SubsidieMeestersNext Generation of Artificial Heterointerfaces as Building Blocks for Energy Materials
NEXUS aims to revolutionize energy technologies by creating artificial oxide heterostructures to enhance fast ionic transport at interfaces, overcoming existing limitations in energy devices.
Projectdetails
Introduction
In an era of rapid green transition changes, interfaces lie at the heart of the advances in most energy conversion and storage technologies, including batteries, Power-to-X, and electrolysis. Depending on the type of device, these technologies rely upon the fast transport of atomic and electronic species across the solid-solid, solid-liquid, and solid-gas interfaces.
Importance of Understanding Interfaces
Developing viable solid-state devices requires a fundamental understanding of how ions move at the interface between two solid materials stacked together. Despite half a century of sustained research into interfaces, we still cannot answer the most critical questions about:
- The role of interface symmetries
- Finding pathways for engineering fast ionic transport at room temperature
The underlying motivation to find the answers is clear: fast transport of ions provides an opportunity to accelerate energy technology. However, the fundamental science required is extremely challenging due to two main factors:
- The interfaces are buried in bulk structures
- Possible combinations of materials are limited by the rules of epitaxy
Vision for the Future
Imagine a future where the precise tuning of materials can take place according to our aspirations by assembling ultrathin layers into new artificial heterostructures. NEXUS is the epitome of this future.
Objectives of NEXUS
In NEXUS, I seek to take a leap from our present knowledge by:
- Creating artificial oxide heterostructures
- Hybridizing their physical properties by directly stacking freestanding membranes with different crystal structures and orientations (Figure 1)
In this way, I will realize novel structures with fast ionic paths potentially breaking fundamental limitations of existing energy devices.
Past Achievements
During the last decade, I pioneered and matured new sets of oxide-based interfaces, exhibiting an exceptionally colorful palette of properties. The approach of NEXUS is radically different from past work and will provide fundamental breakthroughs in the study of fast ionic transport across interfaces.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.491.730 |
| Totale projectbegroting | € 2.491.730 |
Tijdlijn
| Startdatum | 1-1-2023 |
| Einddatum | 31-12-2027 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- DANMARKS TEKNISKE UNIVERSITETpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
Deconstructing the Electrode-Electrolyte Interface by Novel NMR MethodologyThis project aims to enhance rechargeable battery efficiency by investigating the solid electrolyte interphase (SEI) using advanced NMR techniques to optimize ion transport and design next-generation energy storage systems. | ERC Consolid... | € 2.228.750 | 2025 | Details |
Interface-sensitive Spectroscopy of Atomically-defined Solid/Liquid Interfaces Under Operating ConditionsThe project aims to develop novel operando X-ray spectroscopies to analyze solid/liquid interfaces in electrocatalysis, enhancing understanding for efficient energy conversion and storage. | ERC Starting... | € 1.500.000 | 2022 | Details |
Nanoscale Epitaxial Heterostructures Involving Metal HalidesThe project aims to develop synthetic strategies for epitaxial nano-heterostructures involving metal halide nanocrystals to enhance applications in photocatalysis, photoharvesting, and photonic devices. | ERC Advanced... | € 2.499.375 | 2023 | Details |
A Research Platform Addressing Outstanding Research Challenges for Nanoscale Design and Engineering of Multifunctional 2D MaterialsThe project aims to develop a new generation of multifunctional 2D materials from 3D atomic laminates, targeting sustainable applications in energy storage and catalysis through advanced synthesis and engineering. | ERC Consolid... | € 1.999.940 | 2023 | Details |
Directed Evolution of Metastable Electrocatalyst Interfaces for Energy ConversionThis project aims to revolutionize electrocatalysis by leveraging high entropy materials and advanced techniques to discover stable, active catalysts for energy conversion reactions. | ERC Synergy ... | € 9.973.679 | 2024 | Details |
Deconstructing the Electrode-Electrolyte Interface by Novel NMR Methodology
This project aims to enhance rechargeable battery efficiency by investigating the solid electrolyte interphase (SEI) using advanced NMR techniques to optimize ion transport and design next-generation energy storage systems.
Interface-sensitive Spectroscopy of Atomically-defined Solid/Liquid Interfaces Under Operating Conditions
The project aims to develop novel operando X-ray spectroscopies to analyze solid/liquid interfaces in electrocatalysis, enhancing understanding for efficient energy conversion and storage.
Nanoscale Epitaxial Heterostructures Involving Metal Halides
The project aims to develop synthetic strategies for epitaxial nano-heterostructures involving metal halide nanocrystals to enhance applications in photocatalysis, photoharvesting, and photonic devices.
A Research Platform Addressing Outstanding Research Challenges for Nanoscale Design and Engineering of Multifunctional 2D Materials
The project aims to develop a new generation of multifunctional 2D materials from 3D atomic laminates, targeting sustainable applications in energy storage and catalysis through advanced synthesis and engineering.
Directed Evolution of Metastable Electrocatalyst Interfaces for Energy Conversion
This project aims to revolutionize electrocatalysis by leveraging high entropy materials and advanced techniques to discover stable, active catalysts for energy conversion reactions.
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