Plant and soil responses to ground-mounted solar panels in temperate agricultural systems

Lancaster Environment Centre

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https://doi.org/10.1088/1748-9326/ada45b
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Plant and soil responses to ground-mounted solar panels in temperate agricultural systems. / Carvalho, Fabio; Montag, Hannah; Bentley, Laura et al.
In: Environmental Research Letters, Vol. 20, No. 2, 024003, 10.01.2025.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Carvalho, F, Montag, H, Bentley, L, Šarlej, R, Broyd, RC , Blaydes, H , Cattin, M , Burke, M , Wallwork, A , Ramanayaka, S, White, PCL, Sharp, SP, Clarkson, T & Armstrong, A 2025, 'Plant and soil responses to ground-mounted solar panels in temperate agricultural systems', Environmental Research Letters, vol. 20, no. 2, 024003. https://doi.org/10.1088/1748-9326/ada45b

APA

Carvalho, F., Montag, H., Bentley, L., Šarlej, R., Broyd, R. C., Blaydes, H., Cattin, M., Burke, M., Wallwork, A., Ramanayaka, S., White, P. C. L., Sharp, S. P., Clarkson, T., & Armstrong, A. (2025). Plant and soil responses to ground-mounted solar panels in temperate agricultural systems. Environmental Research Letters, 20(2), Article 024003. https://doi.org/10.1088/1748-9326/ada45b

Vancouver

Carvalho F, Montag H, Bentley L, Šarlej R, Broyd RC , Blaydes H et al. Plant and soil responses to ground-mounted solar panels in temperate agricultural systems. Environmental Research Letters. 2025 Jan 10;20(2):024003. doi: 10.1088/1748-9326/ada45b

Author

Carvalho, Fabio ; Montag, Hannah ; Bentley, Laura et al. / Plant and soil responses to ground-mounted solar panels in temperate agricultural systems. In: Environmental Research Letters. 2025 ; Vol. 20, No. 2.

Bibtex

@article{ca424771978542068fdfe62e633d1345,

title = "Plant and soil responses to ground-mounted solar panels in temperate agricultural systems",

abstract = "In the move to decarbonise energy supplies to meet Net Zero targets, ground-mounted solar farms have proliferated around the world, with uncertain implications for hosting ecosystems. We provide some of the first evidence on the effects of ground-mounted solar panels on plant and soil properties in temperate agricultural systems. We sampled 32 solar farms in England and Wales in summer 2021. Plant cover and aboveground biomass, as well as soil nutrients and physiochemical properties, were quantified on land underneath solar panels, in the gaps between rows of solar arrays, and in control land (pasture) adjacent to three solar farms. Plant cover and aboveground biomass were significantly lower under solar panels than in the gaps between solar arrays and in pastures. Soil compaction was 14.4% and 15.5% higher underneath solar panels than in gaps and pastures, respectively. Soil organic carbon was 9% lower under solar panels than in gaps, while particulate organic matter was 29.1% and 23.6% lower under solar panels than in gaps and pastures, respectively. Soil mineral nitrogen was 30.5% higher under solar panels than in gaps, while soil (plant-available) phosphorus was approximately 60% higher in solar farm soils than in pasture soils. Reductions in solar radiation and changes to microclimate caused by solar panels may be driving lower plant productivity and growth, with consequences for nutrient cycling and soil properties. However, impacts must be considered in light of the previous land use and the total land area under solar panels, in the gaps between solar arrays, and around the margins of the solar farm. Our findings can inform solar farm design and management options (e.g., increase the proportion of land unaffected by solar panels, enhance plant cover under solar panels) to ensure the long-term provision of ecosystem services (e.g., soil carbon storage) within this fast-growing land use.",

author = "Fabio Carvalho and Hannah Montag and Laura Bentley and Radim {\v S}arlej and Broyd, {Rosanne C} and Hollie Blaydes and Marta Cattin and Miranda Burke and Abby Wallwork and Sammani Ramanayaka and White, {Piran C L} and Sharp, {Stuart Peter} and Tom Clarkson and Alona Armstrong",

year = "2025",

month = jan,

day = "10",

doi = "10.1088/1748-9326/ada45b",

language = "English",

volume = "20",

journal = "Environmental Research Letters",

issn = "1748-9326",

publisher = "IOP Publishing Ltd",

number = "2",

}

RIS

TY - JOUR

T1 - Plant and soil responses to ground-mounted solar panels in temperate agricultural systems

AU - Carvalho, Fabio

AU - Montag, Hannah

AU - Bentley, Laura

AU - Šarlej, Radim

AU - Broyd, Rosanne C

AU - Blaydes, Hollie

AU - Cattin, Marta

AU - Burke, Miranda

AU - Wallwork, Abby

AU - Ramanayaka, Sammani

AU - White, Piran C L

AU - Sharp, Stuart Peter

AU - Clarkson, Tom

AU - Armstrong, Alona

PY - 2025/1/10

Y1 - 2025/1/10

N2 - In the move to decarbonise energy supplies to meet Net Zero targets, ground-mounted solar farms have proliferated around the world, with uncertain implications for hosting ecosystems. We provide some of the first evidence on the effects of ground-mounted solar panels on plant and soil properties in temperate agricultural systems. We sampled 32 solar farms in England and Wales in summer 2021. Plant cover and aboveground biomass, as well as soil nutrients and physiochemical properties, were quantified on land underneath solar panels, in the gaps between rows of solar arrays, and in control land (pasture) adjacent to three solar farms. Plant cover and aboveground biomass were significantly lower under solar panels than in the gaps between solar arrays and in pastures. Soil compaction was 14.4% and 15.5% higher underneath solar panels than in gaps and pastures, respectively. Soil organic carbon was 9% lower under solar panels than in gaps, while particulate organic matter was 29.1% and 23.6% lower under solar panels than in gaps and pastures, respectively. Soil mineral nitrogen was 30.5% higher under solar panels than in gaps, while soil (plant-available) phosphorus was approximately 60% higher in solar farm soils than in pasture soils. Reductions in solar radiation and changes to microclimate caused by solar panels may be driving lower plant productivity and growth, with consequences for nutrient cycling and soil properties. However, impacts must be considered in light of the previous land use and the total land area under solar panels, in the gaps between solar arrays, and around the margins of the solar farm. Our findings can inform solar farm design and management options (e.g., increase the proportion of land unaffected by solar panels, enhance plant cover under solar panels) to ensure the long-term provision of ecosystem services (e.g., soil carbon storage) within this fast-growing land use.

AB - In the move to decarbonise energy supplies to meet Net Zero targets, ground-mounted solar farms have proliferated around the world, with uncertain implications for hosting ecosystems. We provide some of the first evidence on the effects of ground-mounted solar panels on plant and soil properties in temperate agricultural systems. We sampled 32 solar farms in England and Wales in summer 2021. Plant cover and aboveground biomass, as well as soil nutrients and physiochemical properties, were quantified on land underneath solar panels, in the gaps between rows of solar arrays, and in control land (pasture) adjacent to three solar farms. Plant cover and aboveground biomass were significantly lower under solar panels than in the gaps between solar arrays and in pastures. Soil compaction was 14.4% and 15.5% higher underneath solar panels than in gaps and pastures, respectively. Soil organic carbon was 9% lower under solar panels than in gaps, while particulate organic matter was 29.1% and 23.6% lower under solar panels than in gaps and pastures, respectively. Soil mineral nitrogen was 30.5% higher under solar panels than in gaps, while soil (plant-available) phosphorus was approximately 60% higher in solar farm soils than in pasture soils. Reductions in solar radiation and changes to microclimate caused by solar panels may be driving lower plant productivity and growth, with consequences for nutrient cycling and soil properties. However, impacts must be considered in light of the previous land use and the total land area under solar panels, in the gaps between solar arrays, and around the margins of the solar farm. Our findings can inform solar farm design and management options (e.g., increase the proportion of land unaffected by solar panels, enhance plant cover under solar panels) to ensure the long-term provision of ecosystem services (e.g., soil carbon storage) within this fast-growing land use.

U2 - 10.1088/1748-9326/ada45b

DO - 10.1088/1748-9326/ada45b

M3 - Journal article

VL - 20

JO - Environmental Research Letters

JF - Environmental Research Letters

SN - 1748-9326

IS - 2

M1 - 024003

ER -

Research

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