Block–spiral magnetism: An exotic type of frustrated order

J. Herbrych; J. Heverhagen; G. Alvarez; M. Daghofer; A. Moreo; E. Dagotto

doi:10.1073/pnas.2001141117

Block–spiral magnetism: An exotic type of frustrated order

J. Herbrych
, J. Heverhagen
, G. Alvarez
, M. Daghofer
, A. Moreo
, E. Dagotto

Computational Chemistry and Nanomaterial

Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

Competing interactions in quantum materials induce exotic states of matter such as frustrated magnets, an extensive field of research from both the theoretical and experimental perspectives. Here, we show that competing energy scales present in the low-dimensional orbital-selective Mott phase (OSMP) induce an exotic magnetic order, never reported before. Earlier neutron-scattering experiments on iron-based 123 ladder materials, where OSMP is relevant, already confirmed our previous theoretical prediction of block magnetism (magnetic order of the form ↑↑↓↓). Now we argue that another phase can be stabilized in multiorbital Hubbard models, the block–spiral state. In this state, the magnetic islands form a spiral propagating through the chain but with the blocks maintaining their identity, namely rigidly rotating. The block–spiral state is stabilized without any apparent frustration, the common avenue to generate spiral arrangements in multiferroics. By examining the behavior of the electronic degrees of freedom, parity-breaking quasiparticles are revealed. Finally, a simple phenomenological model that accurately captures the macroscopic spin spiral arrangement is also introduced, and fingerprints for the neutron-scattering experimental detection are provided.

Original language	English
Pages (from-to)	16226-16233
Number of pages	8
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	117
Issue number	28
DOIs	https://doi.org/10.1073/pnas.2001141117
State	Published - Jul 14 2020

Funding

ACKNOWLEDGMENTS. We thank M. L. Baez, C. Batista, and M. Mierzejewski for fruitful discussions. J. Herbrych, A. Moreo, and E. Dagotto were supported by the US Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES), Materials Sciences and Engineering Division. In addition, J. Herbrych acknowledges grant support by the Polish National Agency of Academic Exchange under Contract PPN/PPO/2018/1/00035. The development of the DMRG++ code by G.A. was supported by the Scientific Discovery through Advanced Computing (SciDAC) program funded by the US Department of Energy (DOE), Office of Science, Advanced Scientific Computer Research and Basic Energy Sciences, Division of Materials Science and Engineering, which was conducted at the Center for Nanophase Materials Science, sponsored by the Scientific User Facilities Division, Basic Energy Sciences, DOE, under contract with University of Tennessee–Battelle. J. Heverhagen and M.D. were supported by the Deutsche Forschungsge-meinschaft via the Emmy-Noether program (DA 1235/1-1) and FOR1807 (DA 1235/5-1) and by the state of Baden-Württemberg through Baden-Württemberg High Performance Computing (bwHPC). Calculations have been partly carried out using resources provided by Wroclaw Centre for Networking and Supercomputing.

Keywords

Fe-based superconductors
Frustrated magnetism
Multiorbital Hubbard model

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title = "Block–spiral magnetism: An exotic type of frustrated order",

abstract = "Competing interactions in quantum materials induce exotic states of matter such as frustrated magnets, an extensive field of research from both the theoretical and experimental perspectives. Here, we show that competing energy scales present in the low-dimensional orbital-selective Mott phase (OSMP) induce an exotic magnetic order, never reported before. Earlier neutron-scattering experiments on iron-based 123 ladder materials, where OSMP is relevant, already confirmed our previous theoretical prediction of block magnetism (magnetic order of the form ↑↑↓↓). Now we argue that another phase can be stabilized in multiorbital Hubbard models, the block–spiral state. In this state, the magnetic islands form a spiral propagating through the chain but with the blocks maintaining their identity, namely rigidly rotating. The block–spiral state is stabilized without any apparent frustration, the common avenue to generate spiral arrangements in multiferroics. By examining the behavior of the electronic degrees of freedom, parity-breaking quasiparticles are revealed. Finally, a simple phenomenological model that accurately captures the macroscopic spin spiral arrangement is also introduced, and fingerprints for the neutron-scattering experimental detection are provided.",

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AU - Moreo, A.

AU - Dagotto, E.

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N2 - Competing interactions in quantum materials induce exotic states of matter such as frustrated magnets, an extensive field of research from both the theoretical and experimental perspectives. Here, we show that competing energy scales present in the low-dimensional orbital-selective Mott phase (OSMP) induce an exotic magnetic order, never reported before. Earlier neutron-scattering experiments on iron-based 123 ladder materials, where OSMP is relevant, already confirmed our previous theoretical prediction of block magnetism (magnetic order of the form ↑↑↓↓). Now we argue that another phase can be stabilized in multiorbital Hubbard models, the block–spiral state. In this state, the magnetic islands form a spiral propagating through the chain but with the blocks maintaining their identity, namely rigidly rotating. The block–spiral state is stabilized without any apparent frustration, the common avenue to generate spiral arrangements in multiferroics. By examining the behavior of the electronic degrees of freedom, parity-breaking quasiparticles are revealed. Finally, a simple phenomenological model that accurately captures the macroscopic spin spiral arrangement is also introduced, and fingerprints for the neutron-scattering experimental detection are provided.

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Block–spiral magnetism: An exotic type of frustrated order

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Keywords

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