. 73(C), pages 875-889.
    5. Becker, Sarah & Frew, Bethany A. & Andresen, Gorm B. & Zeyer, Timo & Schramm, Stefan & Greiner, Martin & Jacobson, Mark Z., 2014. "Features of a fully renewable US electricity system: Optimized mixes of wind and solar PV and transmission grid extensions," Energy, Elsevier, vol. 72(C), pages 443-458.
    6. Frew, Bethany A. & Becker, Sarah & Dvorak, Michael J. & Andresen, Gorm B. & Jacobson, Mark Z., 2016. "Flexibility mechanisms and pathways to a highly renewable US electricity future," Energy, Elsevier, vol. 101(C), pages 65-78.
    7. Davis, Steven J & Lewis, Nathan S. & Shaner, Matthew & Aggarwal, Sonia & Arent, Doug & Azevedo, Inês & Benson, Sally & Bradley, Thomas & Brouwer, Jack & Chiang, Yet-Ming & Clack, Christopher T.M. & Co, 2018. "Net-Zero Emissions Energy Systems," Institute of Transportation Studies, Working Paper Series qt7qv6q35r, Institute of Transportation Studies, UC Davis.
    8. Cornelius, Adam & Bandyopadhyay, Rubenka & Patiño-Echeverri, Dalia, 2018. "Assessing environmental, economic, and reliability impacts of flexible ramp products in MISO's electricity market," Renewable and Sustainable Energy Reviews, Elsevier, vol. 81(P2), pages 2291-2298.
    9. Denholm, Paul & Hand, Maureen, 2011. "Grid flexibility and storage required to achieve very high penetration of variable renewable electricity," Energy Policy, Elsevier, vol. 39(3), pages 1817-1830, March.
    10. Kern, Jordan D. & Patino-Echeverri, Dalia & Characklis, Gregory W., 2014. "An integrated reservoir-power system model for evaluating the impacts of wind integration on hydropower resources," Renewable Energy, Elsevier, vol. 71(C), pages 553-562.
    11. Bradbury, Kyle & Pratson, Lincoln & Patiño-Echeverri, Dalia, 2014. "Economic viability of energy storage systems based on price arbitrage potential in real-time U.S. electricity markets," Applied Energy, Elsevier, vol. 114(C), pages 512-519.
    12. Noah Kittner & Felix Lill & Daniel M. Kammen, 2017. "Energy storage deployment and innovation for the clean energy transition," Nature Energy, Nature, vol. 2(9), pages 1-6, September.
    13. Alqahtani, Bandar Jubran & Patiño-Echeverri, Dalia, 2019. "Combined effects of policies to increase energy efficiency and distributed solar generation: A case study of the Carolinas," Energy Policy, Elsevier, vol. 134(C).
    14. Mileva, Ana & Johnston, Josiah & Nelson, James H. & Kammen, Daniel M., 2016. "Power system balancing for deep decarbonization of the electricity sector," Applied Energy, Elsevier, vol. 162(C), pages 1001-1009.
    15. Bandyopadhyay, Rubenka & Patiño-Echeverri, Dalia, 2016. "An alternate wind power integration mechanism: Coal plants with flexible amine-based CCS," Renewable Energy, Elsevier, vol. 85(C), pages 704-713.
    16. Sioshansi, Ramteen & Denholm, Paul & Jenkin, Thomas & Weiss, Jurgen, 2009. "Estimating the value of electricity storage in PJM: Arbitrage and some welfare effects," Energy Economics, Elsevier, vol. 31(2), pages 269-277, March.
    17. Daraeepour, Ali & Patino-Echeverri, Dalia & Conejo, Antonio J., 2019. "Economic and environmental implications of different approaches to hedge against wind production uncertainty in two-settlement electricity markets: A PJM case study," Energy Economics, Elsevier, vol. 80(C), pages 336-354.
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