SubsidieMeestersStrain engineering to design functional 4D polymorphism in nanostructured materials
STRAINSWITCH aims to revolutionize polymorphic material design by using strain engineering to predict and control phase transitions for applications in water harvesting and green energy.
Projectdetails
Introduction
It is often easy to observe the ability of polymorphic materials to undergo a phase transition through changes in colour, conductivity, photovoltaic efficiency, or other functional properties. In contrast, it is challenging to control under which external stimuli—stress, temperature, adsorption—these materials switch. Yet, enabling such polymorphic material design would be a game changer for pressing societal challenges, from access to drinkable water to producing green energy. This requires a firm understanding of how changing a material’s structure impacts its polymorphism and macroscopic function.
Project Overview
In STRAINSWITCH, I aim to transform polymorphic material design by establishing the strain engineering concept. The central characteristic in my in silico approach is strain: the extent to which a material deforms due to external or internal triggers.
External and Internal Strain
On the one hand, external stimuli generate strain, even before they activate a phase transition. On the other, spatial disorder in a structure, tuneable from the atom to the device scale, also induces strain that interferes with external strain fields. My key hypothesis is that it is possible to systematically predict which disorder is needed to ensure polymorphism only occurs under well-defined external triggers by balancing these internal and external strain fields.
Research Goals
To confirm this hypothesis, I will develop new in silico methods with the goal to:
- Understand how disorder induces strain fields in a material that propagate through both space (3D) and time (+1D) to enable 4D design.
- Predict which internal strain fields activate a material’s polymorphism under specific external stimuli.
Application and Impact
In STRAINSWITCH, I will combine both goals to establish fundamental disorder-strain-function relationships that can be validated experimentally for metal-organic frameworks and metal halide perovskites. They will pave the way for 4D polymorphic material design with applications in water harvesting, photovoltaic devices, and more.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.500.000 |
| Totale projectbegroting | € 1.500.000 |
Tijdlijn
| Startdatum | 1-1-2024 |
| Einddatum | 31-12-2028 |
| Subsidiejaar | 2024 |
Partners & Locaties
Projectpartners
- UNIVERSITEIT GENTpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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Straintronic control of correlations in twisted van der Waals heterostructures
This project aims to explore the ground state properties of twisted graphene and transition metal dichalcogenide heterostructures using hydrostatic pressure and mechanical strain to uncover novel quantum phases.
Reversible Heterolytic Mechanophores for Dynamic Bulk Materials
ReHuse aims to develop reversible mechanophores that enable dynamic mechanoresponsiveness in polymers, paving the way for recyclable materials and innovative atmospheric water harvesters.
Polarized 2D Materials Inspired by Naturally Occurring Phyllosilicates
The POL_2D_PHYSICS project aims to explore phyllosilicates as multifunctional 2D materials for sustainable electronics, focusing on their applications in gate dielectrics, magnetic, and ferroelectric insulators.
Ferroic Materials for Dynamic Heat Flow Control
This project aims to develop innovative thermal switches and diodes using domain walls in ferroelectric oxides for efficient heat flow control, enhancing sustainable energy applications.
Engineered carrier transport in nanostructured semiconductors using functional disorder.
EnVision aims to leverage disorder in nanomaterials to enhance carrier transport and interconversion by developing design rules and advanced microscopy techniques for optimized energy landscapes.