Western US faces future of prolonged drought even with stringent emissions control

Southwestern North America can expect more of the extended, severe drought the area has experienced in the last two decades even under the mildest climate warming scenarios, new research finds, but curbing greenhouse gas emissions is still key to limiting severity

8 September 2021

Joint Release

Three maps of the contiguous United States show While the risk of intense single-year droughts increases as greenhouse gas emissions increase in the model results, the risk of multi-year droughts is high regardless of the emissions scenario, a new study found

While the risk of intense single-year droughts increases as greenhouse gas emissions increase in the model results, the risk of multi-year droughts is high regardless of the emissions scenario, according to a new study in Earth’s Future.
Credits: NOAA Climate Program Office / Hunter Allen and Anna Eshelman

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Contact information for the researchers:
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WASHINGTON—Seasonal summer rains have done little to offset drought conditions gripping the western United States, with California and Nevada seeing record July heat and moderate-to-exceptional drought according to the National Oceanic and Atmospheric Administration (NOAA). Now, new research is showing how drought in the region is expected to change in the future, providing stakeholders with crucial information for decision making.

The western United States is headed for prolonged drought conditions whether greenhouse gas emissions continue to climb or are aggressively reined in, according to the new study published in the, Earth’s Future, AGU’s peer-reviewed journal for interdisciplinary research on the past, present and future of our planet and its inhabitants.

However, the new study also showed the severity of acute, extreme drought events and the overall severity of prolonged drought conditions can be reduced with emissions-curbing efforts compared to a high-emissions future. This is important information for decision-makers considering two tools they can use to reduce climate impacts: Adaptation and mitigation.

Bar graphs compare risk of single-year and 21-year drought events under low, medium and high emissions senarios.

As greenhouse gas emissions increase and Earth’s temperature rises, new research forecasts the southwestern United States will become drier, with the risk of future soil moisture deficits increasing as emissions increase. From figure 8 of the new study.
Credits: NOAA Climate Program Office / Anna Eshelman

Adaptation is a term used by the scientific community and policymakers to describe policies that address impacts that will occur or are already occurring. For example, adaptation to rising sea levels might include relocating low-lying infrastructure. By contrast, mitigation—efforts to reduce the amount of greenhouse gases in the atmosphere—can limit the severity of future impacts or even prevent them from happening by limiting how much the climate changes. Switching to cleaner energy sources and reducing greenhouse warming-driven ice melt are examples of mitigation to sea level rise.

Rather than representing competing options, adaptation and mitigation can both be used to address climate impacts. This new research shows how the two can complement each other when it comes to drought.

“Mitigation has clear benefits for reducing the frequency and severity of single-year droughts,” said lead author Ben Cook, a research scientist at NASA’s Goddard Institute for Space Studies (GISS) and an adjunct associate research scientist at Columbia University. “We may have more of these 20-year drought periods, but if we can avoid the really sharp, short-term, extreme spikes, then that may be something that’s easier to adapt to.”

Turning to the Past to Understand the Future

Both acute single-year and prolonged multi-year droughts occur naturally due to variations in ocean currents, precipitation and other factors. But climate change is turning up the heat in addition to these natural variations, causing even more water to evaporate from plants and soil, resulting in increased dryness even in the absence of major precipitation deficits.

To understand the southwest’s vulnerability and tendency towards drought and the factors that contribute to it, the team selected the severe single-year drought of 2002 and the extended drought of 2000 to 2020 as examples of acute and prolonged droughts respectively. They then looked at how common these acute and prolonged droughts were, not only during the period of instrumental records, but also using reconstructed drought conditions stretching back more than a thousand years and state-of-the-art supercomputer simulations of the future.

The team reconstructed soil moisture from the years 800 to 1900 using tree ring data from the region. The thickness of tree rings varies due to the wetness or dryness of each year, providing scientists with a reliable way of estimating how much rain fell in a given year. For years after 1900, they used directly measured soil moisture values. To look at a range of possible futures, the team used data from the latest version of the Coupled Model Intercomparison Project, or CMIP6. CMIP6 is an ensemble of climate model simulations that provide climate change projections depending on a range of possible greenhouse gas emission scenarios, allowing scientists and policymakers to directly compare the impacts of different emissions policies. And under different emissions scenarios, drought behaves differently.

graph compares risk of single-year droughts during 21-year events under low, intermediate and high emissions senarios

In addition to single- and multi-year droughts alone, there’s also a risk of intense single-year droughts occurring within longer periods of drought. This risk increases as greenhouse gas emissions increase, according to the study.
Credits: NOAA Climate Program Office / Anna Eshelman

The southwestern United States has been prone to drought for millennia. But warming temperatures dry the soil further, and the region’s natural aridity becomes the backdrop for a higher risk of severe and prolonged droughts if greenhouse gas emissions continue to climb, said Kate Marvel, a research scientist at GISS and Columbia University.

“The paleoclimate record shows that this region is prone to drought,” she said. “There have been really, really severe droughts in the past: For instance, we know there were megadroughts in the 13th century. But against the backdrop of natural climate variability — the things the climate would do even without human influence — we are confident increases in greenhouse gases make the temperature rise, and we’re fairly confident that increases drought risk in this region.”

A Future Not Yet Set in Stone

Understanding that some amount of increased drought can be expected under high and low emission scenarios alike has implications for adaptation strategies like rationing water usage and changing agricultural practices. At the same time, the study’s finding that greenhouse emissions reductions still matter for extreme drought underscores the value of mitigation.

“The ongoing southwestern drought highlights the profound effects dry conditions have on people and the economy,” said Ko Barrett, senior advisor for climate in NOAA’s Office of Research and vice-chair of the Intergovernmental Panel on Climate Change’s Sixth Assessment Report. “The study clearly highlights the impact that greenhouse gas mitigation could have on the occurrence and severity of Southwestern drought. It is not too late to act and blunt impacts like severe Southwestern drought periods and short-term drought events.”

Marvel agreed. “There’s going to be a new normal regardless,” she said.  “There’s going to have to be some adaptation to a drier regional climate. But the degree of that adaptation – how often these droughts happen, what happens to the drought risk – that’s basically under our control.”

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Notes for Journalists:

This research study is open access. Download a PDF copy of the paper here. Neither the paper nor this press release is under embargo.

This study was led by scientists at NASA’s Goddard Institute for Space Studies (GISS) and funded by NOAA’s Climate Program Office and NASA’s Modeling, Analysis and Prediction (MAP) Program

Paper title:

“Uncertainties, Limits, and Benefits of Climate Change Mitigation for Soil Moisture Drought in Southwestern North America”

Authors:

  • I. Cook, NASA Goddard Institute for Space Studies, New York, NY, USA; and Lamont-Doherty Earth Observatory, Columbia University, Palisades, NY, USA
  • S. Mankin, Lamont-Doherty Earth Observatory, Columbia University, Palisades, NY, USA; and Department of Geography, Dartmouth College, Hanover, NH, USA
  • Williams, Lamont-Doherty Earth Observatory, Columbia University, Palisades, NY, USA; and Department of Geography, University of California, Los Angeles, Los Angeles, CA, USA
  • D. Marvel, NASA Goddard Institute for Space Studies, New York, NY, USA; and Center for Climate Systems Research, Columbia University, New York, NY, USA
  • E. Smerdon, Lamont-Doherty Earth Observatory, Columbia University, Palisades, NY, USA
  • Liu, Lamont-Doherty Earth Observatory, Columbia University, Palisades, NY, USA