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1. Coproduction of solar energy on maize farms – experimental validation of recent experiments

   Grubbs, E; Agrawal, R.; Bermel, P; Imran, H. (January 2019, Coproduction of solar energy on maize farms – experimental validation of recent experiments)

   Abstract—Developing methods for the sustainable coproduction of food, energy and water resources has recently been recognized as a potentially attractive solution to meeting the needs of a growing population. However, many studies have used models, but have not performed an actual experiment to directly validate all their predictions. Here, we report a recently-constructed test site on the ACRE farm in West Lafayette, Indiana, consisting of single-axis trackers in a novel configuration atop a maize test plot. We present a methodology to measure irradiance therein with 10-minute temporal resolution, which allows us to validate prior PV aglectric farm irradiance models. Keywords—aglectric, agrophotovoltaic, agrivoltaic, photovoltaic 

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2. Land Availability, Utilization, and Intensification for a Solar Powered Economy

   https://doi.org/10.1016/B978-0-444-64241-7.50314-1  

   Li, Yiru; Miskin, Caleb; Agrawal, Rakesh (August 2018, Computer-aided chemical engineering)

   Solar energy, though promising as the energy source for a fossil fuel-deprived future, is a dilute resource and harvesting it requires vast tracts of land. In this study, we develop an extensive process system model for land requirement analysis in each of the 48 contiguous states of the United States for a solar powered economy to address the likely land competition. Land requirement analysis in this study takes into account several issues that are usually ignored. Efficiencies of major energy conversion steps from primary energy to end use are accounted and intermittent solar availability, actual solar farm output and land availability are all considered. In addition, we prefer local photons for local use for consideration of minimizing transmission loss and energy security. Under this preferred scenario, our land requirement analysis shows that 16 of the 48 contiguous states have insufficient available land and that the land competition for energy and food will be intense. Thus, in a solar economy, land use intensification will be required to avoid conflict between our competing land use needs. 

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3. Environmental Co‐Benefits of Maintaining Native Vegetation With Solar Photovoltaic Infrastructure

   https://doi.org/10.1029/2023EF003542  

   Choi, Chong Seok; Macknick, Jordan; Li, Yudi; Bloom, Dellena; McCall, James; Ravi, Sujith (June 2023, Earth's Future)

   Abstract Co‐locating solar photovoltaics with vegetation could provide a sustainable solution to meeting growing food and energy demands. However, studies quantifying multiple co‐benefits resulting from maintaining vegetation at utility‐scale solar power plants are limited. We monitored the microclimate, soil moisture, panel temperature, electricity generation and soil properties at a utility‐scale solar facility in a continental climate with different site management practices. The compounding effect of photovoltaic arrays and vegetation may homogenize soil moisture distribution and provide greater soil temperature buffer against extreme temperatures. The vegetated solar areas had significantly higher soil moisture, carbon, and other nutrients compared to bare solar areas. Agrivoltaics in agricultural areas with carbon debt can be an effective climate mitigation strategy along with revitalizing agricultural soils, generating income streams from fallow land, and providing pollinator habitats. However, the benefits of vegetation cooling effects on electricity generation are rather site‐specific and depend on the background climate and soil properties. Overall, our findings provide foundational data for site preservation along with targeting site‐specific co‐benefits, and for developing climate resilient and resource conserving agrivoltaic systems. 

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4. Agrivoltaic system design tools for managing trade-offs between energy production, crop productivity and water consumption

   https://doi.org/10.1088/1748-9326/ad2ab8  

   Warmann, Emily; Jenerette, G. Darrel; Barron-Gafford, Greg A. (March 2024, Environmental Research Letters)

   Abstract Agrivoltaic systems that locate crop production and photovoltaic energy generation on the same land have the potential to aid the transition to renewable energy by reducing the competition between food, habitat, and energy needs for land while reducing irrigation requirements. Experimental efforts to date have not adequately developed an understanding of the interaction among local climate, array design and crop selection sufficient to manage trade-offs in system design. This study simulates the energy production, crop productivity and water consumption impacts of agrivoltaic array design choices in arid and semi-arid environments in the Southwestern region of the United States. Using the Penman–Monteith evapotranspiration model, we predict agrivoltaics can reduce crop water consumption by 30%–40% of the array coverage level, depending on local climate. A crop model simulating productivity based on both light level and temperature identifies afternoon shading provided by agrivoltaic arrays as potentially beneficial for shade tolerant plants in hot, dry settings. At the locations considered, several designs and crop combinations exceed land equivalence ratio values of 2, indicating a doubling of the output per acre for the land resource. These results highlight key design axes for agrivoltaic systems and point to a decision support tool for their development. 

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5. Solar PV Power Potential is Greatest Over Croplands

   Elnaz Adeh, H; Good, Stephen P; Calaf, Marc; Higgins, Chad W. (October 2019, Scientific reports)

   Solar energy has the potential to offset a significant fraction of non-renewable electricity demands globally, yet it may occupy extensive areas when deployed at this level. There is growing concern that large renewable energy installations will displace other land uses. Where should future solar power installations be placed to achieve the highest energy production and best use the limited land resource? The premise of this work is that the solar panel efficiency is a function of the location’s microclimate within which it is immersed. Current studies largely ignore many of the environmental factors that influence Photovoltaic (PV) panel function. A model for solar panel efficiency that incorporates the influence of the panel’s microclimate was derived from first principles and validated with field observations. Results confirm that the PV panel efficiency is influenced by the insolation, air temperature, wind speed and relative humidity. The model was applied globally using bias-corrected reanalysis datasets to map solar panel efficiency and the potential for solar power production given local conditions. Solar power production potential was classified based on local land cover classification, with croplands having the greatest median solar potential of approximately 28 W/m2. The potential for dual-use, agrivoltaic systems may alleviate land competition or other spatial constraints for solar power development, creating a significant opportunity for future energy sustainability. Global energy demand would be offset by solar production if even less than 1% of cropland were converted to an agrivoltaic system. 

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