A multi-model framework for assessing long- and short-term climate influences on the electric grid

Stuart M. Cohen; Ana Dyreson; Sean Turner; Vince Tidwell; Nathalie Voisin; Ariel Miara

doi:10.1016/j.apenergy.2022.119193

A multi-model framework for assessing long- and short-term climate influences on the electric grid

Stuart M. Cohen, Ana Dyreson, Sean Turner, Vince Tidwell, Nathalie Voisin, Ariel Miara

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

Climate change influences many aspects of the electric grid, but prior work and industry practices often ignore the potential effects of changing climate, or they only consider a single effect or individual effects in isolation. Challenges vary with each grid and include adapting to long-term trends such as changing temperature and precipitation or shorter-term events such as drought or storms that could increase in frequency or intensity. Here we present a multi-model framework designed to analyze the effects of long and short-term climate impacts in combination. This framework couples capacity expansion and production cost models with hydrologic models and future climate scenario data to analyze alternative climate and energy futures at high spatial, temporal, and process resolutions. We constructed and evaluated the results of a suite of simulated scenarios exploring climate impacts on capacity investment and stress-tested the resulting future infrastructures using hourly dispatch modeling under alternative drought and load conditions. We demonstrate the approach through a case study of the U.S. Western Interconnection, where climate impacts depend on interactions between temperature-induced load, water availability for hydropower, technology competitiveness, and demand flexibility. Changes in 2038 generating capacity range from −8.5–16.6 GW, and changes in 2038 transmission capacity range from −1–2 GW. Capacity increases are driven by higher load from higher temperatures, while capacity reductions can be achieved in scenarios with higher future hydropower availability and increased demand flexibility. Scenarios requiring additional capacity cost an additional $5–$17 billion (discounted) from 2018 to 2038; however, scenarios with capacity reductions cost $1–$18 billion less. Stress tests on four 2038 infrastructures demonstrated that the identified systems were able to serve at least 99.999% of load and 99.96% of reserves. However, drought and unexpected high-load conditions can result in reduced capacity to respond to contingency events we did not model. Although these results are system and scenario specific, they highlight the importance of considering multiple climate change impacts simultaneously in long-term planning efforts and demonstrate a multi-model, multiscale approach that can be flexibly applied to any system and set of climate change concerns.

Original language	English
Article number	119193
Journal	Applied Energy
Volume	317
DOIs	https://doi.org/10.1016/j.apenergy.2022.119193
State	Published - Jul 1 2022
Externally published	Yes

Funding

This work was authored in part by the National Renewable Energy Laboratory, operated by Alliance for Sustainable Energy, LLC, for the U.S. Department of Energy (DOE) under Contract No. DE-AC36-08GO28308. Funding was provided by the U.S. Department of Energy, Office of Electricity - Electricity Delivery Division under Subcontract 1968666 to Sandia National Laboratories as part of the “Energy and Water Modeling in the Western and Texas Interconnects” project. The views expressed in the article do not necessarily represent the views of the DOE or the U.S. Government. The U.S. Government retains and the publisher, by accepting the article for publication, acknowledges that the U.S. Government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this work, or allow others to do so, for U.S. Government purposes. This work was authored in part by the National Renewable Energy Laboratory, operated by Alliance for Sustainable Energy, LLC, for the U.S. Department of Energy (DOE) under Contract No. DE-AC36-08GO28308. Funding was provided by the U.S. Department of Energy, Office of Electricity - Electricity Delivery Division under Subcontract 1968666 to Sandia National Laboratories as part of the “Energy and Water Modeling in the Western and Texas Interconnects” project. The views expressed in the article do not necessarily represent the views of the DOE or the U.S. Government. The U.S. Government retains and the publisher, by accepting the article for publication, acknowledges that the U.S. Government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this work, or allow others to do so, for U.S. Government purposes.

Keywords

Climate change
Drought
Electricity
Electricity planning
Grid operations
Hydrology

Access to Document

10.1016/j.apenergy.2022.119193

Cite this

@article{e12269b21da540d3bfa802fc7342e9a6,

title = "A multi-model framework for assessing long- and short-term climate influences on the electric grid",

abstract = "Climate change influences many aspects of the electric grid, but prior work and industry practices often ignore the potential effects of changing climate, or they only consider a single effect or individual effects in isolation. Challenges vary with each grid and include adapting to long-term trends such as changing temperature and precipitation or shorter-term events such as drought or storms that could increase in frequency or intensity. Here we present a multi-model framework designed to analyze the effects of long and short-term climate impacts in combination. This framework couples capacity expansion and production cost models with hydrologic models and future climate scenario data to analyze alternative climate and energy futures at high spatial, temporal, and process resolutions. We constructed and evaluated the results of a suite of simulated scenarios exploring climate impacts on capacity investment and stress-tested the resulting future infrastructures using hourly dispatch modeling under alternative drought and load conditions. We demonstrate the approach through a case study of the U.S. Western Interconnection, where climate impacts depend on interactions between temperature-induced load, water availability for hydropower, technology competitiveness, and demand flexibility. Changes in 2038 generating capacity range from −8.5–16.6 GW, and changes in 2038 transmission capacity range from −1–2 GW. Capacity increases are driven by higher load from higher temperatures, while capacity reductions can be achieved in scenarios with higher future hydropower availability and increased demand flexibility. Scenarios requiring additional capacity cost an additional $5–$17 billion (discounted) from 2018 to 2038; however, scenarios with capacity reductions cost $1–$18 billion less. Stress tests on four 2038 infrastructures demonstrated that the identified systems were able to serve at least 99.999% of load and 99.96% of reserves. However, drought and unexpected high-load conditions can result in reduced capacity to respond to contingency events we did not model. Although these results are system and scenario specific, they highlight the importance of considering multiple climate change impacts simultaneously in long-term planning efforts and demonstrate a multi-model, multiscale approach that can be flexibly applied to any system and set of climate change concerns.",

keywords = "Climate change, Drought, Electricity, Electricity planning, Grid operations, Hydrology",

author = "Cohen, {Stuart M.} and Ana Dyreson and Sean Turner and Vince Tidwell and Nathalie Voisin and Ariel Miara",

note = "Publisher Copyright: {\textcopyright} 2022 Elsevier Ltd",

year = "2022",

month = jul,

day = "1",

doi = "10.1016/j.apenergy.2022.119193",

language = "English",

volume = "317",

journal = "Applied Energy",

issn = "0306-2619",

publisher = "Elsevier",

}

TY - JOUR

T1 - A multi-model framework for assessing long- and short-term climate influences on the electric grid

AU - Cohen, Stuart M.

AU - Dyreson, Ana

AU - Turner, Sean

AU - Tidwell, Vince

AU - Voisin, Nathalie

AU - Miara, Ariel

PY - 2022/7/1

Y1 - 2022/7/1

N2 - Climate change influences many aspects of the electric grid, but prior work and industry practices often ignore the potential effects of changing climate, or they only consider a single effect or individual effects in isolation. Challenges vary with each grid and include adapting to long-term trends such as changing temperature and precipitation or shorter-term events such as drought or storms that could increase in frequency or intensity. Here we present a multi-model framework designed to analyze the effects of long and short-term climate impacts in combination. This framework couples capacity expansion and production cost models with hydrologic models and future climate scenario data to analyze alternative climate and energy futures at high spatial, temporal, and process resolutions. We constructed and evaluated the results of a suite of simulated scenarios exploring climate impacts on capacity investment and stress-tested the resulting future infrastructures using hourly dispatch modeling under alternative drought and load conditions. We demonstrate the approach through a case study of the U.S. Western Interconnection, where climate impacts depend on interactions between temperature-induced load, water availability for hydropower, technology competitiveness, and demand flexibility. Changes in 2038 generating capacity range from −8.5–16.6 GW, and changes in 2038 transmission capacity range from −1–2 GW. Capacity increases are driven by higher load from higher temperatures, while capacity reductions can be achieved in scenarios with higher future hydropower availability and increased demand flexibility. Scenarios requiring additional capacity cost an additional $5–$17 billion (discounted) from 2018 to 2038; however, scenarios with capacity reductions cost $1–$18 billion less. Stress tests on four 2038 infrastructures demonstrated that the identified systems were able to serve at least 99.999% of load and 99.96% of reserves. However, drought and unexpected high-load conditions can result in reduced capacity to respond to contingency events we did not model. Although these results are system and scenario specific, they highlight the importance of considering multiple climate change impacts simultaneously in long-term planning efforts and demonstrate a multi-model, multiscale approach that can be flexibly applied to any system and set of climate change concerns.

AB - Climate change influences many aspects of the electric grid, but prior work and industry practices often ignore the potential effects of changing climate, or they only consider a single effect or individual effects in isolation. Challenges vary with each grid and include adapting to long-term trends such as changing temperature and precipitation or shorter-term events such as drought or storms that could increase in frequency or intensity. Here we present a multi-model framework designed to analyze the effects of long and short-term climate impacts in combination. This framework couples capacity expansion and production cost models with hydrologic models and future climate scenario data to analyze alternative climate and energy futures at high spatial, temporal, and process resolutions. We constructed and evaluated the results of a suite of simulated scenarios exploring climate impacts on capacity investment and stress-tested the resulting future infrastructures using hourly dispatch modeling under alternative drought and load conditions. We demonstrate the approach through a case study of the U.S. Western Interconnection, where climate impacts depend on interactions between temperature-induced load, water availability for hydropower, technology competitiveness, and demand flexibility. Changes in 2038 generating capacity range from −8.5–16.6 GW, and changes in 2038 transmission capacity range from −1–2 GW. Capacity increases are driven by higher load from higher temperatures, while capacity reductions can be achieved in scenarios with higher future hydropower availability and increased demand flexibility. Scenarios requiring additional capacity cost an additional $5–$17 billion (discounted) from 2018 to 2038; however, scenarios with capacity reductions cost $1–$18 billion less. Stress tests on four 2038 infrastructures demonstrated that the identified systems were able to serve at least 99.999% of load and 99.96% of reserves. However, drought and unexpected high-load conditions can result in reduced capacity to respond to contingency events we did not model. Although these results are system and scenario specific, they highlight the importance of considering multiple climate change impacts simultaneously in long-term planning efforts and demonstrate a multi-model, multiscale approach that can be flexibly applied to any system and set of climate change concerns.

KW - Climate change

KW - Drought

KW - Electricity

KW - Electricity planning

KW - Grid operations

KW - Hydrology

UR - http://www.scopus.com/inward/record.url?scp=85129593193&partnerID=8YFLogxK

U2 - 10.1016/j.apenergy.2022.119193

DO - 10.1016/j.apenergy.2022.119193

M3 - Article

AN - SCOPUS:85129593193

SN - 0306-2619

VL - 317

JO - Applied Energy

JF - Applied Energy

M1 - 119193

ER -

A multi-model framework for assessing long- and short-term climate influences on the electric grid

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Cite this