SubsidieMeestersField-Theory Approach to Molecular Interactions
The FITMOL project aims to revolutionize modeling of large molecular complexes through a new field-theory approach, enhancing accuracy and efficiency in quantum calculations for intricate biological systems.
Projectdetails
Introduction
The quantum-mechanical theory of molecular interactions is firmly established; however, its applicability to large molecular complexes is hindered by the rather high computational cost of quantum calculations required to achieve high accuracy.
Proposed Paradigm Shift
We propose a paradigm shift in the modeling and conceptual understanding of electrostatic and electrodynamic molecular interactions in many-particle systems from the perspective of (quantum) field theory. This development is critical to accurately and efficiently model increasingly intricate and functional molecular ensembles with millions of atoms subject to external excitations, including:
- Static fields
- Thermal fields
- Optical fields
- Variation in the number of particles
- Arbitrary macroscopic boundary conditions
This molecular size covers a wide range of functional biological systems, including solvated protein/protein and enzyme/DNA complexes.
Theoretical Developments
The theoretical developments in this project will concentrate on two main fronts:
- WP1: Fundamental quantum electrodynamics (QED) theory of molecular interactions based on many-body oscillator Hamiltonians.
- WP2: Second-quantized field theory (FIT) approach to molecular Hamiltonians for modeling large-scale systems with (10^4-10^6) atoms.
Implementation Strategies
The applicability of these challenging developments to realistic molecules will be ensured by:
- WP3: Implementation of non-local machine learning force fields based on second-quantized matrix Hamiltonians for efficient molecular dynamics simulations of molecular ensembles.
- WP4: Implementation of QED/FIT methods in an open-source package FITMOL for increasing the accuracy, improving the efficiency, and enhancing the insight that one obtains from quantum-mechanical calculations of large molecules.
Vision and Goal
It is my vision that revealing fundamental mechanisms of functional (bio)molecules with millions of atoms requires a radically new field-theory approach to molecular interactions. Achieving this goal will be the main breakthrough of the FITMOL project.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.500.000 |
| Totale projectbegroting | € 2.500.000 |
Tijdlijn
| Startdatum | 1-12-2022 |
| Einddatum | 30-11-2027 |
| Subsidiejaar | 2022 |
Partners & Locaties
Projectpartners
- UNIVERSITE DU LUXEMBOURGpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
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 |
Doing Charges Right: Modelling Ion-Controlled Biological Processes with the Correct ToolboxDevelop a machine learning-based force field that incorporates electronic polarization to enhance ion modeling in biological systems, improving understanding and applications in various ion-related processes. | ERC Advanced... | € 2.499.115 | 2023 | Details |
Controlling spin properties of molecules with quantum fields: ab-initio methodologies for spin polaritonsQED-Spin aims to develop novel techniques for manipulating molecular spin properties through quantum field interactions, advancing quantum computing, spectroscopy, and nuclear magnetic resonance. | ERC Starting... | € 1.499.754 | 2023 | Details |
Devising Reliable Electronic Structure Schemes through Eclectic DesignThis project aims to develop an intuitive, accurate computational chemistry method for modeling large organic molecules by enhancing electron-pair states with multi-reference wave function data. | ERC Starting... | € 1.218.088 | 2023 | Details |
The Mathematics of Interacting FermionsThis project aims to rigorously derive Fermi liquid theory from the Schrödinger equation using high-density scaling limits, distinguishing Fermi from non-Fermi liquids in various dimensions. | ERC Starting... | € 1.306.637 | 2022 | Details |
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.
Doing Charges Right: Modelling Ion-Controlled Biological Processes with the Correct Toolbox
Develop a machine learning-based force field that incorporates electronic polarization to enhance ion modeling in biological systems, improving understanding and applications in various ion-related processes.
Controlling spin properties of molecules with quantum fields: ab-initio methodologies for spin polaritons
QED-Spin aims to develop novel techniques for manipulating molecular spin properties through quantum field interactions, advancing quantum computing, spectroscopy, and nuclear magnetic resonance.
Devising Reliable Electronic Structure Schemes through Eclectic Design
This project aims to develop an intuitive, accurate computational chemistry method for modeling large organic molecules by enhancing electron-pair states with multi-reference wave function data.
The Mathematics of Interacting Fermions
This project aims to rigorously derive Fermi liquid theory from the Schrödinger equation using high-density scaling limits, distinguishing Fermi from non-Fermi liquids in various dimensions.