This image shows the riparian community woodlands along the lower Tuolumne River near Merced, California. The dry grassland in the background indicates the semi-arid conditions and drought environment.
A study of woodland ecosystems that provide habitat for rare and endangered species along streams and rivers throughout California reveals that some of these ecologically important areas are inadvertently benefitting from water that humans are diverting for their own needs. Though it seems a short-term boon to these ecosystems, the artificial supply creates an unintended dependence on its bounty, threatens the long-term survival of natural communities and spotlights the need for changes in the way water is managed across the state.
“We need to be more intentional in incorporating ecosystem water needs when we manage water—both for aquatic organisms and species on land,” said Melissa Rohde, the lead author of a study published in June in the Proceedings of the National Academy of Sciences (PNAS). “These forest ecosystems are in a precarious state because we have disrupted the natural hydrologic processes that these plant species rely upon to support and sustain key life processes.”
In California’s seasonally dry Mediterranean climate, plants and animals are adapted to rely on precipitation and soil moisture recharge during the rainy winter and spring seasons for reproduction and growth during the typically dry summers. Once soil moisture is exhausted, tree species often found in stream corridors such as willows, cottonwoods and oaks, typically use groundwater from deeper depths. However, as Rohde, who led the study as a Ph.D. candidate at ESF and scientist with The Nature Conservancy of California, and her colleagues discovered, the story was more complicated.
By analyzing five years of vegetation greenness data from satellite imagery, the researchers found that in some cases, these ecosystems were affected by “subsidies of water” delivered via human regulation of rivers, agricultural canals and discharges from wastewater treatment plants. That discovery, Rohde said, was a “mind bender.” Altered streamside woodlands in the most arid regions of the state stayed greener longer into the dry season and were less responsive to changes in groundwater levels than natural ecosystems.
Many of the most-altered stream ecosystems are in California’s Central Valley, the state’s agricultural hub, which produces a third of the produce for the United States. Since the Gold Rush in the 1850s, the massive human settlement that followed led to clearing of 95 percent of the natural floodplain woodlands across the region. These isolated and restricted riparian — or streamside — forests, now provide important habitat for threatened and endangered species.
As water is rerouted from rivers into canals to accommodate urbanization and the multibillion-dollar agricultural industry, it creates an artificially stable environment for riparian woodland ecosystems and a “live fast, die young” phenomenon favoring fast-growing trees that peak and then decline within a few decades. But other key ecosystem functions, such as the regeneration of new forest stands and their development over time, are being compromised by the extensive alterations to streamflow and to river channels, which are fixed in place and no longer create new floodplain areas where young trees can establish.
Rohde said she and TNC will use the insights from the study to provide scientific guidance to California natural resource agencies for sustainably managing groundwater-dependent ecosystems throughout the state.
The research team conducted the PNAS study using publicly available online data and Google Earth Engine, an open-source tool for analyzing data from satellites and other global spatial datasets. “Our methods and findings open up a whole new world of interdisciplinary research possibilities and ways that water practitioners can consider ecosystem water needs to achieve sustainable water management,” Rohde said.
John Stella, an ESF professor and Rohde’s Ph.D. advisor, is the principal investigator on the National Science Foundation grant that funded the study. Other collaborators and authors on the paper are Dar Roberts of the University of California at Santa Barbara (UCSB) and Michael Singer, who has an affiliation at UCSB and at Cardiff University in the United Kingdom. Stella noted that this study is part of a $2.5 million suite of projects that he and these collaborators at UCSB and Cardiff have currently funded throughout the U.S. Southwest and France to develop water stress indicators for dryland riparian forest ecosystems threatened by climate change and increasing human water demand.
Claire B. Dunn is a writer and director emeritus of the ESF Office of Communications and Marketing.