SubsidieMeestersMulti-property Compositionally Complex Magnets for Advanced Energy Applications
The CoCoMag project aims to develop innovative, critical-element-free magnets using compositionally complex alloys to enhance e-mobility and magnetic refrigeration for a sustainable energy future.
Projectdetails
Introduction
Converting energy efficiently from renewable sources is crucial; however, the large-scale implementation of technologies such as e-mobility and wind turbines, as well as magnetic refrigeration, will drastically increase the material intensity of strategic metals like rare-earths (RE) and cobalt. Magnets are key enablers of a net-zero emission scenario.
Challenges in Magnet Technology
As conversion technologies become more advanced, the required attributes of the magnets are now much more demanding and multifunctional. Additionally, required mechanical, thermal, and mechanical stabilities will increase the efficiency and lifetime of the devices.
Current State of Cooling Technology
We live now in a cryogenic age, and gas-compression cooling has not changed for a century, with only incremental efficiency improvements over time. Magnetic refrigeration uses not only Nd-based permanent magnets, the same as used for the e-motor, to drive the magnetic heat pump but also heavy REs such as Gd for the magnetocaloric heat exchanger.
CoCoMag Proposal Overview
In the CoCoMag proposal, we are targeting these two main applications: e-mobility and magnetic refrigeration, by implementing a disruptive approach for magnet design. Our idea is the use of compositionally complex alloys (CCA) based on hexagonal Fe2P- and MM´X-type compounds, derived from high entropy alloys, for the development of both permanent magnet and magnetocaloric materials without critical elements.
Advantages of Compositionally Complex Alloys
With CCA, we can fully utilize the large degrees of freedom in the compositional space in a multi-element approach, leaving behind traditional metal alloying practiced since the Bronze Age. Using CCA, we address the primary magnetic properties and the equally important secondary engineering properties.
Methodology
We will use the theoretical predictions, experimental validation, and machine learning cycle to reach our goals quickly.
Conclusion
Being successful with CoCoMag, we will provide answers to challenges on the path to the decarbonization and electrification of mobility and energy sectors using new magnets free of critical elements.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.987.943 |
| Totale projectbegroting | € 2.987.943 |
Tijdlijn
| Startdatum | 1-6-2023 |
| Einddatum | 31-5-2026 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- TECHNISCHE UNIVERSITAT DARMSTADTpenvoerder
- UNIVERSIDAD DE SEVILLA
- MAX-PLANCK-INSTITUT FUR NACHHALTIGEMATERIALIEN GMBH
- UNIVERSITAT FUR WEITERBILDUNG KREMS
- CHALMERS TEKNISKA HOGSKOLA AB
- MAGNOTHERM SOLUTIONS GMBH
- NEW IDEAS 4.0 SRL
- AMEN NEW TECHNOLOGIES I.K.E.
Land(en)
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|---|---|---|---|---|
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Clean and efficient cooling in vaccine transportation using Rotating Magnetocaloric Effect
The Magccine project aims to develop a cost-effective, efficient solid-state magnetic refrigerator using the rotating magnetocaloric effect to enhance vaccine cold chain logistics and reduce waste.
First Regenerative sOlid-STate Barocaloric refrIgeraTor
The FROSTBIT project aims to develop an innovative barocaloric refrigerator using sustainable materials to enhance energy efficiency and reduce greenhouse gas emissions in cooling systems.
LARGE-SCALE MAGNETIC COOLING
The LEMON project aims to develop a scalable, helium-3-free cryogenic cooling system using continuous Adiabatic Demagnetization Refrigeration to support quantum computing advancements in the EU.
Cooling with Electrocaloric Polymers
This project aims to develop efficient electrocaloric cooling technologies using advanced polymers and capacitors, targeting a 1 kW cooling power and 60% efficiency to revolutionize energy use in cooling systems.
A HOLISTIC APPROACH OF ELECTRIC MOTOR COOLING
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MAG-TOOL aims to develop a sustainable, high-performance magnet by using machine learning to streamline the exploration of SmFe12-based compounds, reducing experiments from 10^8 to 10^2.
Disrupting the cooling and heating industry: a revolutionary green, energy efficient and cost competitive magnetocaloric technology platform
Magneto's innovative magnetocaloric heat pump uses affordable non-rare earth materials to provide sustainable heating and cooling, targeting high-energy-cost markets in Northern Europe.
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Magnotherm has developed a revolutionary magnetic cooling system that eliminates greenhouse gas emissions and enhances efficiency, achieving 40% electricity savings without harmful refrigerants.
Bulk rare earth free permanent magnets
The project aims to develop a high-performance, rare-earth-free MnBi permanent magnet using a novel processing route for large-scale industrial applications, enhancing temperature stability and energy efficiency.
Engineering Magneto-ionic Materials for Energy-Efficient Actuation and Sensing: From Interfaces to Multifunctional Voltage-Tunable Micromagnets
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