Forskningsprojekter

AmiNIC

Every year, tons of meat products are thrown away since food safety concerns lead to a substantial waste of safe-to-eat food, causing a large waste of resources. Currently, the expiration date for meat/fish is determined by poorly performed subjective sensory. In this project, we found a high sensitive and selective method for detection of cadaverine (marker for meat freashness) by using a cadaverine-specific binder, and the method is applied into integrated sensors in close collaboration with AmiNIC ApS
AutomationsBoost (Væksthus Syddanmark og RoboCluster)
Project duration 03/2017 - 08/2019
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Baltic TRAM

Baltic TRAM aims to enhance innovation capacity and strengthen cooperation between analytical research institutes and companies, by providing industry with new ways of access to expertise, research facilities and open science and innovation concepts
Interreg Deutschland-Danmark
Projektperiode 03/2016 - 05/2019
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CheckNano

Nanoparticles make their way into a broad range of products and help to optimize everyday life, but the tiny particles can also end up taking their toll on our health. Within the project consortium CheckNano, supported by Interreg5a, we will test products for possible harmful particles and develop a rapid test for the identification of toxic nanoparticles for later application in industrial production processes.
Projektperiode 08/2018 - 07/2021
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Compliant PV

Mechanical and photochemical stabilization of flexible organic solar cells
Villum Fonden
Projektperiode 01/2017 - 12/2019
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Green PE

New materials for advanced power electronics. Boosting efficiency in conversion, transmission and consumption of green energy
Interreg Deutschland-Danmark
Projektperiode 03/2016 - 02/2019
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IMPULSE-OPV - Integrated Molecular Plasmon Upconverter for Low-cost, Scalable, and Efficient Organic Photovoltaics

This VILLUM Experiment addresses the fundamental limitation on the solar cell efficiency by exploring a method for exploiting a great fraction of low-energy sunlight photons that are transmitted and lost in traditional solar cell designs. The possibility of conducting plasmon-enhanced molecular up-conversion of sunlight inside an organic solar cell will be investigated. We aim at redefining the theoretical maximum efficiency of organic photovoltaics (OPV) by frequency up-conversion and subsequent absorption of photons with energies below the absorption threshold of OPV. The method applies the quantum properties of the light absorbing molecules in converting two low-energy photons into a single high-energy photon. This novel approach could significantly increase the efficiency of OPV, making this low-cost lightweight technology an important contributor in the transition to renewable power sources.
Projektperiode 00/2018 - 00/2020


Methodologies for Hyperspectral Thermal Imaging

Industrial PhD project in collaboration with Newtec Engineering A/S
Innovationsfonden
Proktperiode 08/2018 - 07/2021


Plasmonic Gas Sensors

Development of novel high-resolution gas sensors using plasmonics technology
Danfoss Uddannelsesfond
Projektperiode 01/2017 - 12/2017

 

ReactPV

In this project, novel reactively sputtered metal oxide films will be developed and integrated as contact layers in organic, hybrid and silicon photovoltaics for the first time. By utilizing composition- and microstructure-tuned metal oxides, high work function layers that are robust to standard PV production and operation treatments will be developed, resulting in PV modules with so far unseen performance and stability. The project partners are besides SDU (lead): UC Berkeley, LBNL Berkeley, IMEC, Aarhus University and Sorbonne University of Paris. DFF FTP research project 2.
Projektperiode 10/2018 - 03/2022

 

RollFlex

An Innovation Project Center for Roll-to-Roll processed flexible devices
Interreg Deutschland-Danmark
Projektperiode 04/2016 - 09/2020
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Smart Surfaces for Sensors

Optimizing surfaces for functionalization, in order to develop high-resolution gas sensors
Danfoss Uddannelsesfond
Projektperiode 07/2017 - 06/2018

 

SMART – Structures of Materials in Real Time

Ministry of Higher Education and Science
Projektperiode 00/2019 - 00/2023
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SOLID ESS lighthouse: Hard materials in 3D 

The Danish lighthouse SOLID has the vision to carry out cutting-edge research in neutron and synchrotron-based 3D imaging of hard materials. The combination of the separately superior sources, ESS and MAX IV, allows mapping the internal structure of a material, its formation and its change at all relevant length and time scales. At NanoSYD we will study cooling systems for power electronic devices. In particular we aim at understanding fundamental issues of flow of two-phase liquids and nanofluids in microporous materials and microfluidics devices. Neutron imaging is ideal for visualising such a flow due to its high penetration and good contrast with liquids. Complementary measurements with high-resolution Helium ion microscopy at SDU will clarify the role of structure between pores and surfaces in relation to nucleation and phase separation.
Danish roadmap for research infrastructures (lead: DTU) 
Projektperiode 11/2019 - 10/2024

 

Thinface

Thin-film Hydrid Interfaces: a training initiative for the design of next-generation energy devices
Initial Training Network (ITN FP7)
Projektperiode 09/2013 - 10/2017
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Tuning the Photostability of Organic Photovoltaics Components

DFF FTP
Projektperiode 00/2020 - 00/2024
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Udvikling af smarte materialer: fra grundforskning til production

Development of Smart Materials and their integration into organic solar cells, and other flexible devices for energy conversion and storage solutions developed from roll-to-roll (R2R) technology at the R2R facility at the Mads Clausen Institute, SDU NanoSYD. The project specifically targets how to mature these materials, thin films and devices for future industrial production of new energy technologies.
Projektperiode 00/2019 - 00/2022

 

Water quality sensing platforms for ecological management or urban rivers

Rivers which are crossing large urban areas are subject to human activities, and in order to preserve the environmental conditions, a constant monitoring of the river must be performed.  Current monitoring platforms are bulky and expensive, besides only collecting information about the physical-chemical properties of water. In this interdisciplinary project we will combine the knowledge of the consortium in order to develop a miniaturized sensing platform, which can collect a complete set of water properties (physical, chemical and biological) in real time
International Network Programme – Danish Agency for Science, Technology and Innovation
Projektperiode 01/2017 - 12/2017
Forskningsaktiviteter planlagt fra 2018