Potential analysis of AgroVoltaics in Austria in the context of climate change – identification of sustainable areas with special respect to technical, economic, environmental and social aspects
Abstract
The project PA³C³ describes the potential of AgroVoltaics in Austria in the context of climate change. It focuses on the combined use of agricultural land for production of food/feed and solar electricity as countermeasure to future impacts of climate change, as well as maximization of land utilization. The coming decades will pose the challenge to meet both increasing demand of agricultural products and electricity, being complicated by changing conditions due to climate change. Expected increase of average temperature, drying trends paired with extreme precipitation events and other climatic changes force agricultural management to adapt. AgroVoltaics is a promising pathway for adaptation. The electrical output can possibly substitute the decreased output of agricultural products. Furthermore, the photovoltaic panels can have a positive effect on the plants below, e.g. reducing peak solar radiation and irrigation demand, being a countermeasure to the negative effects of climate change. The expansion of renewable energy production also has effects on environmental impacts. Beside the agrotechnical and economical challenges of changing management, a broad participation of stakeholders is crucial due to the decentralized structure of AgroVoltaics. To investigate these complex relationships, PA³C³ combines the important aspects for a successful implementation of AgroVoltaics in Austria. Serving this purpose, three scenarios are established: (1) unmodified agricultural management simulated with EPIC, (2) complete substitution of agriculture by photovoltaics simulated with PV-GIS, (3) combined land use, i.e. AgroVoltaics, investigated with life-cycle-assessment. The scenarios will be compared for the base year 2020 and 2050 under regards of projected climate impacts. Since the reliability of agricultural management is strongly dependent on local conditions, the results are resolved on a 500-meter grid over Austria, based on GIS-data such as topographic attributes, soil conditions, actual land management, weather data, etc. The acceptance of these scenarios by stakeholders will be investigated with a “serious gaming”-approach. Combining the results of all researched aspects, the potential for AgroVoltaics can be classified with a high geographical resolution.
keywords AgroPV AgroVoltaics Potential analysis climate change
Publikationen
Combined simulation of electricity and crop outputs of AgriVoltaic Systems
Autoren: Mikovits, C; Krexner, T; Kral, I; Bauer, A; Schauppenlehner, T; Schönhart, M; Schmid, E; Schmidt J Jahr: 2023
Conference & Workshop proceedings, paper, abstract
Project staff
Alexander Bauer
Assoc. Prof. Priv.-Doz. Dipl.-Ing. Dr.nat.techn. Alexander Bauer
alexander.bauer@boku.ac.at
Tel: +43 1 47654-93101, 93150
Project Leader
01.10.2020 - 31.03.2023
Andreas Gronauer
Univ.Prof. Dipl.-Ing. Dr. Andreas Gronauer
andreas.gronauer@boku.ac.at
Tel: +43 1 47654-93111
Project Staff
01.10.2020 - 13.01.2022
Iris Kral
Dipl.-Ing. Dr. Iris Kral
iris.kral@boku.ac.at
Tel: +43 1 47654-93146
Sub Projectleader
01.10.2020 - 31.03.2023
Theresa Krexner
Dipl.-Ing. Theresa Krexner
theresa.krexner@boku.ac.at
Tel: +43 1 47654-93137
Project Staff
01.10.2020 - 31.03.2023