Summary
Smart agriculture is determined to play a major role to foster water and energy conservation solutions, and innovation technologies
should be aimed at overcoming current technical, economic, and sustainable barriers. The SOIL2POWER project focuses on
developing a breakthrough power sourcing technology based in Microbial Fuel Cells (MFCs), that leverage the natural microbial
metabolism processes using organic matter present at the soil to generate electrical energy. The consortium will build a controlled
electrogenic biofilm formation by immobilization techniques to increase overall biobattery performance, creating a continuous,
clean, safe, and maintenance-free energy supply solution. By facing relevant challenges throughout the project, such as bacterial
behavior, startup time conditions or electrode architecture an innovative biological battery of rapid start-up and stable high-power
supply will be conducted to control irrigation valves without maintenance and replacement.
Feasibility and validation of separate components have been already conducted through lab studies and will be the starting point to
perform a continuous improvement development during the first stages of the project. Afterwards, a prototype will be tested in
simulated environment by the end of year 2. If solution is validated with the whole functions up and running, during year 3
(2024-2025) a complete deployment of marketing and investment strategies will be performed, alongside operational environment
validation to rate real performance based on real feedback from end-users.
SOIL2POWER will contribute and ease the transition to develop novel technological solutions by boosting the innovation in clean
energy solutions industry, strengthening human capital, biotechnological research innovatinos and eventually enabling the adoption
of sustainable energy solutions in agricultural industry, paving the way to a sustainable precise irrigation systems for smart
agriculture.
should be aimed at overcoming current technical, economic, and sustainable barriers. The SOIL2POWER project focuses on
developing a breakthrough power sourcing technology based in Microbial Fuel Cells (MFCs), that leverage the natural microbial
metabolism processes using organic matter present at the soil to generate electrical energy. The consortium will build a controlled
electrogenic biofilm formation by immobilization techniques to increase overall biobattery performance, creating a continuous,
clean, safe, and maintenance-free energy supply solution. By facing relevant challenges throughout the project, such as bacterial
behavior, startup time conditions or electrode architecture an innovative biological battery of rapid start-up and stable high-power
supply will be conducted to control irrigation valves without maintenance and replacement.
Feasibility and validation of separate components have been already conducted through lab studies and will be the starting point to
perform a continuous improvement development during the first stages of the project. Afterwards, a prototype will be tested in
simulated environment by the end of year 2. If solution is validated with the whole functions up and running, during year 3
(2024-2025) a complete deployment of marketing and investment strategies will be performed, alongside operational environment
validation to rate real performance based on real feedback from end-users.
SOIL2POWER will contribute and ease the transition to develop novel technological solutions by boosting the innovation in clean
energy solutions industry, strengthening human capital, biotechnological research innovatinos and eventually enabling the adoption
of sustainable energy solutions in agricultural industry, paving the way to a sustainable precise irrigation systems for smart
agriculture.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101112669 |
| Start date: | 01-03-2023 |
| End date: | 28-02-2026 |
| Total budget - Public funding: | 2 499 812,50 Euro - 2 499 812,00 Euro |
Cordis data
Original description
Smart agriculture is determined to play a major role to foster water and energy conservation solutions, and innovation technologiesshould be aimed at overcoming current technical, economic, and sustainable barriers. The SOIL2POWER project focuses on
developing a breakthrough power sourcing technology based in Microbial Fuel Cells (MFCs), that leverage the natural microbial
metabolism processes using organic matter present at the soil to generate electrical energy. The consortium will build a controlled
electrogenic biofilm formation by immobilization techniques to increase overall biobattery performance, creating a continuous,
clean, safe, and maintenance-free energy supply solution. By facing relevant challenges throughout the project, such as bacterial
behavior, startup time conditions or electrode architecture an innovative biological battery of rapid start-up and stable high-power
supply will be conducted to control irrigation valves without maintenance and replacement.
Feasibility and validation of separate components have been already conducted through lab studies and will be the starting point to
perform a continuous improvement development during the first stages of the project. Afterwards, a prototype will be tested in
simulated environment by the end of year 2. If solution is validated with the whole functions up and running, during year 3
(2024-2025) a complete deployment of marketing and investment strategies will be performed, alongside operational environment
validation to rate real performance based on real feedback from end-users.
SOIL2POWER will contribute and ease the transition to develop novel technological solutions by boosting the innovation in clean
energy solutions industry, strengthening human capital, biotechnological research innovatinos and eventually enabling the adoption
of sustainable energy solutions in agricultural industry, paving the way to a sustainable precise irrigation systems for smart
agriculture.
Status
SIGNEDCall topic
HORIZON-EIC-2022-TRANSITIONOPEN-01Update Date
31-07-2023
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