News

TU Delft has presented an integrated vision of the Netherlands' global position in the nuclear and radiation ecosystem. This ecosystem is a major and crucial contribution to the energy transition, effective healthcare and materials transition.

On the 12th of January a large number of parties involved in the development of batteries in the Netherlands – small companies, multinationals and knowledge institutes – attended the kick off of the BatteryNL consortium. Their goal is to develop the next generation of batteries within eight years based on a better understanding of material interfaces.

An outpatients’ centre for cancer patients is certainly not the first thing you would expect to encounter on TU Delft campus. ‘But the decision to choose Delft as the location for the Holland Proton Therapy Centre has actually proved to be a very smart move’, says Medical Director Prof. Marco van Vulpen. The location alongside the TU Delft Reactor Institute offers an excellent opportunity for clinicians and engineers to collaborate closely.

Everyone who works on the development of batteries in the Netherlands, small companies, multinationals and knowledge institutes, has joined together in the BatteryNL consortium to develop the next generation of batteries within eight years based on a better understanding of material interfaces. Prof. M. (Marnix) Wagemaker (TU Delft - Faculty of Applied Sciences) is the project leader of a €9.3 million project funded by NWO-ORC.

The Ommerschans sword is one of the most important pieces from Dutch prehistory and is part of the collection of the Dutch National Museum of Antiquities. This extraordinary sword has now been examined at the TU Delft Reactor Institute, in search of information about its composition and method of making.

TU Delft, the Netherlands and Seaborg Technologies, Denmark, started a one year project on the investigation of fuel molten salt chemistry for the development of an innovative molten salt nuclear reactor design. The researchers at TU Delft are Dr Anna Smith (Associate Professor) and Lukasz Ruszczynski (Postdoc). Seaborg Technologies’ vision is to deliver clean, cost-competitive, and safe energy with their promising Compact Molten Salt Reactor (CMSR) concept.

Current coolant gases from air conditioners and fridges either contribute a significant amount to global warming, or otherwise they are dangerous to use. Bowei Huang and Michael Maschek from the Delft company Magneto are working on a safe and environmental friendly alternative for cooling: a unique solid material for heat pumps.

Anna Smith, Martin Rohde en Danny Lathouwers van het TU Delft Reactor Instituut nemen deel aan het MIMOSA-project dat een multi-recyclingstrategie zal ontwikkelen voor verbruikte splijtstoffen van lichtwaterreactoren op basis van gesmolten-zouttechnologieën.

Researchers from TU Delft have found a new method to efficiently make nano carriers loaded with radioactive salts for both medical imaging and treatment. Because the assembly of these nano carriers is incredibly simple, the innovation is very suitable for clinical research and treatments of cancer patients.

More and more greenhouses are being built worldwide due to their reliable environmental conditions; inside however, the amount of sunlight that plants can use for growth is limited. Physicist Sadiq van Overbeek from PHYSEE Technologies, a spin-off of the Radiation Science & Technology department of TU Delft at TU Delft Reactor Institute & Radiation Science and Technology, found a solution to this bottleneck: a special coating on the greenhouse that converts incoming light towards the part of the spectrum that plants use for photosynthesis. Van Overbeek: “First results show up to 10% more crops with this PAR+ coating.”