SubsidieMeestersDynamical Response of Entangled Quantum Matter
DynaQuant aims to develop theoretical methods to study the dynamical response of topological quantum states, enhancing understanding and experimental detection of their unique properties.
Projectdetails
Introduction
The interplay of correlations and quantum fluctuations in condensed matter can give rise to topological phases with unexpected and exciting properties. While originally proposed for fractional quantum Hall states, recently new opportunities arose for realizing and controlling topological order. Quantum computers have demonstrated the fascinating fractionalized statistics of topological excitations, and moiré semiconductors have appeared as promising candidates for realizing topological order.
However, it remains an important open challenge to understand the dynamical response of such entangled matter, both on the fundamental level as well as for providing key experimental signatures that characterize these phases.
Project Focus
The central focus of the project DynaQuant is to develop new concepts and new theoretical methods to study the dynamical response of topological quantum states. The project has three principal objectives, each of which would represent a major contribution to the field:
- Objective 1 (O1): To introduce new dynamical probes tailored toward emerging experimental platforms that enable the detection of unique signatures of equilibrium phases with topological order.
- Objective 2 (O2): To demonstrate the response of pristine nonequilibrium phases with Floquet topological order that do not possess analogues in thermal equilibrium.
- Objective 3 (O3): To develop novel tensor network approaches for fracton topological order and investigate the collective dynamics of their excitations.
Methodology
To successfully meet our ambitious objectives, my team and I will develop complementary analytical and numerical approaches. This allows us to understand fundamental dynamical properties of entangled quantum matter and to guide future experiments.
Conclusion
Due to the international effort in developing experimental platforms for realizing topological order, it is now the right time to foster a deep understanding of their dynamical response, which is the central goal of the project DynaQuant.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.998.750 |
| Totale projectbegroting | € 1.998.750 |
Tijdlijn
| Startdatum | 1-12-2025 |
| Einddatum | 30-11-2030 |
| Subsidiejaar | 2025 |
Partners & Locaties
Projectpartners
- TECHNISCHE UNIVERSITAET MUENCHENpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
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Correlation-driven metallic topology
The project aims to discover new correlation-driven gapless topological phases in heavy fermion compounds, establishing design principles and assessing their potential for quantum devices.
Statistical mechanics of quantum measurement and quantum entanglement
This project aims to develop a comprehensive theory of measurement-induced criticality and dynamical phases in nonunitary quantum systems, leveraging advancements in quantum simulation and computation.
Hidden metastable mesoscopic states in quantum materials
This project aims to develop tools for investigating mesoscopic metastable quantum states in non-equilibrium conditions using advanced time-resolved techniques and theoretical models.
Tunable Interactions in 2-dimensional Materials for Quantum Matter and Light
This project aims to create a versatile 2D materials platform to explore and realize exotic quantum phases and non-classical light generation through interactions among optical excitations.
Gaining leverage with spin liquids and superconductors
TROPIC aims to revolutionize quantum computing by developing advanced experiments to identify topological properties in quantum materials, focusing on Majorana fermions and unconventional superconductivity.