SubsidieMeestersSteering the Quantum Dynamics of Confined Molecular Materials
QUADYMM aims to revolutionize sustainable energy technologies by developing advanced simulations for nonequilibrium molecular dynamics, enhancing predictive capacity for electrochemistry and optoelectronics.
Projectdetails
Introduction
Molecular materials are often present in forefront technologies targeting new sustainable energy alternatives. However, most of these alternatives currently fall short of the needs of industry and society. QUADYMM will investigate new fundamental mechanisms that could lead to paradigmatic changes in the design of such technologies.
Thematic Avenues
We will explore two main thematic avenues, from a theoretical perspective:
- Tuning the atomic and electronic properties of molecular materials in confined structured environments.
- Realizing nonequilibrium molecular material states for dynamic control of stable and reactive phases of matter.
From a large pool of areas where these concepts can be applied, QUADYMM will focus on:
- Water interfaces with inorganic materials.
- Aromatic hydrocarbon interfaces with 2D materials.
These areas are chosen because of their fundamental impact on electrochemistry and optoelectronics.
Current Limitations
The state of the art of computer simulation in this area is still based on classical mechanics of nuclei or simplified models, especially for nonequilibrium and nonadiabatic processes. Once successful, QUADYMM will provide new first-principles methodology to treat electronic and nuclear nonequilibrium dynamics, changing the predictive capacity of computational simulations of important processes, such as water-splitting and vibronic energy transport.
Development of Novel Protocols
Crucially, we will develop novel protocols for the inclusion of external stimuli in quantum dynamics simulations, bridging electronic and vibrational time scales and reaching the thermodynamic limit. This will be achieved by new techniques joining machine-learning methods with first-principles electronic structure and trajectory-based path-integral approaches.
Expected Outcomes
The resulting framework will elucidate the nonequilibrium quantum dynamics of complex weakly-bound systems containing thousands of atoms, and provide new structural and electronic phase diagrams to aid vibrational design.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.000.000 |
| Totale projectbegroting | € 2.000.000 |
Tijdlijn
| Startdatum | 1-6-2025 |
| Einddatum | 31-5-2030 |
| Subsidiejaar | 2025 |
Partners & Locaties
Projectpartners
- MAX-PLANCK-GESELLSCHAFT ZUR FORDERUNG DER WISSENSCHAFTEN EVpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Ultrafast atomic-scale imaging and control of nonequilibrium phenomena in quantum materialsThe project aims to utilize ultrafast Terahertz-lightwave-driven scanning tunneling microscopy to explore and induce new quantum properties in correlated electron states at atomic scales. | ERC Starting... | € 1.572.500 | 2025 | Details |
Turning gold standard quantum chemistry into a routine simulation tool: predictive properties for large molecular systemsThis project aims to develop advanced quantum simulation methods for large molecules, enhancing predictive power and efficiency to study complex biochemical interactions and reactions. | ERC Starting... | € 1.175.215 | 2023 | Details |
Predictive algorithms for simulating quantum materialsThis project aims to develop advanced predictive algorithms for quantum many-body systems by integrating field-theory methods with tensor techniques and machine learning to enhance understanding of quantum materials. | ERC Advanced... | € 3.499.299 | 2025 | Details |
Quantum Materials for Quantum DevicesDevelop new transition metal dichalcogenides for quantum technology, enabling advanced materials with unique properties for ultra-fast, low-power devices. | ERC Starting... | € 2.457.970 | 2024 | Details |
Quantum interfaces with single moleculesQUINTESSEnCE aims to enhance quantum devices by developing interfaces between single photons, spins, and phonons within a single molecule, enabling unprecedented control and new quantum technologies. | ERC Consolid... | € 1.999.993 | 2023 | Details |
Ultrafast atomic-scale imaging and control of nonequilibrium phenomena in quantum materials
The project aims to utilize ultrafast Terahertz-lightwave-driven scanning tunneling microscopy to explore and induce new quantum properties in correlated electron states at atomic scales.
Turning gold standard quantum chemistry into a routine simulation tool: predictive properties for large molecular systems
This project aims to develop advanced quantum simulation methods for large molecules, enhancing predictive power and efficiency to study complex biochemical interactions and reactions.
Predictive algorithms for simulating quantum materials
This project aims to develop advanced predictive algorithms for quantum many-body systems by integrating field-theory methods with tensor techniques and machine learning to enhance understanding of quantum materials.
Quantum Materials for Quantum Devices
Develop new transition metal dichalcogenides for quantum technology, enabling advanced materials with unique properties for ultra-fast, low-power devices.
Quantum interfaces with single molecules
QUINTESSEnCE aims to enhance quantum devices by developing interfaces between single photons, spins, and phonons within a single molecule, enabling unprecedented control and new quantum technologies.