When it doesn’t rain enough in the rainforest

In 2018, Ketchikan, ֱֻ, received 100 inches of rain. It was deep in a drought.

Compare that to Las Vegas, with its measly four inches of annual rainfall, or California’s Central Valley, with 20 inches. It’s hard to imagine that 100 inches of rain could cause concern.

Yet, from 2016-2019, Southeast ֱֻ experienced drinking water shortages, insect outbreaks, low hydroelectric output and more wildfire than usual.

Low water exposes the banks of a reservoir near Ketchikan during the drought.
Photo by Jeremy Bynum
Low water exposes the banks of a reservoir near Ketchikan during the drought.

No exact amount of low precipitation triggers a drought; instead, it results when drier-than-normal conditions last long enough to affect the local environment and people. Impacts can become more severe when soil and vegetation dry out from a combination of low precipitation, warm temperatures, wind and sunshine.  

High evaporation in summer 2019 was one factor that contributed to an “extreme drought” declaration by the , a tracking system operated by federal agencies and university research partners. Southeast ֱֻ had never before reached that drought intensity.

Scientists at the ֱֻ and the National Oceanic and Atmospheric Administration are studying this drought, its causes and impacts, and the likelihood of future similar droughts. The Southeast ֱֻ Drought Project is a partnership between Rick Thoman, at UAF’s ֱֻ Center for Climate Assessment and Policy, Heather McFarland at UAF’s International Arctic Research Center, Andrew Hoell at NOAA’s Physical Sciences Laboratory and Britt Parker at NOAA’s National Integrated Drought Information System.

The team found that an unusual lack of storms contributed to the Southeast ֱֻ drought. Storms typically originate over the Aleutian Islands, traveling along a reliable track that brings moist air to Southeast ֱֻ, especially in winter. During the drought years from 2016 to 2019, that pattern changed. Storms were “blocked” from the region by unusually high pressure over the Aleutian Islands. In the absence of those storms, Southeast ֱֻ experienced extended periods of dry and sunny weather. 

Though Southeast ֱֻ has seen dry spells in the past, including a short drought in 2004 and a longer one in the 1990s, the 2016-2019 drought followed a decade of much wetter conditions. This made the drought particularly jarring to those experiencing it. Low reservoir levels triggered water restrictions and a shift from hydroelectric to diesel-generated power in communities across the region. 

Humans weren’t the only ones who struggled to adapt to the drought. Southeast’s rainforest is well adapted to persistently wet conditions, and many local plants and animals don’t respond well to dryness. During the drought, residents reported low berry production, the Tongass National Forest saw almost twice as many wildfires, and insects damaged over half a million acres of rainforest. 

While the 2016-2019 drought is still a recent memory, it’s important to know whether this kind of event will happen again in the future. Thoman and Hoell used climate models to show that by 2050 Southeast ֱֻ is likely to get slightly wetter and a lot warmer. They also found that the chance of a drought like the 2016-2019 occurring again is declining, but drought is still possible in a rainforest even in a warming and wetting world.

Learn more about the Southeast ֱֻ Drought Project through a series of two-pagers on drought , , and

This project was funded by the NOAA National Integrated Drought Information System with additional support from the UAF ֱֻ Center for Climate Assessment and Policy, NOAA Award NA16OAR4310162.

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