EU funds innovation project from technology, agricultural science and business studies with around 2.5 million euros
According to a report by the EU Commission, over 60 percent of agricultural soils in the European Union are overfertilised. The consequences are soil acidification, polluted waters, reduced biodiversity and declining soil yields. The upcoming soil health law and associated fertiliser requirements aim at improving soil quality, but for the farmers, this poses severe challenges. Daily variability of nutrient values and time-consuming laboratory analyses make it almost impossible to determine soil data promptly and adjust the fertilisation appropriately. An interdisciplinary research team at Kiel University (CAU) therefore wants to develop a measuring device that records the important nutrients in the soil twenty-for-seven. The sensor will measure nitrate, ammonium, and phosphate directly in the ground and the data can be checked in real-time. The EU is funding the "Soilmonitor" project within an innovation programme with around 2.5 million euros. It started at the beginning of November and is scheduled for three years.
Battery-powered mini-lab in the ground
"Securing food for a growing world population requires both - high crop yields and healthy soils. This EU funding enables an important contribution to a more efficient and at the same time more environmentally friendly cultivation of agricultural land. It also shows once again the potential of strong interdisciplinary cooperation for the big questions of our time," says Prof. Dr.-Ing. Eckhard Quandt, Vice President for Research and Transfer at the CAU.
The plan is to develop a battery-powered measuring device with a size of 5 cm x 3 cm x 3 cm. Embedded in the ground it will automatically extract and analyse soil solution in a microfluidic "lab-on-a-chip". Time-consuming sampling, laboratory analyses and maintenance are no longer necessary. Farmers are able to check the results of the mini-lab at any time via smartphone or other software applications and can adjust the fertilisation immediately. "This matchbox-sized sensor system enables a 24/7 measurement of soil nutrients for the first time and an optimal, data-based fertilisation," says Martina Gerken, Professor of Integrated Systems and Photonics at the Faculty of Engineering and head of the project.
Measurements directly in the soil are more informative
"The underlying technology is based on an optoelectronic detection chip that uses organic light-emitting-diodes developed by us for optical readout. We want to use hydrophilic ceramic materials to make it easier to extract the soil fluid," Gerken continues. The sensor development will be located in the Centre for Networked Sensor Systems (ZEVS) at the Faculty of Engineering. The building that is currently under construction is about to open in the summer of 2023 in Kiel.
"Direct nutrient measurements in the soil, which are collected continuously, are much more informative than today’s punctual measurements on soil samples or indirect measurements, for example via plant leaves,” says Sandra Spielvogel, Professor of Soil Science at the Faculty of Agricultural and Nutritional Sciences and part of the project team. “Particularly the concentration of nitrate in the soil solution is highly variable. Measuring nitrate on a 24/7 basis has the potential to improve the fertilization management of farmers substantially.” The soil-solution extraction into the microfluidic will be investigated and tested in the field for soils with a wide range of pore size distributions, bulk densities, pore-space connectivity, and soil water content. Zeynep Altintas, Professor of Biomaterials and Biosensor Technologies, is responsible in the team for detecting the various nutrients. Monika Sienknecht from the Chair of Entrepreneurship and Innovation Management contributes entrepreneurial know-how.
The goal is to start a spin-off company
The "Soilmonitor" project builds on Gerken's research in previous EU projects (ERC-Starting Grant "PhotoSmart" and ERC-Proof-of-Concept "BEAMOLED"), which have already resulted in two patents. There she also conducted first market analyses and built up a partner network. With the new funding from the EU’s EIC Transition programme, the interdisciplinary team from electrical engineering, chemical engineering, soil science and economics wants to develop a prototype and bring it to the market. "Our long-term goal is to start a spin-off company to produce the Soilmonitor on a larger scale for applications in agriculture and soil remediation. In addition to a standalone system a component that can be integrated into existing systems is also planned," says Gerken.
The project is also supported by Prof. Dr. Henning Kage (Agronomy and Crop Science, Scientific Director of the Experimental Farm Hohenschulen) as well as Prof. Dr. Achim Walter (Entrepreneurship and Innovation Management) and Prof. Dr. Carsten Schultz (Technology Management).
Prof. Dr. Martina Gerken
Head of the EU project „Soilmonitor“
Research Group “Integrated Systems and Photonics”
+49 431 880-6250
- Project acronym: Soilmonitor
- Full project name: "Miniaturized sensor system for continuous soil-nutrient monitoring based on integration of a lab-on-a-chip microfluidic cartridge with an optoelectronic detection unit"
- Project number: 101097989
- Call: HORIZON-EIC-2022-TRANSITION-01
- Project starting date: 1 November 2022
- Project end date: 31 October 2025
- Project duration: 36 months
- Budget: 2.499.716,00 EUR
In the "EIC Transition" funding line, the European Commission supports universities, research institutions and companies in bringing basic research results from previous EU projects into application. The European Innovation Council (EIC) and the European Research Council (ERC) are working closely together here to promote European talents and groundbreaking innovations.
The nanoworld is governed by different laws than the macroscopic world, by quantum physics. Understanding structures and processes in these dimensions and implementing the findings in an application-oriented manner is the goal of the priority research area KiNSIS (Kiel Nano, Surface and Interface Science) at Kiel University. Intensive interdisciplinary cooperation between physics, chemistry, engineering and life sciences could lead to the development of novel sensors and materials, quantum computers, advanced medical therapies and much more. www.kinsis.uni-kiel.de/en