Ground mounted agrivoltaics have minimal impact on grassland carbon-water cycling
Publish Time:2023-08-29
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A US-Spanish research team studied the ecological effect of a solar photovoltaic array located on a managed grassland plot using a hydraulic and soil hydrology model and field measurements. They found minimal effect on the plants’ carbon-water cycling, which they attributed to plant photosynthetic traits changing to take advantage of the dynamic shading under the panels.
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An international research group has investigated the impact of ground mounted solar plants on grassland plots and has found it has a negligible impact on grassland carbon-water cycling.
The scientists also sought to answer questions about water retention and grassland ecosystem resistance to weather extremes such as droughts or heat waves but the answer to this was not clear at the end of the study.
“Indeed, we did not find that the agrivoltaic array increased grassland resistance to drought,” “However, as noted in the paper, I would like to clarify the possibility that this is because the structure of the model does not allow the grass to die back and then regrow after drought, which is commonly observed in natural settings,”
To discover more about the impact of the reduction in light availability caused by solar photovoltaic arrays on grassland photosynthesis, the researchers used a combination of field measurements and a well-established plant hydraulic and soil hydrology model to simulate grassland physiology and hourly carbon-water fluxes over a 23-year time period.
They found that although the agrivoltaic array reduced light availability by 38%, photosynthesis and above ground net primary productivity were reduced by 6 to 7%. Another metric analyzed by the researchers, evapotranspiration, showed a 1.3% decrease compared to a reference land plot with no solar plant.
The grassland plot in the study is dominated by smooth brome (Bromus inermis), a common C3 pasture grass, said the researchers. It is located in Colorado with an east-west oriented 1.2 MW plant equipped with single-axis trackers, installed at a flat panel height of 1.8 m with 5.2 m between rows. The paper notes that care was taken to minimize the impact on soils and vegetation. For example, the land was not graded for installation.
The researchers said the minimal changes in carbon-water cycling occurred largely because plant photosynthetic traits underneath the solar panels changed to take advantage of the dynamic shading environment. They conclude that agrivoltaic systems can serve as a scalable way to expand solar energy production while maintaining ecosystem function in managed grasslands, especially in climates where water is more limiting than light.
“We are planning to continue this research. This paper is one of the first of hopefully many that will come out of work done in Colorado. And we would always be interested in hearing about research from industry on this topic,”
The scientists presented their findings in “Grassland carbon-water cycling is minimally impacted by a photovoltaic array,” published in communications earth environment. They come from Colorado State University and the Technical University of Madrid in Spain.
For more information, please check solar mount website.
The scientists also sought to answer questions about water retention and grassland ecosystem resistance to weather extremes such as droughts or heat waves but the answer to this was not clear at the end of the study.
“Indeed, we did not find that the agrivoltaic array increased grassland resistance to drought,” “However, as noted in the paper, I would like to clarify the possibility that this is because the structure of the model does not allow the grass to die back and then regrow after drought, which is commonly observed in natural settings,”
To discover more about the impact of the reduction in light availability caused by solar photovoltaic arrays on grassland photosynthesis, the researchers used a combination of field measurements and a well-established plant hydraulic and soil hydrology model to simulate grassland physiology and hourly carbon-water fluxes over a 23-year time period.
They found that although the agrivoltaic array reduced light availability by 38%, photosynthesis and above ground net primary productivity were reduced by 6 to 7%. Another metric analyzed by the researchers, evapotranspiration, showed a 1.3% decrease compared to a reference land plot with no solar plant.
The grassland plot in the study is dominated by smooth brome (Bromus inermis), a common C3 pasture grass, said the researchers. It is located in Colorado with an east-west oriented 1.2 MW plant equipped with single-axis trackers, installed at a flat panel height of 1.8 m with 5.2 m between rows. The paper notes that care was taken to minimize the impact on soils and vegetation. For example, the land was not graded for installation.
The researchers said the minimal changes in carbon-water cycling occurred largely because plant photosynthetic traits underneath the solar panels changed to take advantage of the dynamic shading environment. They conclude that agrivoltaic systems can serve as a scalable way to expand solar energy production while maintaining ecosystem function in managed grasslands, especially in climates where water is more limiting than light.
“We are planning to continue this research. This paper is one of the first of hopefully many that will come out of work done in Colorado. And we would always be interested in hearing about research from industry on this topic,”
The scientists presented their findings in “Grassland carbon-water cycling is minimally impacted by a photovoltaic array,” published in communications earth environment. They come from Colorado State University and the Technical University of Madrid in Spain.
For more information, please check solar mount website.
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