Data corresponding to publication: "Classical spin liquids from frustrated Ising models in hyperbolic space" by F. Köhler et al (2026)
Contributing person | Fabian Köhler | |
Contributing person | Matthias Vojta | |
References to related material | https://arxiv.org/abs/2506.02113 | |
Type of the data | Dataset | |
Total size of the dataset | 985583 | |
Author | Vojta, Matthias | |
Upload date | 2026-04-10T12:20:04Z | |
Publication date | 2026-04-10T12:20:04Z | |
Data of data creation | 2025 | |
Publication date | 2026-04-10 | |
Abstract of the dataset | This dataset contains the data and scripts corresponding to the figures in the publication F. Köhler, J. Erdmenger, R. Moessner, M. Vojta, "Classical spin liquids from frustrated Ising models in hyperbolic space", Phys. Rev. E (2026). | |
Public reference to this page | https://opara.zih.tu-dresden.de/handle/123456789/2188 | |
Public reference to this page | https://doi.org/10.25532/OPARA-1161 | |
Publisher | Technische Universität Dresden | |
Licence | Attribution-NonCommercial-NoDerivatives 4.0 International | en |
URI of the licence text | http://creativecommons.org/licenses/by-nc-nd/4.0/ | |
Specification of the discipline(s) | 3::32 | |
Title of the dataset | Data corresponding to publication: "Classical spin liquids from frustrated Ising models in hyperbolic space" by F. Köhler et al (2026) | |
Research instruments | analytical computation; custom-made computer code | |
Project abstract | New materials with customized functionality form the basis for progress of modern technology, from information and communication via energy generation, distribution and storage to mobility and beyond. Condensed matter physics, having time and again sparked major technological breakthroughs, has produced a game-changing paradigm termed topology: materials can have remarkable and robust global properties which lie beyond what can simply be measured locally. The Cluster of Excellence Complexity, Topology and Dynamics in Quantum Matter (ctd.qmat) aims to understand, control and apply novel quantum materials to create the long-term basis for future technologies. Its interdisciplinary research program—a collaboration of chemists, materials scientists and condensed matter physicists—interweaves theoretical and experimental studies in materials search and preparation; discovery and modeling of new physical phenomena; control and manipulation of quantum states; device design for innovative applications; and synthesis of a deeper understanding of the field. The cluster investigates novel materials where, from quantum mechanics at the atomic scale, topology as well as chemical and physical complexity emerge to generate unprecedented properties and phenomena. Topological physics has become one of the largest branches of condensed matter physics worldwide, with Würzburg and Dresden arguably the strongest locations in Germany. Leveraging their complementary scientific expertise and infrastructure, ctd.qmat has evolved into a cohesive, hugely productive and globally visible research effort, also successful in attracting the best minds as well as reaching out to society. ctd.qmat is structured into four research areas, three devoted to different platforms of topological physics: electron transport, magnetism, photonics & metamaterials. The fourth serves as bridge to technological applications; examples from our first funding period include topological lasers, topological catalysts, and quantum sensors. | |
Funding Acknowledgement | Financial support from the Deutsche Forschungsgemeinschaft through SFB 1143 (project-id 247310070) and the Würzburg-Dresden Cluster of Excellence on Complexity, Topology and Dynamics in Quantum Matter --ctd.qmat (EXC 2147, project-id 390858490) is gratefully acknowledged. | |
Public project website(s) | ctdqmat.de | |
Project title | Cluster of Excellence 2147 "ctd.qmat - Complexity, Topology and Dynamics in Quantum Matter" |
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