Wine grapes are susceptible to subtle changes in temperature and precipitation, making them particularly vulnerable to the effects of climate change.
Regenerative agriculture, which uses holistic farming and grazing practices to strengthen soil health and crop productivity, may help grape vines become more resilient to changing climate conditions. However, more research is needed to increase adoption of regenerative agriculture practices on vineyards.
The (FFAR) awarded a $999,003 grant to the University of California, Davis to assess the effects of regenerative practices on vineyard soil health. provided matching funds for a $2.6 million total investment.
Regenerative agriculture can help sequester atmospheric carbon dioxide as soil organic matter, playing a key role in climate change mitigation. Regenerative agriculture proposes the “stacking” of well-known soil conservation practices, such as compost, no-till and cover crops, to take advantage of synergies and maximize benefits to soil health. This technique often includes reintegrating crop and livestock production. For wine grapes, that typically involves bringing sheep to vineyards.
However, the impact of soil health practices on vineyards remains difficult to predict due to various factors, including management strategies, climate and soil type, all of which can influence carbon sequestration potential.
Building soil carbon and soil health
Led by at ٺƵ, a multidisciplinary team of researchers from ٺƵ, , is examining how well regenerative agriculture can build soil carbon and soil health in vineyards and its effects on crop yield, grape and wine quality.
“Woody perennial crops like wine grapes have large potential to sequester carbon and mitigate climate change,” said Lazcano, an associate professor in the ٺƵ Department of Land, Air and Water Resources. “Because of this, the wine grape industry is uniquely positioned to spearhead efforts in regenerative agricultural management. We are proud to contribute to the development of science-based best management practices to support the sustainability efforts of the wine grape industry.”
Lazcano and team are establishing reliable sampling methods to determine changes in soil carbon abundance within vineyards. The team is examining the relationship between historical soil management and soil carbon to estimate the carbon abatement potential of regenerative management in vineyards of the U.S. West Coast. They are also assessing the effects of regenerative practices in a series of 12 controlled field trials stretching from Oregon’s Willamette Valley to Santa Barbara, California.
This research aims to provide farmers with an in-depth understanding of how soil management practices drive soil carbon sequestration while connecting the dots between changes in soil carbon, soil health and grape quality.
Media Resources
Kat Kerlin, ٺƵ News and Media Relations, 530-750-9195, kekerlin@ucdavis.edu