In the context of the project, new concepts were developed to produce proton-conducting polymer membrane fuel cells for use in a wide temperature interval over 100°C. The project synthesised new super
The project produced innovative methods and software tools needed to simulate, validate and optimise carbon capture from, e.g., flue gas, concrete production or pharmaceutical fermentation.
More than 50% of Danish oil is unattainable because the pores in chalk reservoirs are so small. Nano-Chalk explores ways to enhance particle growth thus increasing pore size and oil pro-duction.
In this project next generation fuel cells are developed towards commercial applications. The projects is based on efficient and robust metal-based fuel cell technology.
The project highlighted markets and instruments aimed at promoting renewable energy in Denmark, the EU and internationally, while also identifying key risks and uncertainties related to renewable
The project aimed to find new electrode materials for hydrogen development able to replace the costly and rare platinum normally used in PEM fuel cells. The project succeeded in demonstrating that
Identification and study of a number of central scientific problems – especially concerning interfaces between the different components in the systems. The economical aspects of the technology is also
The aim of the PEP project is to construct molecular components potentially useful for supramolecular or nanoscale devices for the light-induced production of electricity. The design of this system is
The project deals with novel materials for an advanced polymer membrane fuel cell system, which produces electricity and heat from natural gas, biomass or other environmentally friendly fuels. The