³Ô¹ÏÍøÕ¾

Physics Team Electrifies Quantum World

Researchers from the Cluster of Excellence ct.qmat have developed a method to model a central theory of quantum gravity in the laboratory. Their goal: to decipher previously unexplained phenomena in the quantum world.

Illustration of the theory used to model quantum gravity: The lattice simulates a curved space-time – near the boundry, the lattice is denser due to the curvature. The interacting electrical signals (yellow, red and blue lines) in the bulk simulate the gravitational dynamics. The dynamics in the bulk and at the outer boundary correspond to each other. They are consistent with the AdS/CFT correspondence. (Image: Erdmenger/JMU, Böttcher/Alberta)

Gravity is no longer a mystery to physicists – at least when it comes to large distances: thanks to science, we can calculate the orbits of planets, predict tides, and send rockets into space with precision. However, the theoretical description of gravity reaches its limits at the level of the smallest particles, the so-called quantum level.

“To explain the Big Bang or the interior of black holes, we have to understand the quantum properties of gravity”, explains Professor Johanna Erdmenger, Chair of Theoretical Physics III at the University of Würzburg (JMU) in Bavaria, Germany. “At very high energies, the classical laws of gravity fail. Therefore, our goal is to contribute to the development of new theories that can explain gravity at all scales, including at the quantum level.”

Researchers Focus on the Central Theory of Quantum Gravity

The “AdS/CFT correspondence”, a central theory of quantum gravity, plays an important role in the development of new models. It states that complex gravitational theories in a high-dimensional space can be described by simpler quantum theories at the boundary of that space.

[Explanation: “AdS” stands for “Anti-de-Sitter”, a special type of spacetime that is curved inward, like a hyperbola. “CFT” stands for “conformal field theory”, a theory that describes quantum physical systems whose properties are the same at all spatial distances.]

“This sounds very complicated at first, but it’s easy to explain”, says Erdmenger. “The AdS/CFT correspondence allows us to understand difficult gravitational processes, such as those that exist in the quantum world, using simpler mathematical models. At its heart is a curved spacetime, which can be thought of as a funnel. The correspondence states that the quantum dynamics at the edge of the funnel must correspond to the more complex dynamics inside – similary to a hologram on a banknote, which generates a three-dimensional image even though it is only two-dimensional itself.

Proof of Concept for Realizing Gravitational Dynamics in the Laboratory

Together with her team, Erdmenger has now developed a method to experimentally test the predictions of the previously unconfirmed AdS/CFT correspondence: a branched electrical circuit is used to mimic curved space-time – the electrical signals at the individual branch points of the circuit correspond to the gravitational dynamics that would be found at different points in space-time. The theoretical calculations of the research team show that in the proposed circuit, the dynamics at the edge of the mimicked spacetime also correspond to those inside – and thus a central prediction of the AdS/CFT correspondence can be realized by the circuit.

Practical Implementation and Possible Technical Applications

As a next step, the Würzburg research team now plans to put the experimental setup described in the study into practice. In addition to significant advances in gravitational research, this could also lead to technical innovations. “Our circuits also open up new technological applications”, explains Erdmenger. “Based on quantum technology, they are expected to transmit electrical signals with reduced loss, since the simulated curvature of space bundles and stabilizes the signals. This would be a breakthrough for signal transmission in neural networks used for artificial intelligence, for example.”

The University of Alberta, Canada, the Max Planck Institute for the Physics of Complex Systems in Dresden, Germany, the University of Alabama in Tuscaloosa, USA, and the Chair of Theoretical Physics I at the University of Würzburg, Germany, were involved as collaborating partners in the international study. Financial support was provided by the Würzburg-Dresden Cluster of Excellence “ct.qmat – Complexity and Topology in Quantum Materials”.

About the Cluster of Excellence ct.qmat

The Cluster of Excellence ct.qmat – Complexity and Topology in Quantum Matter has been jointly run by the University of Würzburg (JMU) and Technische Universität (TU) Dresden since 2019. Over 300 scientists from more than thirty countries and four continents study topological quantum materials that reveal surprising phenomena under extreme conditions such as ultra-low temperatures, high pressure, or strong magnetic fields. ct.qmat is funded through the German Excellence Strategy of the Federal and State Governments and is the only Cluster of Excellence in Germany to be based in two different federal states.

About the Study

Simulation of holographic conformal field theories on hyperbolic lattices. Santanu Dey, Anffany Chen, Pablo Basteiro, Alexander Fritzsche, Martin Greiter, Matthias Kaminski, Patrick M. Lenggenhager, René Meyer, Riccardo Sorbello, Alexander Stegmaier, Ronny Thomale, Johanna Erdmenger, Igor Boettcher. Physical Review Letters 133, August 9, 2024. DOI:

/Public Release. View in full .